service manual - Doosan Infracore
Transcription
service manual - Doosan Infracore
For use in service manual form SB4099E SB4112E00 Sep. 2003 SERVICE MANUAL CONTENTS NOTICE This form lists the contents of the complete Service Manual for this product. The items listed with form numbers are available and included in the manual. If form numbers listed with mark (*) are, they are not available for the initial release of the manual. When items are updated, or supplements added, they will be announced in preview and should be ordered as they become available. TITLE Service Manual Contents Safety Torque Specifications FORM NUMBER SB4112E00 SB2003E00 SB2004E00 DRIVE & CONTROL SYSTEM MicroController Control Systems(36V) MicroController Control Systems(48V) SB2077E04 SB4101E00 POWER TRAIN Power Train SB4100E00 VEHICLE SYSTEMS Vehicle Systems Vehicle Systems D & A Hydraulic System Schematic Electric Systems Schematic Mast Systems SB4113E00 SB4114E00 SB4115E00 SB4116E00 SB2143E02 OPERATION & MAINTENANC E Operation & Maintenance Manual Models ; B13T-2, B15T-2, B18T-2, B20T-2(36V, 48V) SB2315E02 SB2003E00 O c t. 1 9 9 6 WARNING SAFETY WARNING WARNING Do not operate this machine unless you have read and understand the instructions in the OPERATOR'S GUIDE. Improper machine operation is dangerous and could result in injury or death. The proper and safe lubrication and maintenance for this machine, recommended by DAEWOO, are outlined in the OPERATION & MAINTENANCE GUIDE for this machine. Improper performance of lubrication or maintenance procedures is dangerous and could result in injury or death. Read and understand the OPERATION & MAINTENANCE GUIDE before performing any lubrication or maintenance. 5. Use steps and grab handles (if applicable) when mounting or dismounting a machine. Clean any mud or debris from steps, walkways or work platforms before using. Always face machine when using steps, ladders and walkways. When it is not possible to use the designed access system, provide ladders, scaffolds, or work platforms to perform safe repair operations. The serviceman or mechanic may be unfamiliar with many of the systems on this machine. This makes it important to use caution when performing service work. A knowledge of the system and/or components is important before the removal or disassembly of any component. 6. To avoid back injury, use a hoist when lifting components which weigh 23 kg (50 lb.) or more. Make sure all chains, hooks, slings, etc., are in good condition and are of the correct capacity. Be sure hooks are positioned correctly. Lifting eyes are not to be side loaded during a lifting operation. Because of the size of some of the machine components, the serviceman or mechanic should check the weights noted in this Manual, Use proper lifting procedures when removing any components. 7. To avoid burns, be alert for hot parts on machines which have just been stopped and hot fluids in lines, tubes and compartments. Following is a list of basic precautions that should always be observed. 8. Be careful when removing cover plates. Gradually back off the last two bolts or nuts located at opposite ends of the cover or device and pry cover loose to relieve any spring or other pressure, before removing the last two bolts or nuts completely. 1. Read and understand all Warning plates and decals on the machine before operating, lubricating or repairing the product. 2. Always wear protective glasses and protective shoes when working around machines. In particular, wear protective glasses when pounding on any part of the machine or its attachments with a hammer or sledge. Use welders gloves, hood/goggles, apron and other protective clothing appropriate to the welding job being performed. Do not wear loose-fitting or torn clothing. Remove all rings from fingers when working on machinery. 9. Be careful when removing filler caps, breathers and plugs on the machine. Hold a rag over the cap or plug to prevent being sprayed or splashed by liquids under pressure. The danger is even greater if the machine has just been stopped because fluids can be hot. 10. Always use tools that are in good condition and be sure you understand how to use them before performing any service work. 3. Do not work on any machine that is supported only by lift jacks or a hoist. Always use blocks or jack stands to support the machine before performing any disassembly. 11. Reinstall all fasteners with same part number. Do not use a lesser quality fastener if replacements are necessary. Do not mix metric fasteners with standard nuts and bolts. 4. Lower the forks or other implements to the ground before performing any work on the machine. If this cannot be done, make sure the forks or other implements are blocked correctly to prevent them from dropping unexpectedly. 12. If possible, make all repairs with the machine parked on a level, hard surface. Block machine so it does not roll while working on or under machine. 1 of 2 WARNING 21. Do not operate a machine if any rotating part is damaged or contacts any other part during operation. Any high speed rotating component that has been damaged or altered should be checked for balance before reusing. 13. Disconnect battery and discharge any capacitors (electric trucks) before starting to work on machine. Hang "Do Not Operate" tag in the Operator's Compartment. 14. Repairs, which require welding, should be performed only with the benefit of the appropriate reference information and by personnel adequately trained and knowledgeable in welding procedures. Determine type of metal being welded and select correct welding procedure and electrodes, rods or wire to provide a weld metal strength equivalent at least to that of parent metal. 22. On LP equipped lift trucks, be sure to close the valve on the LP tank before service work is performed. Always close the valve on the LP tank when the lift truck is being stored. Do not check for LP leaks with an open flame. 23. Caution should be used to avoid breathing dust that may be generated when handling components containing asbestos fibers. If this dust is inhaled, it can be hazardous to your health. Components in DAEWOO products that may contain asbestos fibers are brake pads, brake band and lining assemblies, clutch plates and some gaskets. The asbestos used in these components is usually bound in a resin or sealed in some way. Normal handling is not hazardous as long as airborne dust which contains asbestos is not generated. 15. Do not damage wiring during removal operations. Reinstall the wiring so it is not damaged nor will it be damaged in operation by contacting sharp corners, or by rubbing against some object or hot surface. Do not connect wiring to a line containing fluid. 16. Be sure all protective devices including guards and shields are properly installed and functioning correctly before starting a repair. If a guard or shield must be removed to perform the repair work, use extra caution. If dust which may contain asbestos is present, there are several common sense guidelines that should be followed. 17. Always support the mast and carriage to keep carriage or attachments raised when maintenance or repair work is performed, which requires the mast in the raised position. a. Never use compressed air for cleaning. b. Avoid brushing or grinding of asbestos containing materials. 18. Loose or damaged fuel, lubricant and hydraulic lines, tubes and hoses can cause fires. Do not bend or strike high pressure lines or install ones which have been bent or damaged. Inspect lines, tubes and hoses carefully. Do not check for leaks with your hands. Pin hole (very small) leaks can result in a high velocity oil stream that will be invisible close to the hose. This oil can penetrate the skin and cause personal injury. Use cardboard or paper to locate pin hole leaks. c. For clean up, use wet methods or a vacuum equipped with a high efficiency particulate air (HEPA) filter. d. Use exhaust ventilation on permanent machining jobs. e. Wear an approved respirator if there is no other way to control the dust. f. Comply with applicable rules and regulations for the work place (for example in the U.S.A., OSHA requirements as set forth in 29 CFR 1910. 1001). 19. Tighten connections to the correct torque. Make sure that all heat shields, clamps and guards are installed correctly to avoid excessive heat, vibration or rubbing against other parts during operation. Shields that protect against oil spray onto hot exhaust components in event of a line, tube or seal failure must be installed correctly. g. Follow environmental rules and regulations for disposal of asbestos. h. Avoid areas where asbestos particles may be in the air. 20. Relieve all pressure in air, oil or water systems before any lines, fittings or related items are disconnected or removed. Always make sure all raised components are blocked correctly and be alert for possible pressure when disconnecting any device from a system that utilizes pressure. 2 of 2 SB2004E00 Dec. 1998 Specifications TORQUE SPECIFICATIONS STANDARD TORQUE FOR METRIC FASTENERS NOTE : Take care to avoid mixing metric and inch dimensioned fasteners. Mismatched or incorrect fasteners can result in vehicle damage or malfunction, or possible injury. Exceptions to these torques are given in the Service Manual where needed. NOTE : Prior to installation of any hardware, be sure components are in near new condition. Bolt and nut threads must not be worn or damaged. Hardware must be free of rust and corrosion. Clean hardware with a non-corrosive cleaner and apply engine oil to threads and bearing face. If thread lock or other compounds are to be applied, do not apply engine oil. METRIC NUTS AND BOLTS THREAD SIZE (mm) STANDARD TORQUE (N i m) (lb i ft) M6 12 9 M8 28 M10 55 M12 100 M14 160 M16 240 M20 460 M24 800 M30 1600 M36 2700 ±3 ±7 ± 10 ± 20 ± 30 ± 40 ± 60 ± 100 ± 200 ± 300 20 40 75 120 175 340 600 1200 2000 ± ± ± ± ± ± ± ± ± ± 2 5 7 15 22 30 44 75 150 225 METRIC TAPERLOCK STUDS THREAD SIZE (mm) STANDARD TORQUE (N i m) M6 8 M8 17 M10 35 M12 65 M16 110 M20 170 M24 400 M30 650 M36 870 ± ± ± ± ± ± ± ± ± (lb i ft) 3 6 5 13 5 26 10 48 20 80 30 125 60 300 80 480 100 640 1 of 7 ± ± ± ± ± ± ± ± ± 2 4 4 7 15 22 45 60 75 STANDARD TORQUE FOR INCH FASTENERS Exceptions to these torques are given in the Service Manual where needed. INCH NUTS AND BOLTS THREAD SIZE inch STANDARD TORQUE (N i m) 1/4 12 5/16 25 3/8 47 7/16 70 1/2 105 9/16 160 5/8 215 3/4 370 7/8 620 1 900 1-1/8 1300 1-1/4 1800 1-3/8 2400 1-1/2 3100 ± ± ± ± ± ± ± ± ± ± ± ± ± ± (lb i ft) 3 9 6 18.0 9 35 15 50 20 75 30 120 40 160 50 275 80 460 100 660 150 950 200 1325 300 1800 350 2300 ± ± ± ± ± ± ± ± ± ± ± ± ± ± 2 4.5 7 11 15 20 30 35 60 75 100 150 225 250 INCH TAPERLOCK STUDS THREAD SIZE inch STANDARD TORQUE (N i m) 1/4 8 5/16 17 3/8 35 7/16 45 1/2 65 5/8 110 3/4 170 7/8 260 1 400 1-1/8 500 1-1/4 650 1-3/8 750 1-1/2 870 ± ± ± ± ± ± ± ± ± ± ± ± ± (lb i ft) 3 6 5 13 5 26 10 33 10 48 20 80 30 125 40 190 60 300 70 370 80 480 90 550 100 640 2 of 7 ± ± ± ± ± ± ± ± ± ± ± ± ± 2 4 4 7 7 15 22 30 45 50 60 65 75 O-RING FACE SEAL FITTINGS O-RING FACE SEAL FITTING O-RING GROOVE O-RING FACE SEAL NUT STRAIGHT THREAD O-RING PORT FITTING END O-RING IDAS001B STRAIGHT THREAD O-RING FITTING (FOR O-RING FACE SEAL FITTING ONLY) THREAD SIZE inch STANDARD TORQUE (lb i ft) (N i m) 5/16-24 5.0 3/8-24 12 7/16-20 20 1/2-20 30 9/16-18 40 3/4-16 100 7/8-14 135 1 1/16-12 200 1 3/16-12 250 1 5/16-12 300 1 5/8-12 300 1 7/8-12 300 2 1/2-12 300 ± ± ± ± ± ± ± ± ± ± ± ± ± 1.5 2 45±15 lb i in 110±20 lb i in 4 15 5 22 5 30 15 75 15 100 25 150 25 185 40 225 40 225 40 225 40 225 ± ± ± ± ± ± ± ± ± ± ± 3 4 4 10 10 20 20 30 30 30 30 O-RING FACE SEAL FITTING NUT THREAD SIZE inch STANDARD TORQUE (N i m) 9/16-18 16 11/16-16 30 13/16-16 50 1-14 90 1 3/16-12 120 1 7/16-12 160 1 11/16-12 190 2-12 215 ± ± ± ± ± ± ± ± (lb i ft) 3 12 4 22 7 37 10 65 15 90 20 120 20 140 25 160 3 of 7 ± ± ± ± ± ± ± ± 2 3 5 7 10 15 15 20 FITTING INSTALLATION 1. Put locknut (3), backup washer (4) and O-ring seal (5) as far back on fitting body (2) as possible. Hold these components in this position. Turn the fitting into the part it is used on until backup washer (4) just makes contact with the face of the part it is used on. HYDRAULIC LINE INSTALLATION 1. For a metal tube to hose installation, install the tube and tighten all bolts finger tight. 2. Tighten the bolts at the rigid end. 2.To put the fitting assembly in its correct position, turn the fitting body (2) out (counterclockwise) a maximum of 359û. Tighten locknut (3) to the torque shown in the correct chart for the fitting used. 3. Install the hose and tighten all bolts finger tight. 4. Put the hose in a position so that it does not make contact with the machine or another hose. NOTE: If the fitting is a connector (straight fitting), the hex on the body takes the place of the locknut. To install this type fitting, tighten the hex against the face of the part it goes into. 5. Tighten the bolts on both connections. 6. Start the engine. 7. Move the implement control levers to all positions. 8. Look at the hose during movement of the implement. Make sure hose is not in contact with the machine or other hoses. TORQUES FOR FLARED AND O-RING FITTINGS The torques shown in the charts that follow are to be used on the nut part of 37û Flared, 45û Flared and Inverted Flared fittings (when used with steel tubing), O-ring plugs, O-ring fittings and swivel nuts when used in applications to 3000 psi (20 700 kPa). 9. Shut off the engine. 10. If necessary, put the hose in a new position where it will not make contact when the implement is moved. ASSEMBLY OF FITTINGS WITH STRAIGHT THREADS AND O-RING SEALS HOSE CLAMP-BAND TYPE This type of fitting is used in many applications. The tube end of the fitting will be different in design so that it can be used in many different applications. However, the installation procedure of the fitting is the same. If the tube end of the fitting body is the same as in the illustration (either an elbow or a straight body) it will be necessary to assemble the sleeve on the tube before connecting the tube to the end. 2 1 IDAS003B 4 CLAMP WIDTH 7.9 mm (.312 in) 13.5 mm (.531 in) 15.9 mm (.625 in) 3 5 6 IDAS002B ELBOW BODY ASSEMBLY (1) End of fitting body (connects to tube). (2) Fitting body. (3) Lock-nut. (4) Backup washer. (5) O-ring seal. (6) End of fitting that goes into other part. 4 of 7 TORQUE ON NEW HOSE 0.9 ± 0.2 N i m 8 ± 2 lb i in 4.5 40 7.5 65 ± ± ± ± 0.5 N i m 5 lb i in 0.5 N i m 5 lb i in RETIGHTENING TORQUE 0.7 ± 0.2 N i m 6 ± 2 lb i in 3.0 25 4.5 40 ± ± ± ± 0.5 N i m 5 lb i in 0.5 N i m 5 lb i in 37û FLARED AND STRAIGHT THREAD O-RING FITTINGS 37û FLARED O-RING FITTING-PLUG SWIVEL NUTS IDAS004B 37û FLARED AND STRAIGHT THREAD O-RING FITTINGS (EXCEPT O-RING FACE SEAL FITTINGS) METRIC INCH THREAD SIZE inch 3.18 .125 5/16 4.76 .188 3/8 6.35 .250 7/16 7.94 .312 1/2 9.52 .375 9/16 9.52 .375 5/8 12.70 .500 3/4 15.88 .625 7/8 19.05 .750 1-1/16 22.22 .875 1-3/16 25.40 1.000 1-5/16 31.75 1.250 1-5/8 38.10 1.500 1-7/8 50.80 2.000 2-1/2 NOMINAL TUBE O.D. STANDARD TORQUE (N i m) ± 1.5 11.0 ± 1.5 16 ± 2 20 ± 5 25 ± 5 35 ± 5 50 ± 7 65 ± 7 100 ± 10 120 ± 10 135 ± 15 180 ± 15 225 ± 15 320 ± 30 5.0 TIGHTENING OTHER FITTINGS Hi Duty (Shear sleeve) Tube Fittings After tube has been put through the nut and makes contact against the tube shoulder in the fitting body, turn the nut with a wrench until a small decrease in torque is felt. This is an indication that the sleeve has been broken off the nut. Hold the tube to prevent turning and tighten the nut 1-1/2 turns. IDAS005B Hi Seal Fittings Put nut and sleeve over the tubing with the short heavy end of the sleeve facing the end of tubing. Put the tube end against the counterbore in the body of the fitting and tighten until nut is over the last thread on the body. The remainder of space is used whenever the fitting is removed and installed again. IDAS006B 5 of 7 (lb i ft) 4 8 12 15 18 26 37 48 75 90 100 135 165 240 ± ± ± ± ± ± ± ± ± ± ± ± ± ± 1 1 1 4 4 4 5 5 7 7 11 11 11 22 45û FLARED AND 45û INVERTED FLARE FITTINGS INVERTED 45û FLARED 45û FLARED IDAS007B 45û FLARED AND 45û INVERTED FLARE FITTINGS METRIC INCH THREAD SIZE inch 3.18 .125 5/16 5.0 4.76 .188 3/8 8.0 6.35 .250 7/16 11 7.94 .312 1/2 17 9.52 .375 5/8 30 11.11 .438 11/16 30 12.70 .500 3/4 38 15.88 .625 7/8 50 19.05 .750 1-1/16 90 22.22 .875 1-1/4 100 NOMINAL TUBE O.D. STANDARD TORQUE (N i m) ± ± ± ± ± ± ± ± ± ± 1.5 4 1.5 6 2 8 3 13 3 22 3 22 4 28 5 37 8 65 10 75 TIGHTENING OTHER FITTINGS Ermeto Tube Fittings Put nut and sleeve over the tube with head or shoulder end of sleeve next to nut. Push tube into counterbore of fitting body as far as possible. Turn nut clockwise until sleeve holds tube and prevents movement. Tighten the nut 1-1/4 turns more to seat sleeve and give a locking action. When necessary to assemble again, put sleeve over tube and tighten nut until a sudden increase in torque is felt. Then tighten 1/6 to 1/3 turn more to seat the sleeve. IDAS008B Flex Fittings Put nut and sleeve over the tubing and push tube in to counterbore of fitting body as far as possible. Tighten the nut until it is against the hex part of the fitting body. IDAS009B 6 of 7 (lb i ft) ± ± ± ± ± ± ± ± ± ± 1 1 1 2 2 2 3 4 6 7 AIR CONDITIONING AND TAPERED PIPE THREAD FITTINGS O-RING 45û FLARE IDAS010B AIR CONDITIONING FITTINGS 45û FLARE FITTING END O-RING FITTING END THREAD SIZE inch STANDARD TORQUE N im 5/8-18 18 3/4-16 37 7/8-14 40 1 1/16-14 45 ±4 ±4 ±4 ±5 (lb i ft) ± 27 ± 30 ± 33 ± 13 3 3 3 4 STEEL TUBES ALUMINUM TUBES STANDARD TORQUE STANDARD TORQUE N im ± 52 ± 60 ± 75 ± 30 3 5 7 8 (lb i ft) ± 38 ± 44 ± 55 ± 22 N im 2 23 4 33 5 38 6 50 ± ± ± ± 3 4 4 5 TAPERED PIPE THREAD FITTINGS PIPE THREAD SIZE inch STANDARD TORQUE THREADS WITH 1E2200E SEALANT THREADS WITHOUT SEALANT Nim (lb i ft) Nim (lb i ft) 1/16-27 15 11 20 15 1/8-27 20 15 25 18 1/4-18 25 18 35 26 3/8-18 35 26 45 33 1/2-14 45 33 60 45 3/4-14 60 45 75 55 1-11 1/2 75 55 90 65 1 1/4-11 1/2 95 70 110 80 1 1/2-11 1/2 110 80 130 95 2-11 1/2 130 95 160 120 7 of 7 (lb i ft) ± 24 ± 28 ± 37 ± 17 2 3 3 4 SB2077E04 Sep. 2003 Specifications Systems Operation Testing & Adjusting MicroController Control System B15T-2, B18T-2, B20T-2(36V) EMOD4-00001~UP EMOD5-00001~UP EMOD6-00001~UP (36V : P/N A154600, P/N A154701) for Electric Lift Trucks Important Safety Information Most accidents involving product operation, maintenance and repair are caused by failure to observe basic safety rules or precautions. An accident can often be avoided by recognizing potentially hazardous situations before an accident occurs. A person must be alert to potential hazards. This person should also have the necessary training, skill and tools to perform these functions properly. Improper operation, Iubrication, maintenance or repair of this product can be dangerous and could result in injury or death. Do not operater or perform any lubrication, maintenance or repair on this product, until you have read and understood the operation, lubrication, maintenance and repair information. Safety precautions and warnings are provided in this manual and on the product. If these hazard warnings are not heeded, bodily injury or death could occur to you or other persons. The hazards are identified by the “Safety Alert Symbol” and followed by a “Signal Word” such as “WARNING” as shown below. WARNING The meaning of this safety alert symbol is as follows : Attention! Become Alert! Your Safety is Involved. The message that appears under the warning, explaining the hazard, can be either written or pictorially presented. Operations that may cause product damage are identified by NOTICE labels on the product and in this publication. DAEWOO cannot anticipate every possible circumstance that might involve a potential hazard. The warnings in this pulication and on the product are therefore not all inclusive. If a tool, procedure, work method or operating technique not specifically recommended by DAEWOO is used, you must satisfy yourself that it is safe for you and others. You should also ensure that the product will not be damaged or made unsafe by the operation, lubrication, maintenance or repair procedures you choose. The information, specifications, and illustrations in this publication are on the basis of information available at the time it was written. The specifications, torques, pressures, measurements, adjustments, illustrations, and other items can change at any time. These changes can affect the service given to the product. Obtain the complete and most current information before starting any job. DAEWOO dealers have the most current information available. MicroController Control Systems 1 Specifications Index Specifications Component Measurements....................................... Console ..................................................................... Contactors................................................................. Control Panel (Layout) .............................................. Current Measurements ............................................. 5 7 8 9 5 Location of Control Panel Components .................. 16 Logic Unit ................................................................ 17 Operational Circuit Elements .................................. 18 Accelerator Control ............................................. 23 Battery Discharge Indicator (BDI)....................... 22 Central Vehicle Monitoring System..................... 18 Contactors .......................................................... 21 Current Sensor ................................................... 21 CVMS International Pictorial Symbols................ 20 On Board “Run Time” Diagnostics (Fault Detection) ................................................. 18 Steer Angle Control ............................................ 23 Wait Mode........................................................... 21 Direction Switch ........................................................ 7 Display Layout .......................................................... 7 Fuses ........................................................................ 8 Head Capacitor ......................................................... 8 Instrument Panel ....................................................... 7 Thermal Switch - Control Panel ................................ 8 Transistor Connections ............................................. 6 Transistor Measurements ......................................... 6 Symbol Library ........................................................ 15 Testing And Adjusting Systems Operation Accessory Circuits .................................................. DC - DC Converter ............................................. Horn Circuit......................................................... Hour Meter Circuit .............................................. Built-In Diagnostic Operation .................................. 46 Accessing Stored Error Codes ........................... 51 Erased Stored Error Codes ................................51 “Run Time” Diagnostics (Lift Truck in Operation) ...................................... 46 Quick Diagnostic Procedure ............................... 52 Saving Service Records ..................................... 51 “Self” Diagnostics (Lift Truck not in Operation) ................................ 48 Stored Error Codes............................................. 52 24 24 24 24 Actuation Circuit ...................................................... 25 Drive Circuit ............................................................ Bypass Circuit..................................................... Control Circuit ..................................................... Current Limit ....................................................... Electrical Braking (Plugging) .............................. Failure Protection Circuit .................................... Flyback Circuit .................................................... Power Circuit ...................................................... Thermal Protection Circuits ................................ 33 38 33 37 39 41 36 34 41 Component Tests .................................................. 104 Capacitor (Head) .............................................. 107 Conductor and Switch Continuity ..................... 107 Contactors ........................................................ 108 Contactor Components..................................... 108 Current Sensor.................................................. 110 Diode Replacement........................................... 111 Diodes ............................................................... 111 Driver Board (Off Vehicle) ................................. 115 Driver Board (On Vehicle)................................. 112 Logic Unit Quick Reference Voltage Check ..... 104 Resistors (DR1, DR2, and PR1) ....................... 118 Thermal Switch ................................................. 119 Transistors DTR1, DTR2 and PTR1 ................. 117 Transistors Replacement DTR1, DTR2 and PTR1.................................... 117 General Information ................................................ 17 Glossary .................................................................. 11 Hydraulic Pump Motor Circuit ................................. 26 Flyback Circuit .................................................... 30 Lift Circuit............................................................ 32 Lift Control Circuit ................................................31 Power Steering Circuit .........................................26 Power Steering Idle .............................................27 MicroController Control Systems 3 Index Control and Power System Operational Checks .................................................................... 45 Electrical System Adjustments ...............................120 Accelerator Control Linkage ..............................120 BDI Adjustment ..................................................123 Bypass Dropout Adjustment ..............................127 Current Limit Test and Adjustment.....................126 Electrical Braking (Plugging) Current Test and Adjustment ..........................................127 Lift Sensor..........................................................121 Parking Brake Switch.........................................120 Rapid Tune - Up Procedure...............................123 Tilt and Auxiliary Switches .................................122 Valve Control Card Adjustment..........................121 Preparation Tests and Checks .................................42 Programmable Features ........................................128 Activating Default Settings.................................128 Programmable or Settable Option Features.............................................................129 Quick Procedure for Programmable Features.............................................................131 Setting Procedure Option Features ...................128 System Tests and Adjustments ..............................101 Discharging Head Capacitor (HEAD CAP) ......................................................101 Logics Removal .................................................102 “Run Time” Tests................................................102 Test Equipment ..................................................101 Troubleshooting........................................................42 Troubshooting Problem List ....................................53 MicroController Control Systems 4 Index Specifications Component Measurements Component Meter Meter Positive Meter Negative Scale (+) Test Lead (-) Test Lead Desired Indication DIODES (voltage indication) All Diode Anode Cathode 0.3 to 0.9 volts All Diode Cathode Anode OL RESISTORS (resistance indication) Panels With D557003(927566) Transistor DRI, DR2, PR1 200Ω 90 ohms L 5% R2, R5, R9 200Ω 7.5 ohms L 5% HEAD CAPACITOR (resistance indication) Head capacitor 200Ω Positive side of Negative side of 0 then change to capactior (+) capactior (-) above 10K ohms CONTACTOR COILS (resistance indication) Direcitional 200Ω X Y 40 to 50 ohms Line, Pump 200Ω X Y 95 to 115 ohms Bypass 200Ω X Y 40 to 50 ohms Current Measurements CURRENT VALUES (AMPS) Transistor Current Limit Plugging Limit D557003 (927566) 270 L 10A 270 L 10A MicroController Control Systems 5 Specifications Transistor Measurements SPECIFICATIONS Multimeter (+) (-) D557003 (927566) Setting Test Lead Test Lead Results Resistance Emitter Base 45 to 135 ohms Diode Base Collector .3 to .9V Diode Collector Base OL Diode Emitter Collector .3 to .9V Diode Collector Emitter OL Transistor Connections D557554 - for Pump D557003 (927566)-for Pump 2 1 1 2 3 3 (1) Emitter connection (2) Base connection (3) Collector connection MicroController Control Systems 6 Specifications Display Layout Console 1 Instrument Panel (1) Tighten bolts that fasten the cover to a torque of ............................1.5 to 2.5 N•m (13 to 22 lb•in) Direction Switch 1 1 2 (1) Tighten screws that fasten the instrument panel to a torque of ....................................0.5 to 0.7 N•m (4 to 6 lb•in) (1) Torque bolts that hold bracket to steering column to ................2.8 to 3.4 N•m (25 to 31 lb•in) (2) Torque bolts that hold bracket to switch to ............................143.4 to 3.9 N•m (31 to 35 lb•in) MicroController Control Systems 7 Specifications Head Capacitor Thermal Switch - Control Panel Contacts open at ................81 to 89°C (178 to 192˚F) Contacts close at................69 to 77°C (156 to 171˚F) 1 3 2 Contactors Torque for nuts that hold contactor bridge assembly .........................................2.2 N•m (20 lb•in) 4 5 Fuses Line .....................................................................600A Pump ...................................................................150A Key ....................................................................... 10A Horn...................................................................... 10A Voltage Converter................................................. 10A Light...................................................................... 10A Back up ................................................................ 10A NOTE : Proper torque and assembly of capacitor hardware is critical. Avoid disassembly unless capacitor has to be replaced. (1) Tighten capacitor terminal bolt to a torque of.............................4.5 to 5.5 N•m (40 to 50 lb•in) (2) Spring washer D917069. (3) Ring terminal of wire assembly. (4) Lockwasher D917071. (5) Head capacitor terminal. MicroController Control Systems 8 Specifications Control Panel (Layout) Control Panel - Drive 2 3 6 4 7 11 1 12 5 2 2 8 10 9 Control Panel - Pump 12 3 10 9 2 4 7 1 5 MicroController Control Systems 11 6 11 9 Specifications (7) Tighten diodes DD1, DD2, DD3, DD4 and PD to a torque of ......................9 to 11 N•m (81 to 99 lb•in) NOTE : Apply a small amount of D557047 Thermal Joint Compound on the surface of the transistor, diode or thermal switch that contacts the heatsink. (8) Tighten Head Capacitor terminal bolts to a torque of ............................4.5 to 5.5 N•m (40 to 50 lb•in) (1) Control panel plate. Apply a small amount of D557047 Thermal Joint Compound on control panel plate and mating surface prior to assembly. (9) Tighten all bolts that fasten bus bars of cables to either heatsink to a torque of ................................5.5 to 9.5 N•m (50 to 85 lb•in) (2) Apply Sealant (Loctite catalogue No. and nameNo. 242, Adhesive/Sealant) on the threads of all screws that are used to fasten components on the control panel. (10) Tighten bolts that hold the negative heatsink to the control panel to a torque of .......10 to 14 N•m (90 to 125 lb•in) (3) Apply Sealant (Loctite catalogue No. and nameNo. 242, Adhesive/Sealant) to the bolts used to tighten the positive heatsink to the control panel to a torque of ..........10 to 14 N•m (90 to 125 lb•in) (11) Apply Sealant (Loctite catalogue No. and nameNo. 242, Adhesive/Sealant) on portion of setscrew threads that are in the insulator and control panel plate. Tighten bolts to a torque of ................................5.5 to 9.5 N•m (50 to 85 lb•in) (4) Use a backup wrench to hold nuts and tighten bolts the fasten bus bars to the power transistors to a torque of ...............4 to 6 N•m (35 to 55 lb•in) (12) Use a backup wrench to hold bolts and tighten the nuts that fasten the cables or bus bars to the contactors to a torque of .....................4 to 6 N•m (35 to 55 lb•in) (5) Tighten screws that fasten power transistors to positive heatsink to a torque of ......................................4 to 6 N•m (35 to 55 lb•in) (6) Tighten screws that fasten wires to the base of the power transistors to a torque of .............................1.3 to 1.7 N•m (11.5 to 15 lb•in) MicroController Control Systems 10 Specifications Systems Operation Glossary NAME DESCRIPTION Accelerator A device that converts mechanical movement into a analog voltage pattern to the logics for variable drive motor speed. Activate Word used with a component or circuit. To change from the normal condition to the “activated” condition because of an application of force or electricity. Ammeter An electric meter used to measure current flow in amperes. Ampere (or Amp) The unit of measurement of current flow. The amount of current that one volt can push through a resistance of one ohm. Analog to Digital Converter A device that converts an analog voltage into a pattern of digital HIGH and LOW voltage signals. Anode The positive (+) side of a diode. Armature The rotating portion of an electric motor or generator. Base The terminal of a transistor through which control current flows (see Transistor). Battery Two or more cells connected together for a supply of electric current. BDI Battery Discharge Indicator - An electrically controlled display showing the operator the state of battery charge. Brush A conductor, normally a block of carbon, that makes sliding contact between the stationary and moving part of the motor or generator. Bus Bar A heavy electrical conductor to which other smaller wires are connected. Capacitor Device used to store electrical energy for short periods of time. Cathode The negative (-) side of a diode. CVMS Central Vehicle Monitoring System. Circuit A way for current to go from the positive (+) side of an electrical power source to the negative (-) side of an electrical power source. This can be through wires and electrical components. Coil A component made from many circles or turns of wire used to concentrate a magnetic field. Collector A terminal of a transistor through which main current flows (see Transistor). Commutator An armature component used to transfer current from the brushes to the armature windings. Conduct To allow the flow of current. Conductor A material that provides a path for current flow. Connector Part of a wire assembly or harness that connects with another wire assembly or harness. Used for ease of assembly and disassembly. MicroController Control Systems 11 Systems Operation NAME DESCRIPTION Contactor Assembly An electrical component consisting of an electromagnetic coil and a set of heavy contact tips. Control current passes through the coil, building a magnetic field which closes or opens the contact tips. Contactor Coil An electromagnet used to close or open contact tips in a contactor assembly. Contact Tips or Contacts The portion of a switch, relay or contactor where the circuit can be opened or closed. Continuity Having the ability to allow current flow. Control Circuits The wires and components carrying low current used to signal the logic unit, turn on main components, or support auxiliary circuits (indicated by narrow lines on a schmatic). Counter Electromotive Force (CEMF) An opposing voltage set up by a collapsing or increasing magnetic field within a coil. Current The movement or flow of electricity through a conductor. A circuit must be complete for current to flow. Current Limit The maximum allowable armature current of a stalled drive motor during pulsing. Current Sensor A hall-effect sensor in the drive motor circuit that produces an increasing voltage output as the drive motor current increases. Deactivate To change from the activated condition back to the normal (deactivated) condition. It can be caused by the application of force, the removal of force,or the removal of electricity. Digital Signal A signal in which the elements may be either of two distinct values. For example high voltage, low voltage. Diode A semiconductor device that allows current to flow in one direction, from the anode to the cathode. Display An electrical device that converts voltage inputs to a visual output. Electrical Braking Electrically trying to rotate the drive motor opposite to the direction of truck movement. Electromagnet A coil of wire, most often wound on an iron core, which produces a strong magnetic field when current is sent through the coil. Electromotive Force (EMF) The force that causes an electric current to flow in a circuit. This force is measured in volts. Emitter A terminal of a transistor through which low control current and main current flow (see Transistor). Field Windings The stationary coils that produce a magnetic field in motors and generators. Filter An electrical device or component for restriction or suppression of undesired voltage spikes. Fuse A component in an electrical circuit that will open the circuit if too much current goes through it. Harness An assembly made of two or more wires that are held together. Heat Sink A mounting frame used for semiconductor cooling. MicroController Control Systems 12 Systems Operation NAME DESCRIPTION Hour Meter An electrically activated device used to record the amount of usage a truck receives. Indicator LCD that gives an indication of some vehicle condition when it turns on or flashes. Input A voltage change at the incoming connection of a component. Insulator A material that has a very large resistance so that it will not let current flow through it. LCD Liquid Crystal Display. Logics or Logic Unit The main printed circuit board containing a microprocessor and circuits to condition the voltage signals that go into or come out of the logics. It electronically monitors and controls the truck's functions. Magnetic Field The area around a magnet where magnetic forces can be detected. Microprocessor A small computer chip preprogrammed to control the various electrical functions on a lift truck. Normal Condition Words used with a switch or relay. Their normal condition is their condition when they are not controlled by the application of force, temperature, pressure, or electricity. Normally Close (N.C.) A switch or relay whose contacts are closed in the normal condition. Normally Open (N.O.) A switch or relay whose contacts are opened in the normal condition. OFF-Time The amount of time current does not flow through a transistor. Ohm The unit of measurement of resistance. The amount of resistance that will let one volt push only one ampere of current through it. ON-Time The amount of time current flows through a transistor. Open Circuit Wiring or components of a circuit that have no continuity. Output The current flow from a component which initiated from a voltage change at the component's input. Overload The presence of voltage or current which is greater than an electrical circuit or component is designed to handle. Pin The male contact of a connector that fits into a female contact (socket) of another connector. Plugging A portion of electrical braking where the generated current is directed back through the armature. Plugging Current Limit The maximum allowable current at the drive motor armature during the plugging portion of electrical braking. Potentiometer An adjustable resistor to preset electronic controls for proper specifications. Power Circuits The main current carrying components and conductors (indicated by the heavy lines on a schematic). Power Transistor A component in the power circuit which allows main motor current to pass through when turned on. Pulsing Current flow in a circuit being turned on and off. MicroController Control Systems 13 Systems Operation NAME DESCRIPTION Relay An electrical component consisting of an electromagnetic coil and a set of small contact tips. Control current passes through the coil, building a magnetic field which closes or opens the contact tips. When the contact tips are closed, low current can flow in a separate isolated circuit. Resistor A component made of a material that has a specific resistance to the flow of current. Schematic A line drawing of an electrical or electronic assembly which uses symbols to show individual components. It shows how the components, wires and connectors function electrically. Semiconductor Components such as, transistors, diodes, thyristors, etc. Having electrical characteristics between a conductor and an insulator. Series Wound Motor A motor in which the armature is connected in series with the field windings. Short Circuit An electrical connection between two or more components that is not desired. Socket The female contact of a connector that slips over a male contact (pin) of another connector. Solid State Reference to semiconductor components or circuits that use semiconductor components that have no moving parts, such as diodes and transistors. Switch A component used to control an electric circuit . It can close or open a circuit. Systems The electrical components, circuits, and connections that deliver power to perform specific tasks. Terminal An electrical connection point on an electrical component. Thermal Switch A switch that activates at a set temperature. Transistor A semiconductor component used in electric lift trucks as an electronic switch. A transistor most often has three terminals, a base (B), a collector (C) and an emitter (E). The main current flow is between the collector and emitter. This main current flow is controlled by a much smaller current flow between the base and emitter. Turn ON When an electrical component conducts current. Varistor A component terminated across the horn connections to eliminate voltage spikes when the horn is activated. Volt The unit of measurement of electromotive force. One volt is the force needed to make one ampere of current flow through one ohm of resistance in a circuit. Watt The unit of measurement of power. The amount of power used when one volt pushes one ampere of current through a resistance of one ohm. The result of amperes (current) multiplied by volts (voltage) is watts (power). Wire A conductor used to provide a path for current to flow to and from electrical components. Wiring Diagram A drawing using visual representation of components the way they actually look. It is used to show the locations of components and the connections between them. Zener Diode A special diode used to regulate voltage or as an overvoltage (too high a voltage) protector. MicroController Control Systems 14 Systems Operation Symbol Library 2 3 4 6 5 9 16 7 8 1 10 17 21 11 12 13 18 14 15 20 19 Schematic Symbols (1) Power Transistor. (2) Zener Diode. (3) NPN Transistor. (4) PNP Transistor. (5) Thermal Switch. (6) Battery. (7) Resistor. (8) Diode. (9) Normally Close Contacts. (10) Normally Open Contacts. (11) Male Terminal of Connector (pin). (12) Female Terminal of Connector (socket). (13) Wire Connection. (14) No wire Connection. (15) Contactor Coil. (16) Current Sensor. (17) Armature. (18) Field windings. (19) Capacitor. (20) Fuse. (21) Switch. MicroController Control Systems 15 Systems Operation Location of Control Panel Components Control Panel - Drive 3 4 1 5 2 6 Control Panel - Pump 8 9 13 15 7 14 12 10 11 MicroController Control Panel (1) Logic Unit (Logics). (2) DR1, DR2. (3) Key Fuse. (4) Bypass Contactor. (5) Right Dir. Contactor. (6) Left Dir. Contactor. (7) PR1 (8) Board as – HYD. (9) Thermal Switch – HYD. (10) Fuse – HYD. (11) Line Fuse. (12) Line Contactor. (13) PTR1 (Pump Transistor one). (14) PD (Pump Diode) Flyback Diode (15) Pump Bypass Contactor. Behind Logic Unit 17 18 19 20 21 16 25 24 23 22 Components Behind Logic Unit (1) (16) Head Capacitor. (17) Drive Board. (18) DTR2 (Drive Transistor Two). (19) Thermal Switch. (20) DD3 (Drive Diode Three) Flyback Diode. (21) DD1 (Drive Diode One) Flyback Diode. (22) Current Sensors. (23) DD2 (drive Diode Two) Plugging Diode. (24) DD4 (Drive Diode Four) Plugging Diode. (25) DTR1 (Drive Transistor One). MicroController Control Systems 16 Systems Operation General Information The speed of the hydraulic pump motor is controlled by switch inputs to and outputs from the logics. Outputs pulses the hydraulic pump power transistor. The power transistor pulse to control the speed of the hydraulic pump motor. To provide full speed the logics turns the power transistor ON 100%. The hydraulic pump system includes a failure protection circuit to protect against malfunctions of the power circuit. The MicroControl Panel is the control center and the Logic Unit (logics) is the decision making part of the MicroController System. The logics provide a self contained Battery Discharge Indicator (BDI) with lift interrupt and built-in diagnostic capabilities. The battery charge state and built-in diagnostic are monitored by the logics and displayed by the Central Vehicle Monitoring System (CVMS) located on the steer console. Thermal protection circuits are used on the hydraulic pump motor, the drive motor and the control panel to prevent permanent damage caused by over heating. NOTICE Damage to all motors and control panels will result. The motors and control panels are 36 volt unit and must be operated at their designed voltage. The voltage can not be changed without changing motors and control panel. Logic Unit The steering system is activated when the truck is powered up and the line contactor closes. The truck uses a combined power steering/hydraulic system where the hydraulic fluid for steering is provided by a DC series hydraulic motor, pump, and priority valve. 1 12 11 10 9 8 The drive motor and the hydraulic pump motor are controlled by pulsing transistors ON and OFF and controlling contactor operation. The speed and direction of the drive motor are controlled by voltage inputs to and outputs from the logics. Inputs to the logics are generated by the accelerator control and direction switch. Outputs from the logics control contactor coils and drive transistor pulsing. 4 3 2 5 6 7 Components on Logic Unit (1) Connector P1 (2) Connector P2 (3) Connector P9 (4) Connector P8 (5) DIAG/RUN/SETUP (6) Jumper JP1 - 36 V (7) Jumper JP2 - 48 V (8) VR1 potentiometer - Drive current limit adjustment (9) VR2 potentiometer - Plugging current limit adjustment (10) VR5 potentiometer - BDI adjustment (11) VR6 potentiometer - Bypass dropout adjustment (12) VR8 potentiometer - Electrical Assist Brake adjustment The drive circuit pulses transistors to provide travel speed control up to 90% of full speed, after which the bypass contactor closes to provide full speed. The drive circuit includes a failure protection circuit which detects malfunctions of the drive power circuit, a plugging circuit to provide electrical braking and a current limit circuit to prevent excessively high currents during transistor pulsing. NOTE: When you change voltage jumper (JP1 JP2), you should do the default setting on page 129. MicroController Control Systems 17 Systems Operation Operational Circuit Elements On Board “Run Time” Diagnostics (Fault Detection) Central Vehicle Monitoring System “Run Time” diagnostics use letters and numbers on the seven segment LCD portion of the CVMS, International Pictorial Symbols and LCD to signal both improper operating sequences and truck circuit defects. The Central Vehicle Monitoring System (CVMS) is located on the steering console. It is a self contained, solidstate instrument panel with two seven segment liquid crystal displays, warning and system condition segments. The LCD consists of seven segments which are turned on or off to form numbers and letters. Display = “EE” Static Return to Off (SRO) The logics has a Static Return to Off (SRO) circuit which assures that the direction switch has been returned to neutral and the accelerator returned to the full up position after the key and seat switch are closed. This safeguards against an accidental actuation of direction and speed when an operator resumes operation of an idle truck. If SRO occurs, the direction lever can be moved to neutral and the accelerator pedal released. The direction can now be reselected and the accelerator pedal depressed to start normal lift truck drive operation. Display = “EE” (Flashing) Seat Circuit Problem Anytime the battery is connected, the key is turned to ON and no one is in the seat longer than 6 seconds the letter “EE” will flash on and off. The truck will not operate until the seat switch is closed. Seven Segment Display Layout The Central Vehicle Monitoring System interacts with the logics and failure detection circuits. It functions as a battery discharge indicator (BDI) and provides on-board diagnostic data on the operational condition of the truck. During normal operation it provides “Run Time” diagnostics, and during troubleshooting it provides “Self” diagnostics. Display = “E1” Drive Motor Brush Problem The logics monitor the length of the brushes in the drive motors. As the brushes wear, a wire built into the brushes moves down and makes contact with the commutator. A wire from each motor brush set is connected to the logics. If any brushes wear down to a preset limit, an “E1” will display on the LCD. Display = “E2” Pump Motor Brush Problem The logics monitor the length of the brushes in the pump motor. As the brushes wear, a wire built into the brushes moves down and makes contact with the commutator. A wire from each motor brush set is connected to the logics. If any brushes wear down to a preset limit, an “E2” will display on the LCD. MicroController Control Systems 18 Systems Operation Display = “EL” Battery Lock-out Display = “F5” Drive System Problem (Left) When the battery is discharged, the CVMS displays “EL” and pump motor will not operate. If key switch turn off and then on, pump will operate for only 3 seconds. Drive motor speed will not exceed 70% of the max. regardless of an accelerator’s output voltage. The logics at P9-5 uses wire #L64 from the emitter of the left drive transistor to detect battery negative. The logics sends a test pulse out to the left drive transistor when power up. This test pulse is detected at P9-5 also. If battery negative is present or the test pulse is not detected, the line contactor will be deactivated and an “F5” will display on the LCD. Display = “F2” Drive System Problem (Left) Display = “F5” (Flashing) Drive System Problem (Right) The logics at P9-5 uses wire #L64 from the emitter of the left drive transistor to detect if the left drive transistor, bypass contactor tips or the driver board are shorted. In normal operation P9-5 has battery voltage only when the logics is pulsing the left drive transistor or the bypass contactor is activated. When a failure occurs the line contactor will be deactivated and an “F2” will display on the LCD. The logics at P9-6 uses wire #R64 from the emitter of the right drive transistor to detect battery negative. The logics sends a test pulse out to the right drive transistor when power up. This test pulse is detected at P9-6 also. If battery negative is present or the test pulse is not detected, the line contactor will be deactivated and an “F5” will flash on the LCD. Display = “F2” (Flashing) Drive System Problem (Right) Display = “F6” Pump System Problem The logics at P9-7 uses wire #74 from the emitter of the pump transistor to detect battery negative. The logics sends a test pulse out to the pump transistor when power up. This test pulse is detected at P9-7 also. If battery negative is present or the test pulse is not detected the line contactor will be deactivated and an “F6” will display on the LCD. The logics at P9-6 uses wire #R64 from the emitter of the right drive transistor to detect if the right drive transistor, bypass contactor tips or the driver board are shorted. In normal operation P9-6 has battery voltage only when the logics is pulsing the right drive transistor or the bypass contactor is activated. When a failure occurs the line contactor will be deactivated and an “F2” will flash on the LCD. Display = “F7” Drive and Pump System Problem Display = “F3” Pump System Problem The logics will release the line contactor and display “F7” on the LCD when BOTH wires #64 and #74 detect battery negative or do not detect the proper pulsing. See “F5”, “F5” (Flashing) and “F6”. The logics at P9-7 uses wire #74 from the emitter of the pump transistor to detect if the pump transistor or the driver board are shorted. In normal operation P9-7 has battery voltage only when the logics is pulsing the pump transistor is activated. When a failure occurs the line contactor will be deactivated and an “F3” will display on the LCD. Display = “FA” Angle Circuit Problem Steer angle commands are monitored by the logics. If steer angle switch has defects or each wires #50, 51, 52 and 53 is shorted/opened, the line contactor will be deactivated and an “FA” will display on the LCD. Display = “F4” Drive and Pump System Problem The logics will release the line contactor and display “F4” on the LCD when BOTH wires #64 and #74 detect battery voltage when it should not be present. See “F2”, “F2” (Flashing) and “F3”. MicroController Control Systems 19 Systems Operation Display = “Fb” Battery Mismatch Central Vehicle Monitoring System (CVMS) International Pictorial Symbols The motors and control panels are 36 volt units and must be operated at 36 volt. If battery condition is abnormal, an “Fb” will display on the LCD. Refer to problem 42 in troubleshooting. Park Brake Symbol Display = “Fd” Pressure Switch Problem The logics at P 2-1 uses wire #41 from the pressure switch to detect if the pressure switch is opened for more than 10 seconds after the key switch ON. The “Fd” will be displayed and the truck will be operated normally. Park Brake Symbol If the park brake is applied, the park brake symbol will turn on to warn the operator that the brake is applied, and drive operation will be prevented. Overtemperature Symbol Normally closed thermal switches are constantly monitored by the logics and the CVMS. All these thermal switches are normally closed, so must open for the LCD to turn on. Truck performance will automatically be cut back by the logics, and the CVMS will light the LCD until the component cools. Control Panel Overtemperature Symbol Control Panel Overtemperature Symbol Two thermal switches (HYD and MAIN control panels) are connected in series to the logics. If any of the control panels overheat, the thermal switch in the center of the positive heatsink will open. The logics will slow lifting speeds and reduce drive speed. Truck acceleration will decrease. The overtemperature symbol and “Ec” will display on until the controller cools. “Ec” will be saved as stored error code. MicroController Control Systems 20 Systems Operation Drive Motor Overtemperature Symbol Wait Mode If the seat switch is closed, key turned to ON and the direction lever is left in neutral with no other operator requests, the line contactor will deactivate after approximately six seconds. The LCD will display “PP”. The lift truck will remain in this condition until the operator activates the direction switch, accelerator pedal or a control valve lever. The line contactor then reactivates and the truck is ready for normal operatation. Drive Motor Overtemperature Symbol Current Sensor The drive motor thermal switch, held against the drive motor field, will open if the motor gets too hot. The logics will reduce drive pulsing and prevent the bypass contactor from pulling in. The truck speed and acceleration will be reduced. The overtemperature symbol and “Ed” will display on until the motor cools. “Ed” will be saved as stored error code. The left current sensor mounts around the cable that carries left drive motor current. The logics supplies a constant voltage to one lead of the current sensor at P1-16 wire #25 (12V). A second lead of the current sensor is connected to battery negative at the negative heatsink. When current passes through the cable, the third current sensor lead wire #L22 causes the voltage to change at logic P1-12. As the current passing through the cable increases, the voltage at logic P1-12 increases. The logics uses the voltage at P1-12 to determine the amount of current flowing through the left drive motor. Pump Motor Overtemperature Symbol The right current sensor, similar to the left current sensor, mounts around the cable that carries right drive motor current. A third lead of the right current sensor is connected to logics at P1-13 #R22. The logics uses the voltage at P1-13 to determine the amount of current flowing through the right drive motor. Pump Motor Overtemperature Symbol Contactors The pump motor thermal switch, similar to the drive motor thermal switch, will open if the motor gets too hot. The logics will reduce pump motor speeds. The overtemperature symbol and “EP” will display on until the pump motor cools. “EP” will be saved as stored error code. MicroController Control Systems The control panel is equipped with intermittent duty contactors. The logics controls the voltage supplied to the coils. When a contactor is first activated, full battery voltage is supplied to the coil. After the contactor tips have closed, the logics will pulse the coil to reduce the voltage across the coil to between 18 and 36 volts. 21 Systems Operation Battery Discharge Indicator (BDI) BATTERY TERMINAL VOLTAGE BAR SYMBOLS The logics monitors the battery voltage during truck operation and shows the level of battery charge on the LCD. If the battery voltage is below 40.0V or above 60.0V, this is a battery mismatch or misconnection. If these voltages are monitored, the display will show “Fb” on the LCD and no lift truck operate. TYPE 1 (OPT) : Closed Voltage DISPLAY Full 6 bars on the LCD indicates a fully charged battery. As the battery discharges, the bars decreases to 5, 4 etc, down to 1st bottom bar. When the battery nears the 80% discharge level, the 1st bar continuously flashes. This is a warning that lift interrupt is near. The operator should complete the current lift operation and travel to the battery replacement or charge area. If the truck is kept in operation, the display go to a “EL”. The lift, tilt and auxiliary functions will be vastly reduced in speed, operating only with steering flows and the vehicle travel speed will be cut in harf. At this point the battery is greater than 80% discharged. The logics will now remember that the battery has been discharged to lift interrupt and require a fully charged battery to reset the remembered interrupt. See Programmable Option Features “3”. 36V 6 above 37.2 5 36.8 to 37.2 4 36.4 to 36.7 3 36.0 to 36.3 2 35.6 to 35.9 1 35.2 to 35.5 1* 25.8 to 35.1 O/EL below 25.8 1* = Display is flashing BATTERY TERMINAL VOLTAGE BAR SYMBOLS TYPE 2 (STD) : Closed Voltage DISPLAY Due to different voltage characteristic of battery technologies, it may be necessary to use the battery voltage chart as shown below. You can choose a type in Programmable Option Features “10”. 36V 6 above 37.2 5 36.8 to 37.2 4 36.3 to 36.7 3 35.9 to 36.2 2 35.4 to 35.8 1 35.0 to 35.3 1* 34.5 to 34.9 O/EL below 34.5 1* = Display is flashing Descriptions of BDI symbol on the LCD Bar Symbols BATTERY TERMINAL VOLTAGE BAR SYMBOLS 6 : The highest position : Max. charged status TYPE 3 (OPT) : Closed Voltage DISPLAY 5: 36V 6 above 37.2 4: 5 36.9 to 37.2 3: 4 36.6 to 36.8 3 36.3 to 36.5 2 35.9 to 36.2 1 35.6 to 35.8 1* 35.3 to 35.5 O/EL below 35.3 2: 1: : A) Not flashing B) Flashing - 80% discharge warning. 1* = Display is flashing MicroController Control Systems 22 Systems Operation Accelerator Control Steer Angle Control Accelerator Table Two drive motors are controlled independently according to steer wheel position. A direction of drive motors is determined with wheel angle as shown in the chart. OUTPUT VOLTAGE REMARKS OVER ACCELERATOR CIRCUIT 11.00 DEFECT 9.60 BYPASS OPERATION DRIVE SPEED (100%) WHEEL 9.02 8.44 7.86 7.28 6.70 6.12 5.54 4.96 4.38 3.80 3.22 2.64 2.06 1.48 0.90 0.00 ANGLE DRIVE SPEED STEP 14 DRIVE SPEED STEP 13 **DEAD ZONE I** DRIVE SPEED STEP 12 DRIVE SPEED STEP 11 ON - TIME(%) P2-17 P2-18 P2-19 P2-20 -90° LOW HIGH HIGH HIGH -75° LOW HIGH HIGH -45° LOW HIGH L 25° LOW +45° HIGH LEFT RIGHT (-)50 50 LOW 0 75 LOW LOW 75 100 LOW LOW LOW 100 100 LOW LOW LOW 100 75 +75° HIGH HIGH LOW LOW 75 0 +90° HIGH HIGH LOW HIGH 50 (-)50 DRIVE SPEED STEP 10 (–) means that the motor will turn opposite direction. DRIVE SPEED STEP 9 DRIVE SPEED STEP 8 DRIVE SPEED STEP 7 DRIVE SPEED STEP 6 DRIVE SPEED STEP 5 DRIVE SPEED STEP 4 DRIVE SPEED STEP 3 DRIVE SPEED STEP 2 DRIVE SPEED STEP 1 DRIVE SPEED STEP 0 **DEAD ZONE II** i) DEAD ZONE I In order to eliminate the bypass contactor chattering, the bypass contactor will be engaged if the accelerator output voltage is over than 9.6V. But the bypass contactor should be disengaged if the accelerator output is less than 9.02V. ii) DEAD ZONE II In order to eliminate the direction contactors chattering, the direction contactors will be engaged if the accelerator output voltage is over than 1.48V. But the direction contactors should be disengaged if the accelerator output is less than 0.9V. MicroController Control Systems 23 Systems Operation Accessory Circuits Horn Circuit The 12 volt output of the converter is protected against short circuits and overloading by an internal 15 amp current limit circuit. A fuse on the converter protects it from reverse connection of the battery voltage. The horn will operate when the battery is connected and the horn button is pushed. Current flows from battery positive through horn fuse, horn switch and horn, back to battery negative. Refer to Problem 31 in Troubleshooting section. Hour Meter Circuit The hour meter, dependent on marketplace, can be wired a number of different ways. Battery voltage is always supplied from the key switch to the positive terminal of the hourmeter. The negative terminal of the hourmeter can go to seat switch to record seat switch hours, or can be wired into the drive motor armature through a diode assembly to record drive motor hours. NOTICE Do not connect the 12volt negative output of the DC-DC converter to battery negative. Damage to system components could occur. DC-DC Converter DC-DC Converter Circuit System The DC-DC converter changes the lift truck battery voltage to 12 volts. This 12 volts is used to power accessories such as floodlights, brakes/side lights and backup alarms. The positive of the 12 volt output is common to the positive of the battery voltage. The negative of the 12 volt output is pulsed to maintain a steady 12 volt supply. MicroController Control Systems 24 Systems Operation Actuation Circuit Actuation Circuit When the battery is connected and the key switch is closed, current flows from battery positive through the key fuse, key switch, wire #5 to the logic connector P1-1 and P1-2. The logic connection to battery negative is at P1-19 and P1-20. The logic circuits are powered up to accept voltage inputs and create voltage outputs whenever the battery is connected and the key is turned to ON. NOTE: The circuit diagrams have shaded lines for illustration of current flow in each circuit. Other circuits can be activated at the same time, but each one is shown separately to illustrate current flow in each individual circuit. This circuit supplies power to the MicroController Control System and the Central Vehicle Monitoring System (CVMS). It must be activated before power steering, hydraulics or drive will operate. MicroController Control Systems 25 Systems Operation The Central Vehicle Monitoring System (CVMS) is also powered at this time. The CVMS first does a “LCD test” which will light all the warning lights through 6 shield wires, wire #101(5V) and wire #108 (B-) for approximately five seconds. Hydraulic Pump Motor Circuit Only one hydraulic pump motor (series winding) is used for all power steering, lift, tilt and auxiliary hydraulic functions. To activate the pump circuit, the seat switch, key switch and line contactor must be closed first as explained in the topic, Actuation Circuit. The logics will start to perform a set of “Run Time” diagnostic checks. The letter “EE” will flash on the CVMS display indicating the key is ON with no operator in the seat. When the seat switch is closed, current will flow from the logic P2-7 through the seat switch to battery negative. The logics then activates the line contactor by allowing current to flow from P1-3 through the line contactor coil and P1-4 back to battery negative. Power Steering Circuit With the line contactor tips closed the logics continues its checks for any “Run Time” faults. If no faults are detected the display will indicate the battery charge level, the power steering (IDLE) system operates, the pump and drive power circuits receive battery voltage and the logics receives battery voltage on wire #4 at P9-9. Followings are standard PTR1 pulsing rates of the signal at the logics. The power steering (PS) circuit has two speeds (PS idle and PS boost-up) independent of the lifting speeds. Motor Speed PTR1 Pulsing Rate Logic Pin# IDLE 11% – 23% P2-1 TILT 50% P2-2 LIFT1 35% LIFT2 50% LIFT3 95% AUX1 50% P2-2 AUX2 45% P2-16 POWER STEERING P2-3 & P2-4 The above pulsing rate can be adjustable in “Programmable Option Features”. NOTE: The circuit diagrams have shaded lines for illustration of current flow in each circuit. Other circuits can be activated at the same time, but each one is shown separately to illustrate current flow in each individual circuit. MicroController Control Systems 26 Systems Operation Power Steering Idle Transistor PTR1 Pulsing TR5 Base Input Signal logics is ON at TR5, TR5 will be ON. When the base signal is OFF, TR5 will be OFF. After the line contactor is closed the logics generates a positive pulsing signal (approximately 0.7 volts) on P9-3 to the base of transistor TR5. This is a rapidly changing signal that can only be viewed on an oscilloscope. Because TR5 is a NPN type transistor, the positive signal into the base causes current flow through the base/emitter junction. When current flows through the base/emitter junction the transistor turns ON and main current will flow through the collector/emitter junction. If the base signal from the MicroController Control Systems 27 Systems Operation TR6 Base Input Signal, TR5 ON When TR5 is ON, current flows through the emitter/base junction of transistor TR6, through PR1 and TR5 to battery negative. Because TR6 is a PNP type transistor, the current flow to battery negative through the emitter/base junction causes TR6 to turn ON. When TR5 is OFF, TR6 is OFF. MicroController Control Systems 28 Systems Operation PTR1 Base Input Signal, TR5 and TR6 ON When TR6 is ON, current flows through TR6 into the base of transistor PTR1. This puts a voltage signal at the base of PTR1 causing PTR1 to turn ON. With PTR1 ON, high amperage motor current can flow through PTR1, motor armature and motor field to battery negative. When TR5 and TR6 are OFF, PTR1 is OFF. The percent “on-time” of the signal at the logics is also the percent “on-time” of PTR1. PTR1 is pulsed at 11% “on-time” supplying 11% of battery voltage to the pump motor (IDLE). MicroController Control Systems 29 Systems Operation Flyback Circuit Flyback Circuit PD is a flyback diode for the power steering and hydraulic motor circuit. This circuit uses the current created by the collapsing magnetic field of the field windings in the pump motor to keep current flowing when transistor PTR1 is OFF. When PTR1 is OFF all current from the field goes through P2, PD, P1 and pump motor armature (ARM) back to the field. When PTR1 is pulsing the flyback circuit causes the average pump motor current to be greater than the average battery current through PTR1. MicroController Control Systems 30 Systems Operation Lift Control Circuit 1 Location of Components (1) Valve control card. This control panel accept a three speed lift control signals and tilt/aux lever signals. The three speed lift control system is controlled by valve control card (1) mounted at the top of the control valve. When the operator pulls the lift lever, magnet (3) moves closer to the lift sensor (2). The sensor detects the increasing magnetic field and sends an increasing voltage to the valve control card. The valve control card produces voltage changes which input to the logics at P2-3 and P2-4 The logics uses these changing voltages to determine what speed to operate the pump motor. The logics then controls the pump transistor PTR1. The pump motor lift speed as shown in the chart. The valve control card uses a hall-effect transducer (LIFT SENSOR) and a magnet to sense lift lever movement. The closer the magnet is to the transducer the greater the hydraulic pump motor speed. 2 Motor Speed P2-3 P2-4 PTR1 Pulse Ratio 0 12V 12V Steering Variable 1 0.2V 12V 35% Pulsing Variable 2 0.2V 0.2V 50% Pulsing Variable 3 12V 0.2V 95% Pulsing - 3 Variable : Set by Option Programmbles Feature. Pump Bypass Contactor (36V only) The Pump Bypass contactor will close at Lift Speed 3 on 36V system. Also this contactor will activate if the Aux2 speed was set at 95% pulsing in option programmable Feature 15. Location of Components (2) Lift Sensor. (3) Magnet. MicroController Control Systems 31 Systems Operation Lift Circuit Lift Circuit When the lift lever is pulled to lift speed 1 the logics will pulse the pump transistors PTR1. If the streeing wheel is turned, hydraulic pressure increases and a pressure switch (PRESSURE SW) located in the steering gear load sensing hose, will open. This causes the voltage at logic connector P2-1 to change from a LOW (less than one volt) to a HIGH (12 volts). When a HIGH is present the logics knows that more hydraulic flow is required and will supply a pulse from P9-3 to PTR1 at rate of 23% “on-time” for 48 volt trucks. The pump motor speed will increase. MicroController Control Systems As shown in the chart under Lift Control Circuit, if the lift lever is pulled to lift speeds 2 through 3 the pump transistors are pulsed with a higher percent “on-time”. The pump motor armature will turn faster. 32 Systems Operation Drive Circuit Control Circuit Drive Control Circuit Selecting a direction will change the voltage from HIGH to LOW on P2-5 for forward or P2-6 for reverse. Depressing the accelerator pedal will cause the accelerator analog voltage on P1-15. With the forward direction selected current flows from the logics P1-3 through forward direction contactor coil to logics P1-5 and P1-7 back to battery negative. The forward contactors tips close. NOTE: The circuit diagrams have shaded lines for illustration of current flow in each circuit. With the actuation circuit complete the logics supplies a HIGH voltage (12volts) to the direction (F/R) switch at P2-5 and P2-6. A HIGH voltage is also supplied to the power of accelerator at P1-16. Releasing the park brake closes the park brake switch and provides a path to battery negative. MicroController Control Systems 33 Systems Operation Power Circuit TR2 and TR4 Base Input Signal The logics generates a positive pulsing voltage (approximately 0.7 volts) on P9-1 and P9-2, to the base of transistors TR2 and TR4. These pulses turn ON TR2 and TR4 which turn ON TR1 and TR3. A more complete description of this transistor turn on circuit can be found in : Hydraulic Pump Motor Circuit under Power Transistor Pulsing. NOTE: The circuit diagrams have shaded lines for illustration of current flow in each circuit. Other circuits can be activated at the same time, but each one is shown separately to illustrate current flow in each individual circuit. The high amperage current, which provides the power and torque necessary to drive the lift truck, flows in this circuit. The speed of the drive motor is controlled separately from the pump motor circuit by the MicroController Control System. MicroController Control Systems 34 Systems Operation Power Transistors, TR1, TR2, TR3 and TR4 all ON The percent “on-time” of the voltage at logics P9-1 and P9-2 is also the percent “on-time” of the power transistors. As the “on-time” increases, the average voltage applied to the drive motor increases which increases the speed of the lift truck. The percent “on-time” out of the logics is determined by how far the accelerator is depressed. When TR1 and TR3 are ON, current flows through TR1 and TR3 emitter/collector into the base of drive power transistors (DTR1 and DTR2). This puts a HIGH voltage at the base of the power transistors causing them to turn ON. With the power transistors ON, high amperage motor current can flow through them, the field, forward contact tips, armatures, forward contact tips and current sensors back to battery negative. When TR1 and TR3 are OFF, the power transistors are OFF. MicroController Control Systems 35 Systems Operation Flyback Circuit Flyback Circuit Because of this, the average drive motor armature current will be greater than the average battery current. Refer to following Average Current Flow chart. When the drive power transistors (DTR1 and DTR2) are ON, battery current flows through the field windings of the drive motor and a magnetic field is created around the windings. When the power transistors are turned OFF battery current through the windings stops and the magnetic field collapses. This collapsing magnetic field induces current which is used to power the drive motor while the power transistors are OFF (during pulsing). Induced current flows from the field windings through the forward contact tips, armature, forward contact tips, current sensor and diodes DD1, DD3 back to the field windings. MicroController Control Systems 36 Systems Operation Average Current Flow Current Limit through the sensor and will increase or decrease as current changes. The logics uses this voltage to monitor the current in the circult. When the current has increased too high, the logics decreases the pulse rate to the transistors to prevent current higher than the preset value. The logics monitors the current that flows through DTR1 and DTR2 and limit this current flow to a preset value. As this current flows through DTR1 and DTR2 the drive motor and the current sensors, a voltage is created by the sensor. This voltage is proportional to the current flowing MicroController Control Systems 37 Systems Operation Bypass Circuit Bypass Circuit Activated The bypass circuit bypasses DTR1 and DTR2 and connects the drive motor in series with the battery, applying full battery voltage to the drive motor. If the accelerator pedal is fully depressed, and the logics has pulsed DTR1 and DTR2 through 92% “on-time”, the logics will activate the BYPASS CTR after 1.5 seconds. MicroController Control Systems 38 Systems Operation Electrical Braking (Plugging) Plugging Circuit (Transistor DTR1, DTR2 “ON”) When DTR1 and DTR2 are ON, battery current flows through DTR1 and DTR2, field windings, direction contactor tips, armature, direction contactor tips and current sensor back to the battery. Current energizes the field and tries to turn the armature opposite the rotation caused by the truck’s motion. The current acts to electrically brake the truck. With the field energized and momentum of the truck turning the armature opposite the pulsed direction, the armature generates current. Plugging is an electrical braking mode which permits the lift truck operator to slow, stop and change the direction of travel electrically without using the service brake. Plugging begins when the operator selects a direction opposite the lift truck’s motion, while keeping the accelerator depressed. The logics will deactivate the bypass contactor (if activated) and change the direction contactors to the new direction selected. The momentum of the truck causes the drive motor to generate current, and the logics will puise the transistors at a slow rate. MicroController Control Systems 39 Systems Operation Plugging Circuit (Transistor DTR1, DTR2 ”OFF”) back to the field. This current continues the electrical braking action. As long as the truck momentum is turning the armature opposite the pulsed direction, the motor continues to act as a generator with armature generated current flowing through DD2, DD4 back into the armature. When the truck has come to a stop, the armature no longer is turning opposite the pulsed direction. The armature stops generating current and DD2, DD4 no longer conducts. The logics no longer detects a more negative voltage on plug sensing wire #32 than on wire #1, so normal drive operation begins in the opposite direction. The generated current flows from the armature through the direction contactor, current sensor and diode DD2, DD4, back to the armature. When armature generated current flows through DD2, DD4 wire #1 at P1-20 becomes a more positive voltage than plug sensing wire #32 at P1-10, P1-11, due to the voltage drop across DD2, DD4. The logics detects the voltage change at P1-20 and P1-10, P111, then reduces the tansistor pulsing to stay below the preset plugging current limit. When DTR1 and DTR2 are OFF, flyback current from the collapsing motor field flows through the direction contactor tips, armature, direction contactor tips, current sensor and diode DD1, DD3, MicroController Control Systems 40 Systems Operation Thermal Protection Circuits Control Panel Hydraulic Pump Motor If the power transistors overheat, a thermal switch mounted in the transistor heatsink will open at a predetermined temperature. When it opens, voltage at logic connection P2-11 will go HIGH (12 volts). The Central Vehicle Monitoring System will display a “Run Time” diagnostic symbol. The logics will decrease the pulsing of the drive system and restrict the hydraulic circuit pulsing to 50%. The amount of current allowed to flow through the power transistors is decreased to permit them to cool. When the heatsink cools off and the thermal switch closes, the truck will return to normal operation. Drive system bypass is not affected by an overheated control panel, but due to the reduced pulsing acceleration performance will be decreased. An “Ec” is stored in memory. If the hydraulic pump motor overheats a thermal switch mounted in the pump motor housing will open at a predetermined temperature. When it opens, voltage at logic connection P2-13 will go HIGH. The Central Vehicle Monitoring System will display a “Run Time” diagnostic symbol. To decrease the amount of current allowed to flow through the pump motor, the logics will reduce the hydraulic pump motor to 50% pulsing. When the hydraulic pump motor cools off and the thermal switch closes, the truck will return to normal operation. An “EP” is stored in memory. Failure Protection Circuit If the logics detects an improper voltage at P9-5 wire #L64 (left drive circuit) and/or P9-6 wire #R64 (right drive motor) or P9-7 wire #74 (pump circuit), the line contactor will be deactivated and a “Run Time” diagnostic code (display = “F2” through “F7”) will display. Current is also monitored in the drive motor, and should it exceed preset limits in either pulsing or bypass the truck will shut down and display an “F0”. The logics will monitor the four steering angle switch signals, wires #50, 51, 52 and 53 to determine if there is an out of sequence problem. An “FA” will be displayed if this should occur. If the battery voltage is mismatched, the “Fb” will display. The logics will monitor the two current sensor signals, wires #L22 and #R22 to determine if there is an wrong voltage pattern. An “F5” will be displayed. Once a failure has been detected the truck must be repaired before normal operation can resume. Drive Motor If the drive motor overheats a thermal switch mounted in the drive motor housing will open at a predetermined temperature. When it opens, voltage at logic connection P2-12 will go HIGH. The Central Vehicle Monitoring System will display a “Run Time” diagnostic symbol. To decrease the amount of current allowed to flow through the drive motor, the logics will reduce the pulsing and disable the bypass contactor. When the drive motor cools off and the thermal switch closes, the truck will return to normal operation. Drive system acceleration performance and top travel speed is affected by an overheated drive motor. An “Ed” is stored in memory. MicroController Control Systems 41 Systems Operation Testing And Adjusting Troubleshooting NOTICE Damage can be caused to the control panel. Do not switch the direction lever from one direction to the other (plug the lift truck) when the drive wheels are off the ground and in rotation at full speed. The following Troubleshooting Check List is an aid in troubleshooting MicroController lift trucks. The troubleshooting check list, “Run Time” diagnostic indications, “Self” diagnostic tests, problem list and problem flow charts will assist in: 1. Defining the problem and verifying a problem exists. Troubleshooting Check List 2. Performing the checks in a logical order. 1. Perform Preparation Tests and Checks. 3. Making the necessary repairs. 2. Correct any display problems and “Run Time” diagnostic faults. 4. Verifying the problem has been resolved. 3. Correct the “Self” diagnostic faults. 4. Perform Operational Checks. WARNING The lift truck can move suddenly.Battery voltage and high amperage are present. Injury to personnel or damage to the lift truck is possible. Safely lift both drive wheels off the floor. Put blocks of wood under the frame so the drive wheels are free to turn. During any test or operation check, keep away from drive wheels. Before any contact with the control panel is made, disconnect the battery and dis- charge HEAD CAP. Ring's, watches and other metallic objects should be removed from hands and arms when troubleshooting, the MicroController Control System. 5. Correct “Failure Code Problems” in the Troubleshooting Problem List. NOTICE Damage can be caused to the test equipment. Make resistance and continuity checks only after the battery is disconnected. 1. Verify proper polarity at the battery connector and the MicroController panel. Positive cable should be at the line contactor and negative at the negative heatsink. 6. Perform Operational Checks to verify repairs. Preparation Tests and Check Battery Tests A weak battery can cause or contribute to problems in the MicroController and power circuits. Verify the battery is good before investigating other possibilities. 2. If the lift truck is operational, perform a battery load test. 3. If the truck is not operational and the battery is suspected, perform a cell voltage or specific gravity test. NOTICE Damage can be caused to the control panel. Do not use steam or solvent to clean the controls. Use pressure from an air hose with a maximum pressure of 205 kPa (30 psi) to clean the control panel when necessary. Make sure the air pressure supply is equipped with a water filter. MicroController Control Systems 42 Testing And Adjusting Battery Load Test Cell Voltage Test 1. Turn the range switch on the multimeter to read battery voltage. With the truck powered up and the power steering motor running, measure the voltage at each cell. Normal voltage should be between 1.95V and 2.12V per cell. If the voltage on each cell is below 1.95V the battery must be charged or repaired before continuing to troubleshoot. 2. Connect the battery. NOTE : The indication between cells should not differ more than 0.05 volts. If it does, the battery must have an equalizing charge or be repaired. Hydrometer Test 1 2 Test each cell of the battery with a hydrometer. If the specific gravity indication is below 1.140, the battery must be charged. The battery is fully charged if the indication is 1.265 to 1.285. Battery Voltage Test (1) Positive cable connection (2) Negative cable connection NOTE : The indication between cells should not differ more than .020. If it does, the battery needs an equalizing charge or needs to be repaired. 3. Connect the multimeter leads between positive (+) cable connection (1), and negative (-) cable connection (2). 4. In a safe area, operate the hydraulic system, (hold tilt lever to maximum position momentarily) while reading the voltage indicated on the multimeter. Battery Maintenance NOTE : It is important that all batteries be charged and maintained according to the battery manufacturers instructions. 5. If the indication is less than 44.2 volts, the battery needs to be charged or repaired before continuing to troubleshoot. The care and maintenance of batteries is most important to maximize battery life and efficient truck operation. Periodic inspection and service will increase the life of batteries. Special attention should be given to the rules that follow: 1. Keep batteries clean at all times. Cleaning will prevent corrosion, current leakage and shorts to chassis. Tighten all vent plugs, wash the battery with water and a brush, then dry with an air hose. It may be necessary to use a baking soda solution if water alone will not clean the top of the battery. 2. Add enough water to cover the plates before charging. This will ensure the proper chemical reaction over the entire plate surface. After charging is complete, add water until it is about 12.7 mm (.50 in) above the plates. Use distilled water or water that has tested free from minerals. MicroController Control Systems 43 Testing And Adjusting switch and accelerator linkage for adjustment or interference problems. 3. Charge the battery correctly. A battery should be discharged to 80% of its capacity then fully recharged. It should cool four to eight hours to allow the voltage to stabilize before being put back in use. The battery should have an equalizing charge (an extra three or four hour charge at a low finish rate) once a month to make sure all cells are in a fully charged condition. Properly charged batteries should be identified to prevent low batteries from being installed in trucks. Resistance to Chassis Checks Resistance between any point in the truck wiring and the chassis should be a minimum of 10,000 ohms or more. Many malfunctions are caused by shorts to chassis. Usually, two shorts must exist before a malfunction will occur. But, since batteries can have chassis leakage, only one short to chassis in the truck wiring can cause problems. To prevent problems because of shorts, do the following: 4. Operation with a low battery must be prevented. Low battery operation may damage the battery and will cause higher than normal current in the electrical system. High current draw due to a low battery will damage contactor tips and shorten motor brush life. 1. Disconnect the battery and discharge the HEAD CAP. 5. The battery's maximum temperature is critical. The electrolyte temperature should never exceed 43°C (110˚F) either while operating or charging. Overcharging a battery will cause over heating and warp the battery plates. Maximum battery life will result from maintaining 25˚C (77˚F) electrolyte temperature. Most of the charging equipment is fully automatic but should be checked periodically to assure proper working order. 2. Randomly measure any component connection or wiring connection in respect to the lift truck chassis for a minimum resistance of 10,000 ohms. Any test point with low resistance must have the short to chassis removed. 3. Always keep batteries clean to minimize current leakage to the chassis. 6. Keep accurate battery records. Regular battery readings should be taken with a battery tester or voltmeter and a written record kept. Specific gravity and voltage of each cell should be checked and recorded at least once each month. This inspection should be made after an equalizing charge. Readings should never be taken directly after water has been added. Records of all battery maintenance should be made and filed so it will be known which batteries are being abused or wearing out. 4. Routinely clean the brush dust from the motors. 5. Be sure that all attachments, such as horns and lights are designed for no chassis connection (a two wire system). Removal of Shorts to Chassis When a short is found, it must be cleared even if the machine has normal operation. It is necessary to narrow the field of possible problem areas before inspection of individual wires and components. Repairs should be made immediately otherwise the battery may become damaged. Batteries stored in a discharged condition may be difficult to recharge due to sulfate formation. When a low resistance circuit is located, it should be opened at various points. This will permit the shorted wire or component to be pin-pointed for repair or replacement. Visual Checks 1. Verify all components and wires are in their proper place. Check fuses, components, contactor tips, wires and connections. Verify that they are not burned, broken or loose. 2. Verify there is no mechanical binding or interference in the contactors. 3. Visually check the parking brake switch, the lift MicroController Control Systems 44 Testing And Adjusting Control and Power System Operational Checks All operational checks are to begin with the battery connected, directional switch in neutral, drive wheels off the ground and the accelerator and parking brake released. 4. Depress the accelerator fully. The forward contactors should remain activated. The bypass contactors should activate. The drive wheels will turn forward at full speed. NOTE: Perform all operational checks before returning to the Troubleshooting Check List. Check 5: Reverse Drive Performance Check 1: Key Switch, Seat Switch and Power Steering 1. Select reverse direction and depress the accelerator slightly. The reverse contactors should activate and the drive wheels should turn in reverse slowly. 1. Activate the key and seat switch. The line contactor activate and the hydraulic pump motor should turn on at slow speed (idle). 2. Slowly increase the amount of accelerator depression. The reverse contactors should remain activated. The drive wheels should turn in reverse and slowly increase in speed. 2. Turning the steering wheel will increase the hydraulic pump motor speed (boost-up). 3. Depress the accelerator fully. The reverse contactors should activated. The bypass contactors should activate. The drive wheels will turn in reverse at full speed. 3. After five to ten seconds the line contactor deactivates and the motor turns off. Check 2: Lift Performance Check 6: Electrical Braking (Plugging) Performance 1. Pull the lift lever half way. The hydraulic pump motor activates slowly to a preset speed. 2. Pull the lift lever to maximum. The hydraulic pump motor activates full speed. NOTICE Do not perform this check with the lift truck in bypass mode. Damage to the Drive Train can result. Check 3: Tilt and Auxiliary Performance 1. Slowly pull and push the tilt and auxiliary levers. The hydraulic pump motor activates to one of the preset speeds with each lever movement. 1. Select forward direction and depress the accelerator to the point before bypass occurs. While continuing to depress the accelerator, change the direction switch to reverse. The forward contactors should deactivate and the reverse contactors should activate. There should be a smooth deceleration of forward tire rotation. After the forward tire rotation stops, there is a smooth acceleration of reverse tire rotation. Check 4: Forward Drive Performance 1. Engage the parking brake. Select forward direction and depress the accelerator slightly. The forward contactor should NOT activate and the drive wheels should NOT turn. 2. Release the parking brake, select forward direction and depress the accelerator slightly. The forward contactors should activate and the drive wheels should turn forward slowly. 2. Continue to depress the accelerator while in reverse direction. Change the direction switch to forward. The reverse contactors should deactivate and the forward contactors should activate. There should be a smooth deceleration of reverse tire rotation. After the reverse tire rotation stops, there is a smooth acceleration forward tire rotation. 3. Slowly increase the amount of accelerator depression. The forward contactors should remain activated. The drive wheels should turn forward and slowly increase in speed. MicroController Control Systems 45 Testing And Adjusting Built-In Diagnostic Operation Display =“Ec” Lift truck will not operate, see Troubleshooting Problem 20. Possible cause, control panel thermal problem. The overtemperature indication will display on LCD. The logics and the display provide built-in diagnostic analyzer functions. Several diagnostic functions occur while the lift truck is in operation. These are called “Run Time” diagnostics. The other diagnostics are called “Self” diagnostics. They are performed when the lift truck is not in operation by using a switch located in the logics. Display =“Ed” Lift truck will not operate, see Troubleshooting Problem 21. Possible cause, drive motor thermal problem. The overtemperature indication will display on LCD. Central Vehicle Monitoring System (CVMS) Problems Display =“EP” Lift truck will not operate, see Troubleshooting Problem 22. Possible cause, pump motor thermal problem. The overtemperature indication will display on LCD. If the display does not work, or it’s operation seems incorrect see Troubleshooting Problems 1, 2, 3 and 4. Display =“EL” Lift truck will not operate, see Troubleshooting Problem 23. Possible cause, low battery voltage. “Run Time” Diagnostics (Lift Truck in Operation) Display =“F0” Lift truck operates, then shuts down during travel. See Troubleshooting Problem 32. Possible cause, excessive currents in drive motor. The diagnostic functions that follow would occur during normal lift truck operation and are shown on the seven segment display. Display =“F2” Lift truck will not operate, see Troubleshooting Problem 33. Possible cause, a failed left drive power transistor (DTR1). NOTE: Improper lift truck operation with normal battery indication, should be checked with “Self” diagnostics. Display =“F2” (Flashing) Lift truck will not operate, see Troubleshooting Problem 34. Possible cause, a failed right drive power transistor (DTR2). Display =“F3” Lift truck will not operate, see Troubleshooting Problem 35. Possible cause, a failed pump power transistor (PTR1). Display =“F4” Lift truck will not operate, see Troubleshooting Problem 36. Possible cause, failed pump and drive power transistors. Display =“F5” Lift truck will not operate, see Troubleshooting Problem 37. Possible cause, left drive flyback diode DD1 failed. Display Layout Display =“EE” No Lift truck operation, see Troubleshooting Problem 17. Possible cause, static return to off. Display =“F5” (Flashing) Lift truck will not operate, see Troubleshooting Problem 38. Possible cause, right drive flyback diode DD3 failed. Display =“EE” (Flashing) Lift truck will not operate, see Troubleshooting Problem 18. Possible cause, seat switch open. Display =“F6” Lift truck will not operate, see Troubleshooting Problem 39. Possible cause, pump flyback diode PD failed. Display =“E1” or “E2” Lift truck will operate, see Troubleshooting Problem 19. Possible cause, pump or drive brush problem. MicroController Control Systems 46 Testing And Adjusting Display =“F7” Lift truck will not operate, see Troubleshooting Problem 40. Possible cause,pump and drive flyback diodes (DD1,DD3 and PD) failed. Display =“FA” Lift truck will not operate, see Troubleshooting Problem 41. Possible cause, steer angle switch failure or harness problem. Display =“Fb” Lift truck will not operate, see Troubleshooting Problem 42. Possible cause, abnormal battery condition. Display =“Fd” Lift truck will operate, see Troubleshooting Problem 43. Possible cause, pressure switch failure or harness problem. MicroController Control Systems 47 Testing And Adjusting “Self” Diagnostics (Lift Truck not in Operation) 3 The diagnostic procedure should be used to aid in troubleshooting after a problem occurs. It will help to find the faulty circuit or component. Complete all the tests before returning to the MicroController Troubleshooting Check List. Before testing, do the steps that follow : 2 1. Turn the key to off. 2. Disconnect the battery and discharge the head capacitor below 5 volts by holding the discharge resistor in place for 10 seconds. Removing Cover from Logic Unit (Logics) (2) Screws. (3) Cover. 5. Loosen four screws (2) to remove logic cover (3). 4 1 Location of Fuse (1) Line fuse 3. Disconnect line fuse (1) to prevent lift truck movement. DIAG/RUN/SETUP Switch Location (4) Switch. WARNING 6. Move switch (4) to “DIAG” position. This places the controller in diagnostics when the battery is connected and key is turned to ON. The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Disconnect the battery and disconnect the line fuse to prevent lift truck movement. 4. Release the parking brake to close the park brake switch. MicroController Control Systems 48 Testing And Adjusting 7. Connect the battery and turn key to ON. Test 4 : Lift Switch Circuit Display = “blank” See Troubleshooting Problems 1 or 2. Pull lift lever slowly. Display now shows the speed that the lift lever is set to. As lever is pulled back, 0 through 3 will be shown. Display = “F” Logics has a failure. Replace logics. This indicates at what position the lift lever changes the pump motor speed. Display = “d” Line fuse is not disconnected or discharge the head capacitor. Return to step 2. If still “A0” lift switch circuit defect, see Troubleshooting Problem 10. Test 5 : Tilt Switch Circuit Display = “8b” Direction lever is in the reverse position. Move direction lever to neutral. Pull tilt lever to maximum. Display = “A6” Tilt switch circuit OK. NOTE: This test does not check all the logics circuit, so the logics may pass this test and still have a failure. Release tilt lever. Display = “A0” Tilt switch circuit OK. The LCD will display all symbols about 2 seconds. Display = “A0” Ready for test 1. If still “A0” or “A6”, tilt switch circuit defect, see Troubleshooting Problem 11. Test 1 : Seat Switch Test 6 : Auxiliary Switch Circuit Press seat to close seat switch. Display = “A1” Seat switch circuit OK. Pull auxiliary lever to maximum. Display = “A7” Auxiliary switch circuit OK. Release seat to open seat switch. Display = “A0” Seat switch circuit OK. Release auxiliary lever. Display = “A0” Auxiliary switch circuit OK. If still “A0” or “A1”, see Troubleshooting Problem 8. If still “A0” or “A7”, auxiliary switch circuit defect, see Troubleshooting Problem 12. Test 2 : Reverse Direction Switch Test 7 : Parking Brake Switch Move direction switch from neutral to reverse. Display = “A2” Direction switch circuit OK. Pull park brake lever to maximum. Display = “A9” Park brake circuit OK. Move direction switch from reverse to neutral. Display = “A0” Direction switch circuit OK. Release Park brake lever. Display = “A0” Park brake circuit OK. If still “A0” or “A1”, see Troubleshooting Problem 9. If still “A0” or “A9”, Park brake circuit defect, see Troubleshooting Problem 13. Test 3 : Forward Direction Switch Move direction switch from neutral to forward. Display = “A3” Direction switch circuit OK. Move direction switch from forward to neutral. Display = “A0” Direction switch circuit OK. If still “A0” or “A3”, see Troubleshooting Problem 9. MicroController Control Systems 49 Testing And Adjusting Test 8 : Accelerator Control Press accelerator pedal to maximum. Display = The speed symbols will increase from 0 to 10 on the LCD, Accelector circuit OK. 6 7 Release accelerator pedal. Display = The speed symbols will decrease from 10 to 0 on the LCD, Accelector circuit OK. If the speed symbols is not full on the LCD, see Troubleshooting Problem 14. Test 1 through 8 may be checked without sequence and there are repeatable checkings to adjust switches and levers. 8 Contactor Locations (6) Bypass contactor. (7) Right direction contactor. (8) Left direction contactor. 36V Contactor Test Test 9 through 14 may be activated in regular sequence by movement of the DIAG/RUN/SETUP (4) to “Run” then back to “Diagnostic” position, and “AC” will display on the LCD. Test 9 : Line Contactor Test 10 : Bypass contactor 5 Test 11 : Left Forward Direction Contactor Test 12 : Right Forward Direction Contactor Contactor Locations (5) Line contactor. Test 13 : Left Reverse Direction Contactor Test 14 : Right Reverse Direction Contactor Test 15 : Pump Bypass Contactor (36V only) If the above actions do not occur, see Troubleshooting Problem 15. This completes the built-in diagnostic test. Contactor test may be repeated contiune by movement of the DIAG/RUN/SETUP to “Run” then back to “Diagnostic” position. After running through the contactor testing, pull tilt lever and then release to netural position will access the stored error codes. See Accessing Stored Error Codes. MicroController Control Systems 50 Testing And Adjusting Accessing Stored Error Codes Saving Service Records The B18T series of trucks remembers the last 24 error codes. This is useful in case the truck has had an intermittent problem, but the operator cannot remember which code appeared on the display. Also by analyzing the contents of the last 24 error codes, it may be possible to determine what sort of application the truck has been working in. To save service records, the following procedures are used at the end of self diagnostics and service records are numbered from 1 to 9. 1. Access all of the error codes until display shows static “E” on the LCD. 2. Move the direction lever to the forward then display will show static “8d”. The stored error codes are accessed at the end of diagnostics by using the following procedure: 3. Move the DIAG/RUN/SETUP switch to “SETUP” and back to “DIAG” two times. 1. Access the self diagnostics procedure as usual. 2. Either step through the self diagnostics procedure, or override each test by moving the DIAG/RUN/SETUP switch from DIAG to RUN and back to DIAG until the contactor testing is completed. 4. Pull the tilt lever to maximum position and then release. 3. Cycle the DIAG/RUN/SETUP switch once more, and cycle through the contactor testing again. After the right reverse contactor drops out, now the display will indicate a “AC”. 6. Wait until the display will show a flashing “8d”, the display indicates that a service record have been saved. 5. A saved service records will show for a few second. 7. Turn OFF the key switch. The error codes can now be accessed one at a time by pulling tilt lever and then release. This will display the most recent error code. By cycling the tilt lever more times, more error codes will appear on the display, up to a total of 24. When the display shows a solid “E”, it will indicate that all of the stored error codes have been displayed. It is possible that the “E” will appear immediately, indicating no error codes have been encountered. Erased Stored Error Codes To erase all of the error codes, the following procedures are used at the start of self diagnostics. 1. Move the direction lever to the reverse and the DIAG/RUN/SETUP switch to the DIAG position. 2. Turn on the key switch and wait until display shows a solid “8b”, then move the DIAG/RUN/SETUP switch to the SETUP position and back to DIAG two times. 3. Move the direction lever to neutral. 4. Wait until the display will show a “A0”, the display indicates that all error codes have been erased. 5. Turn off the key switch. MicroController Control Systems 51 Testing And Adjusting Stored Error Codes Quick Diagnostic Procedure The following are possible error codes stored in memory. Most error codes are identical to the ones displayed during RUN. An alternative method of entering diagnostics has been programmed into the logics. This will enable quick diagnostics of some of the components without removing the controller room, line fuse, or placing the DIAG/RUN/SET switch to the “Diagnostic” position. Contactors and seat circuit will NOT be energized. E1 : Drive motor brush problem. E2 : Hydraulic motor brush problem. Ec : Control panel thermal problem. Ed : Drive motor thermal problem. EL : Battery lock out. EP : Pump motor thermal problem. F0 : Excessive drive motor current in pulsing or bypass operation. F2 : Left drive problem, voltage on left drive transistor emitter (wire #L64). F2 (Flashing) : Right drive problem, voltage on right drive transistor emitter (wire #R64). F3 : Pump problem, voltage on pump transistor emitter (wire #74). F4 : Both F2 and F3 problems together. F5 : Left drive problem, no voltage on left drive transistor emitter (wire #L64). F5 (Flashing) : Right drive problem, no voltage on right drive transistor emitter (wire #R64). F6 : Pump problem, no voltage on pump transistor emitter (wire #74). F7 : Both F5 and F6 problems together. FA : Steer angle problem. Fb : Battery mis-match. Fd : Pressure switch problem. MicroController Control Systems To enter quick diagnostics, open the seat switch and place the direction lever to forward and ensure that the park brake is released. While depressing the accelerator to maximum position other than OFF, and key switch to ON. Display will go to a solid “A3” and the speed symbols will increase from 0 to 10 on the LCD, indicating that you have entered diagnostics and you are ready for Test: You can test the direction control lever, all hydraulic levers, the park brake switch and the accelerator. See Built-In Diagnostic Operation on page 50-52. NOTE : This test enables a salesman to demonstrate some of the diagnostic procedure without ever having to open up the controller room. 52 Testing And Adjusting Troubleshooting Problem List TROUBLESHOOTING PROBLEM LIST Problem # CENTRAL VEHICLE MONITORING SYSTEM (CVMS) PROBLEMS 1 CVMS does not work, with no lift truck operation. 2 CVMS does not work at all, lift truck operation normal. Display portion of CVMS seems random or wrong. 3 4 Lift truck operation normal. Display portion of CVMS works until seat switch is closed then blank, no lift truck drive or pump motor operation. “SELF” DIAGNOSTIC PROBLEMS 5 Display = “d”, no lift truck operation or “Self-diagnostics” operation. 6 Display = “F”, no lift truck operation. 7 Display = “8b”, no lift truck operation. 8 Seat switch circuit defect. 9 Direction switch circuit defect. 10 Lift switches circuit defect. 11 Tilt switch circuit defect. 12 Auxiliary switch circuit defect. 13 Park brake switch circuit defect. 14 Accelerator circuit defect. 15 Incorrect contactor operation. 16 Any contactor closes when key switch is activated. “RUN TIME” DIAGNOSTIC PROBLEMS 17 Display = “EE”, no lift truck drive operation. 18 Display = “EE” (Flashing), no lift truck drive operation. 19 Display = “E1”, or “E2” lift truck operation normal. 20 Overtemperature is ON and display = Lift truck accelerates slower than normal. Lifting speed is slower than normal. Overtemperature is ON and display = 21 Bypass contactor will not close. Pump and steering operation normal. Acceleration slow. Overtemperature is ON and display = 22 Lifting speed slow. Drive and power steering operation normal. 23 Display = “EL”. No hydraulic (lift and tilt). Steering normal. 24 Hourmeter does not work. 25 Normal hydraulic operations, display is normal and no drive operations. 26 Current limit adjustment cannot be made. 27 Slow steering, but pump motor does turn. Drive system operation normal. Pump motor runs continously when neutral is selected. Pump motor turns at high power steering 28 speed continuously. Drive motor does not operate or operates with low power or is erratic. 29 30 Pump and power steering systems operation normal. Horn does not function correctly. Lift and drive operation normal. Auxiliary lighting and/or alarm does not function correctly. 31 Lift and drive operation normal. MicroController Control Systems 53 Testing And Adjusting TROUBLESHOOTING PROBLEM LIST Problem # FAILURE CODE PROBLEMS 32 Display = “F0”, no lift truck operation. 33 Display = “F2”, no lift truck operation. 34 Display = “F2” (Flashing), no lift truck operation. 35 Display = “F3”, no lift truck operation. 36 Display = “F4”, no lift truck operation. 37 Display = “F5”, no lift truck operation. 38 Display = “F5” (Flashing), no lift truck operation. 39 Display = “F6”, no lift truck operation. 40 Display = “F7”, no lift truck operation. 41 Display = “FA”, no lift truck operation. 42 Display = “Fb”, no lift truck operation. 43 Display = “Fd”, lift truck operation normal. MicroController Control Systems 54 Testing And Adjusting PROBLEM 1 Central Vehicle Monitoring System (CVMS) does not work, with no lift truck operation. POSSIBLE CAUSE Battery polarity not correct on control panel; Key fuse open circuit; Key switch defect; Logics defect. CHECKS With battery connected, check control panel battery connections for correct polarity. Positive battery connected to line contactor and negative battery connected to negative heatsink. If correct If not correct Push horn buttton to close horn switch. Make correction to cables. Horn work Horn does not work Does CVMS pass self test at actuation of key and seat switches. Yes Disconnnect battery and check the horn fuse for continuity. NO Continuity See Problem 2, CVMS does not work, lift truck operation normal. Check for shorts and replace fuse. Check continuity from horn fuse holder to control panel battery positive connection at the line contactor. Also check continuity from key fuse holder to wire #3 on key switch Close key switch. Measure voltage on P1-1 and P1-2. Battery voltage No continuity Less than Battery voltage Continuity Replace key switch or repair broken wire #5 between key switch and P1-1 and P1-2. Repair horn circuit. No continuity Repair or replace open wire. Check continuity from negative heatsink to logics P1-19 and P1-20. Continuity Replace logics. No continuity Repair or replace open wire. MicroController Control System 55 Troubleshooting PROBLEM 2 CVMS does not work at all, lift truck operation normal. If only part of CVMS works, replace the CVMS. POSSIBLE CAUSE Disconnected logic connector P8; Open circuit from P8-1 to CVMS connector PIN 1; Open circuit from P88 to CVMS connector PIN 8; CVMS defect. CHECKS Make sure CVMS connector is connected to CVMS. If connected If not connected Connect multimeter positive lead to P8-1 wire #101 and negative lead to P8-8 wire #108. Measure the voltage. 5 volts Replace the CVMS module. MicroController Control System Connect CVMS connector. 0 volt Repair or replace open circuit between 8 wires from logics to CVMS. 56 Troubleshooting PROBLEM 3 Display portion of the CVMS module seems random or wrong. Lift truck operation normal. POSSIBLE CAUSE Connection defect; Wiring defect; Logics defect; Display defect. CHECKS Check continuity from logics to CVMS connector (wire #101/WH/YL/GN/BU/BK/RD/108). Continuity No Continuity Check for shorts to battery negative from PIN 2 to PIN 7 on CVMS connector. No shorts found Repair or replace open wire. Shorted Replace logics. MicroController Control System Repair or replace shorted wire. 57 Troubleshooting PROBLEM 4 Display portion of CVMS works until seat switch is closed then blank, no lift truck drive or pump motor operation. POSSIBLE CAUSE Line contactor defect; Line fuse open circuit; Wire #4 at P9-9 open circuit; Logics defect. CHECKS Does the line contactor close and remain closed ? Yes No Check voltage at bottom of line fuse with line contactor activated. Battery voltage See Problem 15. Incorrect contactor operation. Less than Battery voltage Check voltage at top of line fuse with line contactor activated. Battery voltage Repair or replace line contactor tips or power connections. Less than Battery voltage Check voltage at logic connector P9-9, wire #4 with line contactor activated. Less than Battery voltage Battery voltage Replace logics. MicroController Control System Check for possible shorts in the power circuit (Head Capacitor, diode, shorted cables) and replace line fuse. If repeat failures occur, check drive motor current limit and/or lift truck application. Repair open circuit between line fuse and P9-9, wire #4. 58 Troubleshooting PROBLEM 5 Display = “d”, no lift truck or “Self-diagnostics” operation. POSSIBLE CAUSE Logic DIAG/RUN/SETUP switch in DIAG position with line fuse installed; Head capacitor not discharged below 5 volts; Logics defect. CHECKS Trying to run “Self-Diagnostics” ? Trying to operate lift truck ? Disconnect battery, discharge head capacitor below 5 volts, remove line fuse, set DIAG/RUN/SETUP switch to DIAG position, reconnect the battery and recycle key switch. Display remains at “d” Measure voltage on P9-9. Disconnect battery, remove logic cover, set DIAG/RUN/SETUP switch to RUN position, reconnect the battery and recycle key switch. “Self-diagnostic” Operation OK Display remains at “d” Continue with “SelfDiagnostics” operation. Replace logics. Lift Truck Operation OK Place lift truck into operation. Below 5V. Replace logics. MicroController Control System 59 Troubleshooting PROBLEM 6 Display = “F”, no lift truck operation. POSSIBLE CAUSE Wiring defect; Logics defect. CHECKS With the key on, check the voltage at logic P1-1 and P1-2, wire #5. Battery voltage No voltage Check continuity from control panel battery negative to logic P1-19 and P1-20. Continuity Replace logics. Repair or replace open wire. No continuity Repair or replace open wire. MicroController Control System 60 Troubleshooting PROBLEM 7 Display = “8b”, no lift truck operation. POSSIBLE CAUSE Wiring defect; Direction switch defect; Logics defect. CHECKS Does the DlAG/RUN/SETUP switch in “Diagnostic” position ? NO YES Does the direction switch in neutral ? YES NO Check continuity from logic P2-6 to battery negative. No continuity Replace logics. Move switch to “Run” position. Move switch to neutral. Continuity Repair or replace short wire or direction switch. MicroController Control System 61 Troubleshooting PROBLEM 8 Seat switch circuit defect. POSSIBLE CAUSE Seat switch defect; Wiring to seat defect; Logics defect. CHECKS Disconnect the battery and remove logic cover. Disconnect P2 connector. Check continuity from P2-7 harness connector to negative heatsink with multimeter in diode test position. Should be closed circuit when seat is pressed on and open circuit when seat is released. No continuity Constant continuity Disconnect seat switch connector. Push on the seat and check the continuity across the seat switch. Continuity No continuity Replace seat switch. Check OK Replace logics. Disconnect seat switch connector. Check continuity from logic harness connector P2-7 to control panel battery negative with multimeter in diode test position. Continuity No continuity Check continuity from terminal #1 of seat switch to control panel battery negative. Replace seat switch. Continuity No continuity Repair or replace open wire Check wiring for short circuits between harness connector P2-7 and control panel battery negative. Repair any short circuit found. Check continuity from terminal #2 of seat switch to logic harness connector P2-7 with multimeter in diode test position. Repair or replace open wire. MicroController Control System 62 Troubleshooting PROBLEM 9 Direction switch circuit defect. POSSIBLE CAUSE Direction switch defect; Wiring to direction switch defect; Logics defect. CHECKS Release park brake. Disconnect the battery and remove logic cover. Disconnect P2 connector. Disconnect service brake switch connector. Check continuity from control panel battery negative to P2-5 logic connector; With direction lever in forward should have a closed circuit, in neutral should be open. Check OK Check failed Check continuity from control panel battery negative to logic connector P2-6. With direction lever in reverse should have a closed circuit, in neutral should be open. Check OK Disconnect direction switch connector. Check continuity of wire #27. Continuity Check failed Repair or replace wire. Replace logics. Check continuity from terminal #2 of direction switch harness connector to control panel battery negative. Disconnect direction switch connector. Check continuity of wire #28. Continuity No continuity Continuity No continuity No continuity Replace direction switch. Repair or replace wire. Repair or replace open wire. Check continuity from terminal #2 of direction switch harness connector to control panel battery negative. Continuity No continuity Replace direction switch. MicroController Control System Repair or replace open wire. 63 Troubleshooting PROBLEM 10 Lift sensor circuit defect. POSSIBLE CAUSE Lift sensor not adjusted properly or defective; Lift sensor wiring defect; Valve control card (board) defect; Logics defect. CHECKS Disconnect the tilt and auxiliary switch connectors. Retest lift sensor circuit in self diagnostics. Circuit passes “Self-Diagnostics” Perform Problem 11,12 Tilt or auxiliary circuit defect. Circuit fails “Self-Diagnostics” Disconnect PV connector at the valve control board. Connect multimeter negative lead to PV-5 and the positive lead to PV-2. Measure the voltage. Battery Voltage Measure each voltage from : PV-1, PV-3 to battery negative PV-5. All = 11.5 to 12.5 Any/All = 0V 0 Volt Repair or replace broken wire between key switch and PV-2 (wire #5) or between PV-5 and battery negative(-). Reconnect PV and adjust the lift sensor and valve control card to specifications. Measure each voltage from P2-3, P2-4 to battery negaive. Display does not change 0 to 3 All = 11.5 to 12.5 Display changes 0 to 3 Repair or replace broken wire between P2 logic connector and PV connector. Perform “Self-Diagnostics”. Lift circuit should work. Measure each voltage from P2-3, P2-4 to battery negative as the lever is pulled. 11.5 to 12.5 and .2v Measured on each Replace logics. Any one or all 0V Remove P2 logic connector. Check P2-3, P2-4 for shorts to negative. 11.5 to 12.5 and .2V NOT measured on each If shorted Replace valve Control Card. Replace or replace wire. No shorts Replace logics. NOTE : Before lift truck is placed into service, connect tilt and auxliary switches and verify proper adjustment. MicroController Control System 64 Troubleshooting PROBLEM 11 Tilt switch circuit defect. POSSIBLE CAUSE Tilt switch defect; Wiring defect; Logics defect. CHECKS Disconnect the battery and remove logic cover. Disconnect P2 connector. Pull tilt lever to maximum. Check continuity from P2-2 logic connector to control panel negative. Continuity No continuity Replace logics. Check continuity of wire #49. Continuity Check continuity from tilt switch terminal of wire #1 to control panel negative. Continuity Replace tilt switch. MicroController Control System No continuity Repair or replace wire. No continuity Repair or replace wire. 65 Troubleshooting PROBLEM 12 Auxiliary switch circuit defect. POSSIBLE CAUSE Wiring defect; Auxiliary switch defect; Logics defect. CHECKS Disconnect the battery and remove logic cover. Disconnect P2 connector. Pull auxiliary lever to maximum. Check continuity from P2-16 logic connector to control panel negative. Continuity No continuity Replace logics. Check continuity of wire #46. Continuity Check continuity from Aux. switch terminal of wire #1 to control panel negative. Continuity Replace Aux. switch. MicroController Control System No continuity Repair or replace wire. No continuity Repair or replace wire. 66 Troubleshooting PROBLEM 13 Park brake switch circuit defect. POSSIBLE CAUSE Park brake switch defect; Wiring defect; Logics defect. CHECKS Disconnect the battery. Check continuity from wire #71 to #1 on the park brake switch; With park brake released should have a closed circuit; With park brake applied should have an open circuit. Check park brake switch to make sure it is activated by the park lever. Check OK Check failed Check continuity from wire #1 on the park brake to control panel battery negative. Continuity Replace park brake switch. No continuity Check continuity from wire #71 on the park brake switch to logic P2-8 Continuity Repair or replace wire. No continuity Replace logics. MicroController Control System Repair or replace wire. 67 Troubleshooting PROBLEM 14 Accelerator circuit defect. POSSIBLE CAUSE Wiring defect; Accelerator defect; Logics defect. CHECKS With the key switch on, the seat switch closed, park brake released and connect multimeter positive lead to P1-16, negative lead to P1-20. Measure the voltage. 12 volts Other voltage Connect multimeter positive lead to P1-15, negative lead to P1-20. Measure the voltage accelerator pedal released : 0 volt. Press accelerator pedal to max. : 9.6 to 11 volts. Check OK Replace logics. Check failed Disconnect P1 logic connector. Check continuity of wire #18. Continuity Replace accelerator. No continuity Check continuity from terminal #1 of accelerator harness connector to logic harness connector P1-16. Continuity No continuity Check continuity from terminal #3 of accelerator harness connector to logic harness connector P1-20. Continuity Replace logics. Repair or replace wire. Repair or replace wire. No continuity Repair or replace wire. MicroController Control System 68 Troubleshooting PROBLEM 15 Incorrect contactor operation. POSSIBLE CAUSE Wiring defect; Contactor defect; Logics defect. CHECKS During the “Self-Diagnostic” test, which of the following occurs? Contactor does not activate or does not remain activated. A contactor activates whenever the key switch is closed through all tests. Disconnect the battery. Check for free mechanical movement of contactor tips Movement OK See Problem 16. “Any contactor closes when key switch is closed”. Movement not free Remove logic cover. Disconnect P1. Check continuity from P1-3 (wire #15) to terminal of the contactor with incorrect operation. Continuity No continuity Measure continuity from the appropriate P1 socket to the coil terminal of the contactor that has incorrect operation. Determine the P1 socket with respect to the contactor that has incorrect operation as follows: Line ....................................................P1-4, wire #33 Forward direction left .........................P1-5, wire #L34 Reverse direction left .........................P1-6, wire #L35 Forward direction right .......................P1-7, wire #R34 Reverse direction right .......................P1-8, wire #R35 Bypass ..............................................P1-9, wire #36 Pump Bypass Contactor ....................P1-14,wire #37 Continuity Repair or replace wire. No continuity Check the contactor coil resistance. See Component Measurements in Specifications section. Check OK Replace contactor. Repair or replace wire. Check not OK Connect P1 and run “Self-Diagnostics” again. If contactor does not close, replace logics. MicroController Control System Replace contactor. 69 Troubleshooting PROBLEM 16 Any contactor closes when key switch is activated. POSSIBLE CAUSE Wiring defect; Logics defect. CHECKS Connect the battery. Does the line contactor close when the key switch is closed ? Yes No Did the seat switch pass “Self-Diagnostics”? No Yes See Problem 8 Seat Switch Circuit Defect. With contactor closed ? Disconnect the battery. Remove logic cover and disconnect logic P1 connector. Check for a short circuit from control panel battery negative to P1 harness connector socket. Determine the P1 socket with respect to the contactor that closed as follows: Line................................................................P1-4 Forward direction left.....................................P1-5 Reverse direction left ....................................P1-6 Forward direction right ..................................P1-7 Reverse direction right ..................................P1-8 Bypass...........................................................P1-9 Pump Bypass Contactor ...............................P1-14 Short circuit Repair or replace shorted wire. MicroController Control System 70 Open circuit Replace logics. Troubleshooting PROBLEM 17 Display = “EE”, no lift truck drive operation. POSSIBLE CAUSE Static Return to Off (SRO) circuit activated by improper operation sequence; Direction switch defect; Accelerator linkage not fully released; Accelerator control defect; Logics defect. CHECKS Check for SRO by release of accelerator, release park brake move, the direction lever to neutral, reselect direction and press the accelerator. No change Run “Self-Diagnostics” to find faulty circuit or component. Lift Truck Operation OK Inform operator of correct start–up procedure. Also, that the direction lever must be left in neutral when leaving the truck. If no faulty component is found, replace logics. MicroController Control System 71 Troubleshooting PROBLEM 18 Display = “EE” (Flashing), no lift truck drive operation. POSSIBLE CAUSE No opterator in seat; Seat switch defect; Open wiring; Logics defect. CHECKS See Problem 8, seat switch circuit defect. MicroController Control System 72 Troubleshooting PROBLEM 19 Display = “E1”, or “E2” lift truck operation normal. POSSIBLE CAUSE Worn brushes; Short wiring; Display defect. CHECKS If “E1” displays, drive motor brush wear. If “E2” displays, hydraulic motor brush wear. Disconnect the respective wire from the motor. Wire #31 for drive motor or wire #72 for pump motor. Connect the battery and close the key switch and seat switch. Does the LCD go out ? No Yes Disconnect the battery. Check continuity of the respective wires to the logics. Continuity Check the brushes and replace as necessary. No continuity Replace or repair wires. Disconnect logic P2 and check for shorts from logic P2-14 and P2-15 to battery negative. Shorted Repair wires. MicroController Control System Opened Replace logics. 73 Troubleshooting PROBLEM 20 Overtemperature is ON and Display = . Lift truck accelerates slower than normal. Lifting speed is slower than normal. Power steering operation normal. POSSIBLE CAUSE Control panel overheated; Control thermostat (thermal switch) defect; Open wiring; Display defect; Logics defect. CHECKS Let the truck cool for 15 minutes. Overtemperature indicator ON Disconnect the battery. With the controller at close to room temperature, disconnect the control thermal switch connectors P10 and PP. Check continuity of thermal switches. Should have continuity below 69°C (156°F) Continuity Control panel was overheated, resume normal operation. If repeats occur, check drive and pump motors current draw or operating cycle for excessive ramp climbing, towing or excessive lifting. No continuity Replace thermal switch. Check continuity of wire #69 between themostat connector P10 and PP. Continuity No continuity Check continuity of wire #1 at HYD. thermostat to negative heatsink (control panel negative). Continuity Repair or replace wire. No continuity Remove logic cover. Check continuity of wire #69 at P10-7 to logic P2-11. Continuity Replace logics. Normal display Repair or replace wire. No continuity Repair or replace wire. MicroController Control System 74 Troubleshooting PROBLEM 21 Overtemperature is ON and Display = . Bypass contactor will not close. Pump and power steering operation normal. Acceleration slow. POSSIBLE CAUSE Drive motor overheated; Drive motor thermostat (thermal switch) defect; Open wiring; Display defect; Logics defect. CHECKS Let the truck cool for 15 minutes. Overtemperature indicator ON Disconnect the battery. With the drive motor at close to room temperature, disconnect the drive motor thermal switch connector. Check continuity of thermal switch. Should have continuity below 123°C (253°F) Continuity Drive motor was overheated, resume normal operation. If repeats occur, check drive motors current draw or operating cycle for excessive ramp climbing or towing. No continuity Replace thermal switch. Check continuity of wire #43 between left and right drive motor thermal switch. Continuity No continuity Check continuity of wire #1 at left drive motor thermal switch to negative heatsink. Continuity Repair or replace wire. No continuity Remove logic cover. Check continuity of wire #43 at right drive motor thermal switch to logic P2-12. Continuity Replace logics. Normal display Repair or replace wire. No continuity Repair or replace wire. MicroController Control System 75 Troubleshooting PROBLEM 22 Overtemperature is ON and Display = . Lifting performance slow. Drive and power steering operation normal. POSSIBLE CAUSE Pump motor overheated; Pump motor thermostat (thermal switch) defect; Open wiring; Display defect; Logics defect. CHECKS Let the truck cool for 15 minutes. Overtemperature indicator ON Disconnect the battery. With the pump motor at close to room temperature, disconnect the pump motor thermal switch connector. Check continuity of thermal switch. Should have continuity below 123°C (253°F). Continuity Pump motor was overheated, resume normal operation. If repeats occur, check pump motor current draw or operating cycle for excessive lifting and tilting. No continuity Repair or replace switch. Check continuity of wire #1 at pump motor thermal switch to negative heatsink. Continuity No continuity Remove logic cover. Check continuity of wire #42 at pump motor thermal switch connector to logic P2-13. Continuity Replace logics. Normal display Repair or replace wire. No continuity Repair or replace wire. MicroController Control System 76 Troubleshooting PROBLEM 23 Display = “EL”. No hydraulic (lift and tilt). Steering normal. Battery discharge indicator (BDI) circuit defect. POSSIBLE CAUSE Battery discharged or has a defect; Logics defect. CHECKS Connect battery, turn on key switch, close seat switch and measure voltage from line contactor to negative heatsink. Voltage must be greater than 45 volts. Voltage OK Voltage low With key ON, seat switch and line contactor closed, measure voltage at P9-9. Battery voltage Check battery connections; Charge or replace battery. Less than battery Replace logics. MicroController Control System Repair shorted wire or high resistance connection causing the improper voltage. 77 Troubleshooting PROBLEM 24 Hourmeter does not work. POSSIBLE CAUSE The hourmeter requires battery voltage to run. Measure voltage at hourmeter to ensure that it is battery voltage. No voltage Battery voltage Check continuity from key switch to hourmeter positive (+) terminal. Continuity Replace hourmeter. No continuity Check continuity from hourmeter negative (-) to seat switch wire #45. Continuity Repair or replace wire. No continuity Repair or replace wire. Check continuity from seat switch to battery negative wire #1. No continuity Repair or replace wire. MicroController Control System 78 Troubleshooting PROBLEM 25 Normal hydraulic operations, display is normal and no drive operations. POSSIBLE CAUSE Service brake switch shorted. Short wires (#27, #28). Charged head capacitor. CHECKS Disconnect the battery connector and discharge the head capacitor fully. Check continuity from wire #27 (logic P2-5) to wire #28 (logic P2-6). Continuity No continuity Check service brake switch and wires #27, #28 from logics to service brake switch. Check direction switch. All checks OK Replace logics. Any checks failed Replace logics. Repair or replace wire or switches. MicroController Control System 79 Troubleshooting PROBLEM 26 Current limit adjustment cannot be made. POSSIBLE CAUSE Current sensor defect; Wiring defect; Logics defect. CHECKS Perform current sensor component check. Check OK Check failed Replace logics. MicroController Control System Repair wiring or replace current sensor. 80 Troubleshooting PROBLEM 27 Slow steering, but pump motor does turn. Drive system operation normal. POSSIBLE CAUSE Steering pressure switch defect; Wiring defect; Logics defect. CHECKS Check the battery, close the seat and key switches. Put the direction lever in forward. Disconnect pressure switch connector. Pump motor speed remains the same Pump motor speed increases Replace the pressure switch. Disconnect pressure switch connector. Check for a continuity between P2-1 and battery negative. No continuity Replace logics. Continuity Repair the wiring. MicroController Control System 81 Troubleshooting PROBLEM 28 Pump motor runs continuously when neutral is selected (no wait mode). Pump motor turns at high power steering speed continuously. POSSIBLE CAUSE Steering pressure switch defect; Pressure switch connector disconnected; Wiring defect; Logics defect. CHECKS Check steering pressure switch connector for proper connection. Connected Disconnected Disconnect the pressure switch connector. Place jumper wire between both pressure switch connector terminals. With the key ON, seat switch closed and a direction selected, the pump motor should run at slow speed. Remains at high speed Runs at slow speed Disconnect the battery and discharge the head capacitor. Check continuity from terminal #1 of pressure switch connector to the control panel negative. Also check continuity from terminal #2 of pressure switch connector to logic connector P2-1. Continuity Replace logics. Connect connector. Replace the pressure switch. No continuity Repair or replace open wire. MicroController Control System 82 Troubleshooting PROBLEM 29 Drive motor does not operate or operates with low power or is erratic. Pump and power steering systems operation normal. POSSIBLE CAUSE Accelerator defect; Direction control circuit defect ; Current limit set too low; Wiring defect ; Logics defect. CHECKS Perform self-diagnostics. Passed Does not pass See respective problem for defective circuit. Readjust current limit to specifications. Check DR1 and DR2 for correct resistance. Resistance is 90Ω L 5%. In specification Not in specification Check wire #L67, #L68, #R67 and #R68 for a good connection on DR1 and DR2. Check wires #L63 and #R63 to base of transistors DTR1 and DTR2. Check continuity of wire #L64 and #R64 from emitter of power transistors to logics P9-5 and P9-6. All OK Defective wiring Repair or replace defective wiring or connection. Check diode DD1, DD2, DD3 and DD4 for shorts or open circuit. Diode OK Defective diode Check drive motor, cables and contactor for open circuits. Check OK Replace logics. Replace resistor. Replace defective diode. Open circuit Repair open circuit or replace drive motor. MicroController Control System 83 Troubleshooting PROBLEM 30 Horn does not function correctly. Lift and drive operation normal. POSSIBLE CAUSE Open fuse; Faulty wiring; Defective switch; Horn defect. CHECKS With the faulty horn circuit activated, check for voltage on the load side of the horn fuse. Battery voltage No voltage Check for voltage on the load side of the horn switch. Battery voltage Check for short circuits; Replace horn fuse. 0 volt Repair or replace open wire from fuse or replace defective switch. Check for voltage at the negative connection of the load. 0 volt Battery voltage Repair or replace open wire from the horn switch or replace horn. MicroController Control System Repair or replace open wire going to battery negative. 84 Troubleshooting PROBLEM 31 Auxiliary lighting and/or alarm does not function correctly. Lift and drive operation normal. POSSIBLE CAUSE Open fuse; Faulty wiring; Defective switch; Shorted load; Open load; Loss of input voltage to DC-DC converter; Defective DC-DC converter. CHECKS Connect the battery and close the key switch. Measure from the DC-DC converter 12V positive terminal to the 12V negative terminal. No voltage output Voltage above 13V Con’d Next Page Voltage below 11V Con’d Next Page Con’d Next Page Voltage 11 to 13V With the faulty auxiliary circuit activated, check for voltage on load side of the auxiliary fuse. 11 to 13 volts Check for voltage on the load side of the auxiliary switch. 11 to 13 volts Check for short circuits; Replace auxiliary fuse. 0 volt Check for voltage at the negative connection of the load. 0 volt No voltage Repair or replace open wire from fuse or replace detective switch. 11 to 13 volts Repair or replace open wire from the auxiliary switch or replace the defective auxiliary component. Repair or replace open wire going to battery negative. MicroController Control System 85 Troubleshooting Problem 31 (continued) No voltage output. Measure the voltage from (POS INPUT) to (NEG INPUT). Battery voltage 0 volt Measure the voltage from (12V POS) terminal of the DC-DC converter to battery negative. Battery voltage Measure the voltage from the battery positive cable at the line contactor to the (NEG INPUT) terminal of the DC-DC converter. 0 volt Battery voltage Measure the voltage from (ENABLE) terminal of the DC-DC converter to battery negative. Battery voltage Replace the DC-DC converter. 0 volt Check for open fuse or wiring between the line contactor and the (POS INPUT) terminal of the DC-DC converter. 0 volt Repair open negative connection from converter (NEG INPUT) to battery negative. Open fuse Open wiring Repair or replace open wiring from the key sw to the (ENABLE) terminal of the DC-DC converter. Replace fuse and check wiring for shorts. If no shorts are found and the fuse continues to fail, replace the DC-DC converter. Repair or replace faulty wiring. Test the fuse at the DC-DC converter for continuity. Fuse good Fuse open Remove the load connections at the (12V POS) and (12V NEG) terminals of the DC-DC converter. Measure the voltage from the (12V POS) to the (12V NEG) terminals of the DC-DC converter. 11 to 13 volts <11 or >13 volts Replace the DC-DC converter. Check for a short circuit in each auxiary circuit. No shorts found Replace the DC-DC converter. MicroController Control System Replace fuse. If fuse continues to fail, replace the DC-DC converter. Shorts found Repair or replace faulty wiring or components. 86 Troubleshooting Problem 31 (continued) Voltage bellow 11 volts. Measure the voltage from (POS INPUT) or (+IN) terminal to the (NEG INPUT) or (-IN) terminal of the DC-DC converter. 36 volts or above Below 35 volts Remove all connections at the (12V POS) and(12V NEG) or the (+OUT) and (-OUT) terminals of the DC-DC converter. Measure the voltage from (12V POS) to (12V NEG) or (+OUT) to (-OUT). 11 to 13 volts Check the battery and DC-DC converter input connections from the battery. Battery low Poor connection Below 11 volts Charge or replace battery. Repair or replace faulty wiring or connections. Check for a short or low resistance in the auxiliary circuits and loads. NOTE : Excessive loading places the converter into current limit (12A maximum). DC-DC converter faulty. Replace converter. Voltage above 13 volts. Remove all connections at the (12V POS) and (12V NEG) or the (+OUT) and (-OUT) terminals of the DC-DC converter. Measure the voltage from (12V POS) to (12V NEG) or (+OUT) to (-OUT). 11 to 13 volts Above 13 volts Check the output load circuits for incorrect wiring or shorts to battery negative. MicroController Control System DC-DC converter faulty. Replace converter. 87 Troubleshooting PROBLEM 32 Display = “F0”, no lift truck operation. POSSIBLE CAUSE Logic potentiometers VR1 and VR6 out of adjustment. Excessive drive motor currents due to pushing or ramp application. Failed drive motor. Failed logics. Weak or discharged battery. CHECKS Adjust current limit to specification : 48 V - 250 amps OK Still “F0” Place lift truck into operation. Determine when the “F0” occurs. Before bypass During bypass Is there a steep ramp that the truck must stop on ? If so the Excessive Drive Motor Current option may not be applicable in this application. Set option Programmable Feature 9 to Data Codes 3. Determine if there is a steep ramp in the application. Adjust VR6 so that current is greater than maximum drive motor current going up the ramp. No ramp, or continues “F0” No ramp, or continues “F0” Does the “F0” occur due to excessive pushing or abuse. Ensure that the battery is not being deep discharged, causing high currents. Inspect the battery for poor maintenance or bad cells. Explain situation to the customer. If abuse continues, any drive failure will not be warranted. Discussion : The logic card monitors the current in the drive motors, and prevents high currents that may damage the drive motor, or possibly blow the line fuse. It uses two current limits settings for this purpose. Potentiomenter VR1 sets current limit for transistor pulsing, and if drive motor current exceeds the VR1 current setting for longer than 3 seconds, it will failsafe and display an “F0”. Similary, if the bypass contactor is closed, and the current exceeds the potentiometer VR6 setting for longer than 3 seconds, the truck will failsafe in a similar manner. In addition, the bypass operation will be prevented if the drive motor currents exceed the VR1 current limit. MicroController Control System 88 Troubleshooting PROBLEM 33 Display = “F2”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Shorted DTR1; Welded bypass contactor tips ; Open wiring; Driver board defect; Logics defect; Frame voltage on LS1 drive motor cable. CHECKS Disconnect the battery, check bypass contactor for welded tips. Check contactor for free tip movement. Not welded Welded Disconnect battery, remove logic cover, check continuity and connections of wire #L64 at DTR1 emitter to P9-5 on logics. Continuity No continuity Disconnect LS1 cable at panel and retry. Still “F2” Repair or replace contactor tips. Check BDI adjustment and battery Check current limit adjustment. Repair or replace wiring or connection. OK Investigate voltage present on LS1 cable. Check DTR1 for failure Test OK Test driver board (drive side only). Test OK Failed Replace transistor. Failed Replace logics. MicroController Control System Replace driver board. 89 Troubleshooting PROBLEM 34 Display = “F2” (Flashing), no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Shorted DTR2; Welded bypass contactor tips ; Open wiring; Driver board defect; Logics defect; Frame voltage on RS1 drive motor cable. CHECKS Disconnect the battery, check bypass contactor for welded tips. Check contactor for free tip movement. Not welded Welded Disconnect battery, remove logic cover, check continuity and connections of wire #R64 at DTR2 emitter to P9-6 on logics. Continuity Repair or replace contactor tips. Check BDI adjustment and battery. Check current limit adjustment. No continuity Disconnect RS1 cable at panel and retry. Still “F2” (Flashing) Repair or replace wiring or connection. OK Investigate voltage present on RS1 cable. Check DTR2 for failure Test OK Test driver board (drive side only). Test OK failed Replace transistor. Failed Replace logics. MicroController Control System Replace driver board. 90 Troubleshooting PROBLEM 35 Display = “F3”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Shorted PTR1; Open wiring; Driver board (HYD.) defect; Open circuit pump motor or P1, P2 cables ; Logics defect. CHECKS Connect the battery, close the seat and key switches. Line contactor closes then opens, pump motor does not turn. Display = “F3” Line contactor closes then opens, pump motor turns a small amount. Display = “F3” Disconnect battery, remove logic cover, check continuity of wire #74 at emitter connector of PTR1 to P9-7 on logics. No continuity Check PTR1 for a short circuit. Not failed Failed Continuity Replace transistor. Repair or replace wiring Check continuity from P1 to P2 at panel. Check driver board (HYD.). Continuity Not failed Replace logics. No continuity Check motor and cables and repair. Replace logics. * Failed Replace driver board (HYD.) * * See Notice NOTICE Damage to the control panel could result. To prevent further damage, before PTR1 or driver board are replaced, complete the following checks: 1. 2. 3. 4. 5. Check Check Check Check Check the diode PD for a failure. Head capacitor for a failure. PTR1 for a failure. Driver board for a failure. for continuity from PTR1 emitter (wire #74) to logics P9-7. MicroController Control System 91 Troubleshooting PROBLEM 36 Display = “F4”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Bypass contactor tips shorted; Shorted DTR1, DTR2 and PTR1. Poor connection at logic P9 connector ; Driver board defect. CHECKS See Problems 33, 34 and 35, Display = “F2” or “F2” (Flashing) and “F3”. Do both procedures. MicroController Control System 92 Troubleshooting PROBLEM 37 Display = “F5”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Faulty wire connections; DTR1 failed; Current limit set to low; Failed DD1 or DD2; Failed driver board; Failed current sensor; Failed logics. CHECKS Disconnect the following wires, visually inspect them for burnt or discolored terminals; Loose connections; Smashed or compressed connectors; Corrosion or foreign material. Wire #L65 at P9-1. Wire #L64 at P9-5 and emitter bus bar of left drive power transistors. Wire #L67 and #L68 at resistor DR1. Wires #L63 at DTR1. Wire #4 from driver board to positive heatsink. Wire #1 from driver board to negative heatsink. Wire #L22 from logics P1-12 to current sensor. Wire #25 from logics P1-16 to current sensor. Current sensor PIN3 to negative heatsink. Repair any defects then reconnect the wires. Display = “F5” Display normal Test DTR1 for a failure. Not failed Return truck to operation. Failed Replace transistor. Make sure that the connecter of current sensor is connected. Measure the voltage at P1-12 with the key switch closed. If the voltage is over than 10V, replace the current sensor. * Test diodes DD1 and DD2 for a failure. Not failed Failed Measure voltage at P1-16 with the key switch closed. Voltage = 11 to 12V Any other voltage Perform Rapid Turn-Up procedure for current limit (VR1). Display “F5” Replace logics. Replace logics. * * Display normal Test driver board (drive) for a failure. Not failed Replace failed components. Recalibrate current limit to specifications. Recalibrate current limit adjustments to specifications. Failed Replace failed components. Recalibrate current limit to specifications. * * See Notice #1 MicroController Control System 93 Troubleshooting PROBLEM 38 Display = “F5” (Flashing), no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Faulty wire connections; DTR2 failed; Current limit set to low; Failed DD3 or DD4; Failed driver board; Failed current sensor; Failed logics. CHECKS Disconnect the following wires, visually inspect them for burnt or discolored terminals; Loose connections; Smashed or compressed connectors; Corrosion or foreign material. Wire #R65 at P9-2. Wire #R64 at P9-6 and emitter bus bar of right drive power transistors. Wire #R67 and #R68 at resistor DR2. Wires #R63 at DTR2. Wire #4 from driver board to positive heatsink. Wire #1 from driver board to negative heatsink. Wire #R22 from logics P1-13 to current sensor. Wire #25 from logics P1-16 to current sensor. Current sensor PIN3 to negative heatsink. Repair any defects then reconnect the wires. Display = “F5” (Flashing) Display normal Test DTR2 for a failure. Not failed Return truck to operation. Failed Replace transistor. Make sure that the connecter of current sensor is connected. Measure the voltage at P1-13 with the key switch closed. If the voltage is over than 10V, replace the current sensor. * Test diodes DD3 and DD4 for a failure. Not failed Failed Measure voltage at P1-16 with the key switch closed. Voltage = 11 to 12V Any other voltage Perform Rapid Turn-Up Procedure for current limit (VR1). Display “F5” (Flashing) Replace logics. Replace logics. * * Display normal Test driver board (drive) for a failure. Not failed Replace failed components. Recalibrate current limit to specifications. Recalibrate current limit adjustments to specifications. Failed Replace failed components. Recalibrate current limit to specifications. * * See Notice #2 MicroController Control System 94 Troubleshooting NOTICE #1 Damage to the control panel could result. To prevent further damage, before DTR1 or driver board are replaced, complete the following checks: 1. 2. 3. 4. 5. 6. Check Check Check Check Check Check the diode DD1 and DD2 for a failure. DTR1 for a failure. Driver board for a failure. Head capacitor for a failure. for continuity from DTR1 emitter (wire #L64) to logics P9-5. Current sensor for a failure. NOTICE #2 Damage to the control panel could result. To prevent further damage, before DTR2 or driver board are replaced, complete the following checks: 1. 2. 3. 4. 5. 6. Check Check Check Check Check Check the diode DD3 and DD4 for a failure. DTR2 for a failure. Driver board for a failure. Head capacitor for a failure. for continuity from DTR2 emitter (wire #R64) to logics P9-6. Current sensor for a failure. MicroController Control System 95 Troubleshooting PROBLEM 39 Display = “F6”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Failed Fuse - Hydraulic; Faulty wire connections; PD, PTR1 failed; Failed driver board (HYD.); Failed logics. CHECKS Check the continuity of Fuse - Hydraulic. Disconnect the following wires, visually inspect them for burnt or discolored terminals, loose connections, smashed or compressed connectors, corrosion or foreign material. Wire #75 at P9-3. Wire #77 and #78 at resistor PR1. Wire from driver board (HYD.) to positive heatsink. Wire #1 from driver board (HYD.) to negative heatsink. Wire #73 at base of transistor PTR1. Repair any defects then reconnect the wires. Display = “F6” Display normal Check diode PD for a failure. Return truck to operation. Not failed Failed Check transistor PTR1 for a failure. OK Replace failed diode. Failed Check driver board (HYD.). Not failed * Replace transistor. * Failed Replace logics. Replace driver board (HYD.). * * See Notice NOTICE Damage to the control panel could result. To prevent further damage, before PTR1 or driver board are replaced, complete the following checks: 1. Check the diode PD for a failure. 3. Check PTR1 for a failure. 2. Check Head capacitor for a failure. 4. Check Driver board for a failure. 5. Check for continuity from PTR1 emitter (wire #74) to logics P9-7. MicroController Control System 96 Troubleshooting PROBLEM 40 Display = “F7”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Failure in both the drive and pump circuits. Incorrect wiring of wires #L67, #L68, #R67, #R68, #77 and #78. CHECKS See Problem 37, 38 and 39, Display = “F5” or “F5” (Flashing) and Display = “F6”. Do both procedures. MicroController Control System 97 Troubleshooting PROBLEM 41 Display = “FA”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Faulty wire connections; Failed steer angle switch; Failed logics. CHECKS Disconnect steer angle switch connector. Check continuity of wires #50, #51, #52 and #53 from logic P2-17 ~ 20 to steer angle switch connector. Continuity Not continuity Repair or replace wires. Check continuity wire #1 at steer angle switch connector to negative heatsink. Continuity No continuity Put steer wheel in straight position. Remove steer angle switch assembly cover. Check continuity of steer angle switches. Continuity Repair or replace wires. Not continuity Check steer angle switch operation by steer wheel position. (See steer angle control - page 24) Check OK Replace logics. MicroController Control System Replace failed switches. Failed Adjust steer angle switches. 98 Troubleshooting PROBLEM 42 Display = “Fb”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Battery defect; Logics defect. CHECKS Disconnect battery, measure voltage at battery connector terminal. Voltage must be higher than 20 volts. Voltage OK Wrong voltage Check battery connections; Replace battery. With key on, seat switch and line contactor closed, measure voltage at logic P9–9. Battery voltage No battery voltage Replace logics. MicroController Control System Repair or replace wire. 99 Troubleshooting PROBLEM 43 Display = “Fd”, lift truck operation normal. POSSIBLE CAUSE Pressure switch defect; Wiring defect; Logics defect. CHECKS Disconnect the battery. Check continuity from wire #41 to #1 on the pressure switch. Continuity No continuity Check continuity from wire #1 on the pressure switch to control panel battery negative. continuity No Continuity Check continuity from wire #41 on the pressure switch to logic P 2-1 continuity Repair or replace wires. No Continuity Replace logics. MicroController Control System Repair or replace wires. Repair or replace wires. 100 Troubleshooting System Tests and Adjustments Potentiometer Adjustment Tool -Trimmer Test Equipment Available from most electronic suppliers, this insulated tool allows for fast and easy adjustments of potentiometers. Hydrometer Hydrometers are usually available from any battery supplier. Battery maintenance is a crucial part of maintaining the electric vehicle. The ability to measure specific gravity and adjust the battery discharge indicator to match battery manufacturers specifications is an important part in the total maintenance of the electric vehicle. Discharging Head Capacitor (HEAD CAP) There are various pieces of electric truck test equipment that Daewoo recommends for all service personnel. This equipment is available from a number of world wide manufacturers and local electronic suppliers. Contact your Daewoo dealer or the factory for further recommendations. WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. Handheld Multimeter A digital multimeter that measures DC voltage, resistance, and has a diode tester, is required. It is recommended that a high quality meter that is drop protected, or comes with a drop proof case, be purchased. Autoranging features, fast becoming an industry standard, are convenient for the service personnel, but are not required for servicing the lift truck. A variety of miniature test leads, alligator clips, and needle probes are also useful, and some of these usually come with the multimeter. Clamp-on Current Probe The electric lift truck testing and adjusting procedures require the measurement of average DC currents. Currents in excess of 600 amps may be present, so a clamp-on meter that will exceed this level is required. It is also highly recommeded that a device that has a voltage output, as well as a visible display, be used. This makes viewing and adjusting currents from the operator's seat possible. The jaws of the current probe should be able to accept at least a 19mm (.75 inch) cable diameter. MicroController Control Systems 2 1 3 Discharging Head Capacitor (HEAD CAP) (1) Resistor. (2) Positive heatsinks. (3) Negative heatsinks. 1. Disconnect the battery and discharge the head capacitor. 2. Put a 82 ohm, 80 watt resistor (1) Part No. 929315, in position between the positive (2) and negative (3) heatsinks. Hold the resistor in position for 10 seconds. This will discharge the capacitor below 5 volts. 101 Testing And Adjusting Logics Removal 8 WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 7 Logics Removal (7) Nuts. (8) Logics. 1. Disconnect the battery and discharge the head capacitor. 5. Remove screws (7) which hold logics (8) to control panel. 6. Remove logics and replace logic cover to prevent damage. 2 “Run Time” Tests 1 WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. Component Location (1) Screws. (2) Logic Cover. 2. Loosen screws (1) that hold logic cover (2). 3. Remove the logic cover. WARNING 3 5 6 The lift truck can move suddenly. Battery voltage and high amperage are present. Injury to personnel or damage to the lift truck is possible. Safely lift both drive wheels off the floor. Put blocks of wood under the frame so the drive wheels are free to turn. During any test or operation check, keep away from drive wheels. 4 Key ON, No Operator Warning, Display =“EE” (Flashing) 1. Connect the battery. 2. Turn key to ON with no one on the seat. Connector Re4moval (3) Connector P1. (4) Connector P2. (5) Connector P8. (6) Connector P9. 3. The display should show the letter “EE” flashing on and off. 4. Disconnect connectors P1(3), P2 (4), P8 (5) and P9 (6). When disconnecting connectors pull on plastic connector housing, not on the wires. MicroController Control Systems 4. With an operator on the seat or by pressing on the seat the letter “EE” should stop flashing. 102 Testing And Adjusting Overtemperature Protection Static Return to Off (SRO), Display = “EE” 1. Connect the battery and sit on the seat. 2. Select a direction before turning key to ON. 3. Turn key to ON. An “EE” should appear on the display and the drive system should not operate. 4. Return the direction lever to neutral, then back to forward or reverse. The “EE” should disappear from the display and the drive system should operate. 5. Turn key to OFF. Depress and hold the accelerator pedal. To turn on overtemperature indicator. 6. Turn the key to ON. An “EE” should appear on the display and the drive system should not operate. 1. Disconnect the battery and discharge the head capacitor. 7. Release the accelerator padal. The “EE” should disappear from the display and the drive system should operate. 2. Disconnect the control panel thermal switch connector. 3. Connect the battery, close the seat switch and turn the key ON. The overtemperature indicator and “Ec” should be truned on. The drive and hydraulic speed will be reduced. “Ec” stored. Steps 1 through 3 can be repeated for the drive and pump motor thermal switches, the results should be: Drive – Drive pulse ratio reduced, bypass operation prevented, and “Ed” stored. Pump – Lifting performance reduced, and “EP” stored. MicroController Control Systems 103 Testing And Adjusting Logic Unit Quick Reference Voltage Check Component Tests The chart that follows is a quick reference of the expected voltages at the logic pin connectors. All voltage measurements are made with respect to battery negative. WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels. NOTICE Do not use steam or solvent to clean the controls. Damage can be caused to the control panel. Use pressure from an air hose with a maximum pressure of 205 kPa (30 psi) to clean the control panel when necessary. The air supply must be equipped with a water filter. 1. Put blocks of wood under the frame so both drive wheels are free to turn. 2. Disconnect the battery and discharge the head capacitor. NOTE: When control wires and power cables or bus bars are to be connected to the same bolt or stud, place all control wires together on the top of the bus bar or power cable. 3. Remove the logic cover. 4. Set the multimeter to the 200 volt DC range. Use the electrical schematic (located in left side panel) to locate components referred to by name and number in the procedures that follow. All wires must be located as shown on the schematic. Refer to SB2082E02 schematic(A154764) as attached. 5. Connect the multimeter negative lead to control panel battery negative. 6. Use the multimeter positive lead with an Needle Tip to measure the voltages under normal and activated conditions as shown in the Logic Voltage Reference chart. Make sure the chart matches the control system being tested. 1 3 4 2 Connector Layout (1) Connector P1.(2) Connector P2. (3)Connector P8. (4) Connector P9. MicroController Control Systems 104 Testing And Adjusting Logic Terminal P1-1 P1-2 P1-3 Wire No. P1-4 P1-5 P1-6 P1-7 P1-8 P1-9 P1-10 P1-11 P1-12 P1-13 P1-14 P1-15 33 L34 L35 R34 R35 36 L32 R32 L22 R22 18 Battery (+) from key switch Battery (+) to all CTR coils Line CTR coil Left-FWD coil Left-REV coil Right-FWD coil Right-REV coil Bypass CTR coil Left Plug sensor Right Plug sensor Left drive CT Right drive CT Not used Accelerator P1-16 25 12 Voltage (+) P1-17 P1-18 P1-19 P1-20 – – Not used Not used 1 Battery Negative P2-1 41 P2-2 49 P2-3 P2-4 P2-5 P2-6 P2-7 47 48 27 28 45 Pressure switch Tilt switch AUX1. switch Lift 1 switch Lift 2 switch FWD switch REV switch Seat switch P2-8 71 P2-9 P2-10 20 24 P2-11 69 P2-12 43 P2-13 42 P2-14 31 P2-15 72 5 15 Function LOGIC VOLTAGE CHECKS Normal Activated Voltage Voltage B (+) B (+) B (+) B (+) B B B B B B (+) (+) (+) (+) (+) (+) 0 0 0 to 0.03 0 to 0.03 Low Low Low Low Low Low -0.8 to -0.2 -0.8 to -0.2 0.03 to 12 0.03 to 12 0 to 0.89 0.9 to 12 11 to 13 11 to 13 0 0 Test Function Procedure 0V: key switch OFF, B (+): key switch ON. B (+) to all coils with key ON, 0V key OFF. B (+): Line CTR open, 0V: closed B (+): Left FWD open, 0V: closed B (+): Left REV open, 0V: closed B (+): Right FWD open, 0V: closed B (+): Right REV open, 0V: closed B (+): Byp. CTR open, 0V: closed Voltage exchanges 0 to negative Voltage exchanges 0 to negative Voltage increases with current Voltage increases with current Activate pedal from full up to full down 0V = key switch OFF, 12V = key switch ON Logic board negative Low High Activate steering wheel High Low Activate lever from OFF to ON High High High High High Low Low Low Low Low Park brake switch Low High Height 1 switch Height 2 switch Control thermal switch Drive motor thermal switch Pump motor thermal switch Drive brush wear indicator sensor Pump brush wear indicator sensor High High Low Low Low High Low High Low High High Low High Low Activate lever from OFF to ON Activate lever from OFF to ON Activate lever from OFF to ON Activate lever from OFF to ON High: switch open, Low: closed Low: Park brake activated High: Park brake released Activate lever from OFF to ON Activate lever from OFF to ON Activated by overtemperature of control panel Activated by overtemperature of drive motor Activated by overtemperature of pump motor Activated by brush wear of drive motor Activated by brush wear of pump motor MicroController Control Systems 105 Testing And Adjusting LOGIC VOLTAGE CHECKS Logic Wire Terminal No. P2-16 46 AUX2 switch P2-17 50 ANGLE SWITCH 1 High/Low High/Low Turn steer wheel lock to lock P2-18 51 ANGLE SWITCH 2 High/Low High/Low Turn steer wheel lock to lock P2-19 52 ANGLE SWITCH 3 High/Low High/Low Turn steer wheel lock to lock P2-20 53 ANGLE SWITCH 4 High/Low High/Low Turn steer wheel lock to lock P8-1 101 LCD: DC 5 Volt (+) 4.5 to 5.5 4.5 to 5.5 Key switch OFF: 0V, ON: 5V P8-2 WH LCD: DATA 0 High / Low 0V: segment OFF, High: On P8-3 YL LCD: DATA-bar 0 High / Low 0V: segment ON, High: OFF P8-4 GN LCD: CLOCK 0 High / Low 0V: segment OFF, High: On P8-5 BU LCD: CLOCK-bar 0 High / Low 0V: segment ON, High: OFF P8-6 BK LCD: LOAD 0 High / Low 0V: segment OFF, High: On P8-7 RD LCD: LOAD-bar 0 High / Low 0V: segment ON, High: OFF P8-8 108 Battery negative 0 0V P9-1 L65 0 0.1 to 1.3 Activated as drive TR pulses (Left TR) 0 0.1 to 1.3 Activated as drive TR pulses P9-2 R65 P9-3 75 P9-4 – P9-5 L64 P9-6 R64 P9-7 74 P9-8 – P9-9 4 Function Normal Activated Test Function Voltage Voltage Procedure High Low Activate lever from OFF to ON Logic board negative Pulse drive TR base (Left motor) Pulse drive TR base (Right motor) (Right TR) Pulse pump main TR base 0 0.1 to 1.3 0 1.5 to B (+) 0 1.5 to B (+) 0 1.5 to B (+) Activated as pump TR pulses Not used Drive TR emitter sensor (Left) Voltage increases as drive TR pulses Drive TR emitter sensor (Right) Voltage increases as drive TR Pump main TR emitter Not used faster (Left TR) pulses faster (Right TR) Voltage increases as pump TR pulses faster 0 B(+) from positive heatsink 0 B (+) B (+) with line CTR closed NOTE : “Normal” ; battery connected, key switch and park switch closed. High voltage signal should be 9 to 12 volts. Low voltage signal should be 0 to 0.9 volt. MicroController Control Systems 106 Testing And Adjusting Conductor and Switch Continuity 1. Set the multimeter to the 200 Ω range. 2. Use the multimeter to perform the continuity test. lf continuity exists, the measurement will be less than 1 ohm. lf the measurement is more than this, continuity does not exist and the problem will have to be repaired. Capacitor (Head) 5 2 1 4 3 WARNING Location of Components (1) Positive connection point. (2) Positive cable. (3) Negative connection point. (4) Negative cable. (5) Capacitor. Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 4. Disconnect positive cable (2) from the positive connection point (1). 5. Disconnect negative cable (4) from the negative connection point (3). NOTICE Damage can be caused to the head capacitor. Do not remove bolts from capacitor to perform tests. Remove capacitor connecting cables at heatsink connections. 6. Set the multimeter to the 20 KΩ range. Connect the multimeter positive lead to positive cable (2) of head capacitor (5). Connect the multimeter negative lead to negative cable (4) of head capacitor (5). 7. The meter must increment to above 10 KΩ. lf the capacitor fails the Head Capacitor Test, then replace capacitor. 8. If the head capacitor fails this test, then capacitor should be replaced. 1. Disconnect the battery and discharge the head capacitor. See Head Capacitor in Specifications section for proper assembly order of the head capacitor connections and bolt torque specifications. 2. Visually inspect the capacitor for bulges at the terminals. 3. Verify the plastic top is not melted around the terminals and that the blow plug is not leaking. WARNING Head Capacitor “blow plug” will rupture with reverse polarity. Vapors and contents of Head Capacitors are toxic, flammable and corrosive. Personal injury can be caused from breathing the fumes or if its contents make contact with the skin. Be sure to always connect the positive wire, from the positive heatsink, to the positive terminal of the Head Capacitor. MicroController Control Systems 107 Testing And Adjusting Contactors Contactor Components WARNING WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 1. Disconnect the battery and discharge the head capacitor. NOTICE Damage can be caused to the control panel. Do not switch the direction lever from one direction to the other (plug the lift truck) when the drive wheels are off the ground and in rotation at full speed. Coil Suppression Diodes 1. Connect the battery and close the seat switch. 1 35 2. Turn the key to ON and release the parking brake. The line contactor will close. 3. Select a direction and rapidly depress the accelerator pedal all the way to the floor. 246 4. Measure and record the time it takes the bypass contactor to close. This should be 1.5 to 2.5 seconds after the accelerator is fully depressed. 5. If the recorded value from Step 5 is less than 1.0 seconds, the logics may need to be replaced. (During normal operation this time will vary with the load on the truck). Suppression Diodes (1) D3-Line. (2) D4-Left Forward. (3) D5-Left Reverse. (4) D6-Right Forward. (5) D7-Right Reverse. (6) D8-Bypass. 6. If the recorded value from Step 5 is more than 2.5 seconds, check the bypass contactor tips for free movement. Check wiring for bad connections, and check current limit. 2. Disconnect the logic connector P1. 3. Set the multimeter to the diode test position. NOTE : The bypass contactor will not close if the accelerator linkage is not adjusted correctly. 4. Connect positive multimeter lead to anode, and the negative multimeter lead to cathode of diode in the logics. 5. The multimeter must indicate .3 to .9 volts. 6. Reverse the leads (positive multimeter lead to cathode and negative multimeter lead to anode). The meter must indicate OL. MicroController Control Systems 108 Testing And Adjusting Contactor Tips Coil Resistance 2. Disconnect all leads to both terminals of the coil. 3. Set the multimeter to the 200Ω range. 4. Measure the resistance of the coil at both teminals. If must be within specifications. See Component Measurements in Specifications section. 5. If the coil is not within specifications, the contactor assembly will be replaced. Coil Pulsing Checking Contactor Tip Gap 2. With the contactor coil leads and suppression assembly leads connected, set the multimeter to the 200 volts DC range. 2. Visually inspect the tips to verify they are not welded, melted, burned, or pitted. 3. Pull and release the tips quickly to verify there is no binding. 3. Connect the multimeter negative lead to the negative coil terminal wire #33 and the meter positive lead to the coil positive terminal wire #15. 4. Visually inspect the contactor assembly. Verify foreign objects don't interfere with normal contactor operation. 4. Connect the battery and activate the controls necessary for the contactor to be activated. 5. Check contactor tip gap with a feeler gauge as shown. Refer to Specifications section for correct settings. 5. After the contactor activates the multimeter must indicate 24 to 36 volts. If the voltage is not correct and the contactor passed the Coil Suppression Diodes test and the Coil Resistance test, the logics must be replaced. MicroController Control Systems 109 Testing And Adjusting Current Sensor 4. Check continuity from harness connector PIN2 wire #L22 to logic P1-12 (3) and connector PIN2 wire #R22 to logic P1-13 (4). Repair or replace any defective wires. WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery. The head capacitor (HEAD CAP) must be discharged before any contact with the control panel is made. Disconnect the battery and discharge HEAD CAP. 5. Set the multimeter to the 200V DC range. With connector P1 disconnected, connect the multimeter positive lead to logic P1-16 (5). Connect the multimeter negative lead to control panel battery negative. 1. Disconnect the battery, discharge the head capacitor, and remove the logic cover. 6. Connect the battery and turn the key to ON. The measurement must be 11 to 13 volts. If the measurement is not correct replace the logics. 7. Disconnect the battery and discharge the head capacitor. Connect P1. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 2 1 8. Set the multimeter to the 200V DC range and connect the positive lead to logic P1-12 (3) or P113(4) Location Of Components (1) Current Sensor - Right. (2) Current Sensor - Left. 2. Disconnect current sensor connector. 9. Connect the battery and turn the key to ON. The measurement must be 0 volts. 3. Make sure wire #1 from current sensors is connected to the negative heatsink. 3 10. Move the direction lever to forward and depress the accelerator. The voltage being measured should increase. If there is no voltage measured or the voltage being measured does not change, the current sensor must be replaced. 4 5 NOTE: If the current sensor is replaced current limit must be adjusted. P1 Connector Locations (3) P1-12. (4) P1-13. (5) P1-16. MicroController Control Systems 110 Testing And Adjusting Diodes Diode Replacement WARNING WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 1 5 Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 1. Disconnect the battery and discharge the head capacitor. 6 2. Remove the logics. 3. Disconnect the lead wire and remove the diode. 1 2 7 9 3 4 8 Location of Comporrents (1) DD1. (2) DD1cathode lead wire. (3) DD2. (4) DD2 cathode lead wire. (5) DD3. (6) DD3 cathode lead wire.(7) DD4. (8) DD4 cathode lead wire. (9) Battery negative heatsink. Diode installation (1) Contact surfaces. DD1 (1) is shown in the procedure that follows. Use a similar procedure for the other diodes. DD1 (1), DD2 (3), DD3 (5) and DD4 (7) have a cathode lead wire. 4. Wipe clean contact surfaces (1). Put a small amount of D557047 Thermal Joint Compound on contact surfaces (1), but not on the threads. 5. lnstall the diode and tighten to the specification listed in the chart that follows. 1. Disconnect the battery and discharge the head capacitor. 2. Disconnect DD1 cathode lead wire (2). Diode Torque DD1, DD2, DD3, DD4 9 to 11 N•m (81 to 99 lb•in) 3. Set the multimeter to the diode test position. 6. Connect all wires that were removed. 4. Connect the negative multimeter lead on DD1 cathode lead wire (2). Connect the positive multimeter lead to battery negative (9). The multimeter should indicate .3 to.9 volts. 5. Reverse the multimeter leads. The multimeter should indicate OL. If any of the measurements are not correct, replace the diode. MicroController Control Systems 111 Testing And Adjusting Driver Board (On Vehicle) NOTE: Driver board components are soldered parallel to each other. The tests that follow may not be typical of individual components tests. The driver board must be replaced if any incorrect test results are obtained. WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. Drive Side Tests Refer to Driver Board Components and Connections. If any of the measurements that follow are incorrect the driver board must be replaced. NOTICE Damage to the control panel could result. To prevent further damage before the Driver Board is replaced, complete the check list that follow; 1. Disconnect the battery, discharge the head capacitor. 2. Disconnect CONN A from driver board - main. 3. Resistor R2 test. Set the multimeter to the 200Ω range. Connect the positive lead to CONN A-8. Connect the negative lead to CONN A-9. The measurement must be 7.1 to 7.9 ohms. 1. Check head capacitor for a failure. If the drive circuit failed: 2. 3. 4. 5. 6. Check diodes DD1, DD2. Check diodes DD3, DD4. Check transistors DTR1, DTR2. Check continuity of current sensor wires. Check continuity from DTR1 emitter (wire #L64) to logic connector P9-5 and DTR2 emitter (wire #R64) to logic connector P9-6. 4. Resistor R5 test. Set the multimeter to the 200Ω range. Connect the positive lead to CONN A-2. Connect the negative lead to CONN A-3. The measurement must be 7.1 to 7.9 ohms. 5. Transistor TR1 (collector/emitter) and ZD1 test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-9. Connect the negative lead to CONN A-1. The measurement must be .3 to .9 volts. If the hydraulic pump circuit failed: 2. Check diode PD. 3. Check transistor PTR1. 4. Check continuity from PTR1 emitter (wire #74) to logic connector P9-7. Reverse the test leads. The measurement must be OL. NOTE: Visually inspect the following connections to ensure proper connection and lack of corrosion. 6. Transistor TR3 (collector/emitter) and ZD2 test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-2. Connect the negative lead to CONN A-1. The measurement must be .3 to .9 volts. 1. Wire #L63 to the base of DTR1. 2. Wire #R63 to the base of DTR2. 3. Wire #73 to the base of PTR1. 4. Wire #74 to the emitter of PTR1. 5. Wire #4 to the positive heatsink. 6. Wire #1 to the negative heatsink. 7. Wires #L67 and #L68 to DR1. 8. Wires #R67 and #R68 to DR2. 9. Wires #77 and #78 to PR1. 10. Wires #L65, #R65 and #75 to connector P9–1, P9-2 and P9-3. Reverse the test leads. The measurement must be OL. 7. Transistor TR1 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-9. Connect the negative lead to CONN A-10. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. MicroController Control Systems 112 Testing And Adjusting 15. Transistor TR2 (emitter/base) and R3 test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-12. Connect the negative lead to CONN A-7. The measurement must be .3 to .9 volts as above 8. Transistor TR3 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-2. Connect the negative lead to CONN A-4. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. Reverse the test leads. The measurement must be almost same as above. 9. Transistor TR1 (emitter/base) and R1 test. Set the multimeter to the 200Ω range. Connect the positive lead to CONN A-1. Connect the negative lead to CONN A-10. The measurement must be 3.5 to 4.3 ohms. 16. Resistor R3 test. Set the multimeter to the 2 KΩ range. Connect the positive lead to CONN A-7. Connect the negative lead to CONN A-12. The measurement must be 1000 to 1400 ohms. 10. Transistor TR3 (emitter/base) and R4 test. Set the multimeter to the 200Ω range. Connect the positive lead to CONN A-1. Connect the negative lead to CONN A-4. The measurement must be 3.5 to 4.3 ohms. 17. Transistor TR4 (emitter/base) and R6 test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-6. Connect the negative lead to CONN A-7. The measurement must be .3 to .9 volts. 11. Transistor TR2 (collector/emitter) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-7. Connect the negative lead to CONN A-11. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be almost same as above. 18. Resistor R6 test. Set the multimeter to the 2 KΩ range. Connect the positive lead to CONN A-7. Connect the negative lead to CONN A-6. The measurement must be 1000 to 1400 ohms. Reverse the test leads. The measurement must be OL. 12. Transistor TR4 (collector/emitter) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-7. Connect the negative lead to CONN A-5. The measurement must be .3 to .9 volts. 19. Connect all disconnected connectors. Reverse the test leads. The measurement must be OL. 13. Transistor TR2 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-12. Connect the negative lead to CONN A-11. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. 14. Transistor TR4 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-6. Connect the negative lead to CONN A-5. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. MicroController Control Systems 113 Testing And Adjusting 8. Transistor TR6 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN P-3. Connect the negative lead to CONN P-5. The measurement must be .3 to .9 volts. Hydraulic Pump Side Tests Refer to Driver Board Components and Connections. If any of the measurements that follow are incorrect the driver board must be replaced. Reverse the test leads. The measurement must be OL. 1. Disconnect the battery, discharge the head capacitor. 9. Transistor TR6 (emitter/base) and R11 test. Set the multimeter to the 200 Ω range. Connect the positive lead to positive heatsink. Connect the negative lead to CONN P-5. The measurement must be 3.5 to 4.3 ohms. 2. Disconnect CONN A, CONN B from driver board main and CONN P from driver board - hydraulic. 3. Transistor TR5 (collector/emitter) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-7. Connect the negative lead to CONN B-4. The measurement must be .3 to .9 volts. 10. Resistor R9 test. Set the multimeter to the 200 Ω range. Connect the positive lead to CONN P-3. Connect the negative lead to CONN P-4. The measurement must be 7.1 to 7.9 ohms. Reverse the test leads. The measurement must be OL. 11. Connect all disconnected connectors. 4. Transistor TR5 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN B-6. Connect the negative lead to CONN B-4. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. 5. Transistor TR5 (emitter/base) and R7 test. Set the multimeter to the diode test position. Connect the positive lead to CONN B-6. Connect the negative lead to CONN A-7. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be almost same as above. 6. Resistor R7 test. Set the multimeter to the 200Ω range. Connect the positive lead to CONN B-6. Connect the negative lead to CONN A-7. The measurement must be 1000 to 1400 ohms. 7. Transistor TR6 (collector/emitter) and ZD3 test. Set the multimeter to the diode test position. Connect the positive lead to CONN P-3. Connect the negative lead to positive heatsink. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. MicroController Control Systems 114 Testing And Adjusting Driver Board (Off Vehicle) Driver Board – Main 2 1 1 1 6 7 5 6 12 3 4 10 Driver Board – Hydraulic 8 8 1 9 10 Driver Board Components and Connections (1) CONN A. (2) CONN B. (3) TR1. (4) TR2. (5) TR3. (6) TR4. (7) TR5. (8) CONN P. (9) TR6. (10) Positive heatsink. MicroController Control Systems 115 Testing And Adjusting DRIVER BOARD TEST (OFF VEHICLE) Component Multimeter Range + Lead - Lead Result DRIVE SIDE TR1 (C to E) Diode #R63-A9 #4-A1 0.3 to 0.9 volts TR1 (C to E) Diode #4-A1 #R63-A9 OL TR1 (C to B) Diode #R63-A9 #R67-A10 0.3 to 0.9 volts TR1 (C to B) Diode #R67-A10 #R63-A9 OL TR1 (E to B) AND R1 200Ω #4-A1 #R67-A10 3.5 to 4.5 ohms R2 200Ω #R64-A8 #R63-A9 7.1 to 7.9 ohms TR2 (C to E) Diode #1-A7 #R68-A11 0.3 to 0.9 volts TR2 (C to E) Diode #R68-A11 #1-A7 OL TR2 (C to E) Diode #R65-A12 #R68-A11 0.3 to 0.9 volts TR2 (C to B) Diode #R68-A11 #R65-A12 OL TR2 (E to B) AND R3 Diode #R65-A12 #1-A7 0.3 to 0.9 ohms R3 200Ω #R65-A12 #1-A7 1000 to 1400 ohms TR3 (C to E) Diode #L63-A2 #4-A1 0.3 to 0.9 volts TR3 (C to E) Diode #4-A1 #L63-A2 OL TR3 (C to B) Diode #L63-A2 #L67-A4 0.3 to 0.9 volts TR3 (C to B) Diode #L67-A4 #L63-A2 OL TR3 (E to B) AND R4 200Ω #4-A1 #L67-A4 3.5 to 4.3 ohms R5 200Ω #L63-A2 #L64-A3 7.1 to 7.9 ohms TR4 (C to E) Diode #1-A7 #L68-A5 0.3 to 0.9 volts TR4 (C to E) Diode #L68-A5 #1-A7 OL TR4 (C to B) Diode #L65-A6 #L68-A5 0.3 to 0.9 volts TR4 (C to B) Diode #L68-A5 #L65-A6 OL TR4 (E to B) AND R6 Diode #L65-A6 #1-A7 0.3 to 0.9 ohms R6 200kΩ #1-A7 #1-A7 1000 to 1400 ohms PUMP SIDE TR5 (C to E) Diode #1-A7 #78-B4 0.3 to 0.9 volts TR5 (C to E) Diode #78-B4 #1-A7 OL TR5 (C to B) Diode #75-B6 #78-B4 0.3 to 0.9 volts TR5 (C to B) Diode #78-B4 #75-B6 OL TR5 (E to B) AND R7 Diode #1-A7 #75-B6 0.3 to 0.9 ohms R7 200kΩ #1-A7 #75-B6 1000 to 1400 ohms TR6 (C to E) Diode #73-P3 + HEATSINK 0.3 to 0.9 volts TR6 (C to C) Diode + HEATSINK #73-P3 OL TR6 (C to B) Diode #73-P3 #77-P5 0.3 to 0.9 volts TR6 (C to B) Diode #77-P5 #73-P3 OL TR6 (E to B) AND R11 200Ω #77-P5 + HEATSINK 3.5 to 4.3 ohms R9 200Ω #73-P3 #74-P4 7.1 to 7.9 ohms MicroController Control Systems 116 Testing And Adjusting 1. Check head capacitor for a failure. Transistors DTR1,DTR2 and PTR1 If drive circuit failed: WARNING 2. 3. 4. 5. 6. Check DD1,DD2 for a failure. Check DD3,DD4 for a failure. Check DTR1,DTR2 for a failure. Check driver board (drive side) for a failure. Check continuity from DTR1,DTR2 emitter bus bar (wire #L64, #R64) to logic P9-5, P9-6. 7. Perform Current Sensor test. Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. If the pump circuit failed: 1. Disconnect the battery, discharge the head capacitor and remove the logics. 2. 3. 4. 5. 2. Remove wires and bus bars from base and emitter terminals of the transistors to be tested. Check PD for a failure. Check PTR1 for a failure. Check driver board (pump side) for a failure. Check continuity from PTR1 emitter (wire #74) to logic P9-7. 2 1 Transistor Replacement DTR1, DTR2 and PTR1 WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 3 D557003 (927566) Transistor (1) Emitter. (2) Base. (3) Collectror. TRANSISTOR SPECIFICATIONS Multimeter (+) (-) D557003 Setting Test Lead Test Results Resistance Emitter Base 45 to 135Ω Diode Base Collector 3 to .9 V Diode Collector Base OL Diode Emitter Collector .3 to.9V Diode Collector Emitter OL 7 6 31 2 Location of Components (1) Bolt. (2) Bar. (3) Emitter wire #L64. (4) Base wire #L63. (5) Transistor DTR1. (6) Screw. (7) Bolts. NOTICE Damage to the control panel could result. To prevent further damage before a power transistor is replaced, complete the check list that follows: MicroController Control Systems 4 5 DTR1,DTR2 and PTR1 are all replaced in the same way. DTR1(5) is shown in the procedure that follows. 117 Testing And Adjusting 1. Disconnect the battery, discharge the head capacitor, and remove the logics. Resistors (DR1, DR2 and PR1) 2. Remove bolt (1), bar (2) and emitter wire #L64 (3). WARNING 3. Remove screw (6) and base wire #L63 (4). Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 4. Remove mounting bolts (7). NOTE : Look for visual breaks or cracks on resistors. 1. Disconnect the battery, discharge the head capacitor, and remove the logics. 8 1 2 Transistor Removal (8) Contact surface. 4 5 3 6 5 8 Location of Components (1) DR1. (2) Wire #L67. (3) DR2. (4) Wire #R67. (5) PR1. (6) Wire #77. Transistor Removal (5) DTR1 transistor. (8) Contact surface. 2. Disconnect wire #L67 (2) from resistor DR1 (1) and disconnect wire #R67 from resistor DR2 (3). 5. The contact surface (8) of transistor (5) is coated with D557047 Thermal Joint Compound. Carefully remove the transistor. 3. Set the multimeter to the 200Ω range. Connect the multimeter leads to terminals on resistor (1) to check the resistance of DR1. Connect the multimeter leads to terminals on resistor (3) to check the resistance of DR2. Connect the multimeter leads to terminals on resistor (5) to check the resistance of PR1. 6. To Replace the transistor, wipe clean contact surfaces. Put a small amount of D557047 Thermal Joint Compound on the contact surface (8). Coat transistor so that compound covers only the contact area. 7. Install transistor (5) with mounting bolts (7). See Specifications section for proper torques. 4. The measurement for each resistor must be: 85 to 95 ohms. 8. Install base wire #L63 (4) with screw (6). See Specifications section for proper torques. 5. If the measurement is not correct, the resistor must be 9. Install bar (2) and emitter wire #L64 (3) with bolts (1). See Specifications section for proper torques. MicroController Control Systems 118 Testing And Adjusting Thermal Switch The Thermal Switch (1) will open circuit if the temperature is 81 to 89°C (178 to 192°F) and close circuit at 69 to 77°C (156 to 171°F). WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. If the thermal switch is removed from the heatsink, it can be tested in an oven. See Troubleshooting Problem 20. Possible cause, pump or drive transistors overtemperature. NOTICE Damage to the thermal switch will occur. Do not heat the thermal switch over an open flame. Pump Motor and Drive Motor The Thermal Switch (1) will open circuit if the temperature is 144 to 156°C (291 to 313°F) and close circuit at 123 to 137°C (253 to 279°F). If the thermal switch is removed from the motor, it can be tested in an oven. Control Panel See Troubleshooting Problems 21 and 22. Possible cause, drive or pump motors overtemperature. 1 5 Location of Components (1) Thermal switch-Drive. (5) Thermal switch-Hydraulic. MicroController Control Systems 119 Testing And Adjusting Method B (Electrical) Electrical System Adjustments 1. Enter diagnostics, through the specified procedure, the display is an “A0”. Accelerator Control Linkage 2. Depress the accelerator slowly to stop. The speed symbols will increase from 0 to 10 on LCD. Method A (Mechanical) 3. Release the accelerator, the display will be “A0”, disconnect the battery, and place the DIAG/RUN/SETUP switch back to RUN, and reinstall the line fuse. 1 4 Parking Brake Switch 63 2 WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 3 1. Disconnect the battery and discharge the head capacitor. 2. Adjust length of lever (1) to 63 L 2 mm and tighten the nut (2). Fully depress accelerator pedal (4) until stopped by accelerator stopper (3). 3. Release accelerator pedal (4). Check for dimension. 3 2 1 Parking Brake Switch Adjustment (1) Switch. (2) Plate. (3) Bolts. 1. Close the seat switch and turn the key to ON. 2. Release the parking brake and put the truck in forward. MicroController Control Systems 120 Testing And Adjusting 3. Reposition plate (2) so the switch (1) actuator is against the bracket. Tighten bolts (3). Valve Control Card Adjustment 4. Engage the parking brake and the park brake symbol will be displayed. Repeat the procedure until adjustment is correct. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safety lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. Lift Sensor 1. Disconnect the battery and discharge the head capacitor. 1. Verify the lift sensor clearance is adjusted correctly. 1 2. Disconnect all tilt and auxiliary switch connectors. 3 3. Place the lift truck in “Quick” or “Self” diagnostics so that the display is flashing the lift speed. 4 2 Lift Sensor Adjustment (1) Lift Sensor(transducer) (2) Magnet. (3) Screw. (4) Setscrew. (A) 1.0 mm (.039 in) Clearance. 1 NOTICE Lift sensor may be damaged. Do not allow the magnet (2) to make contact with the plastic bracket when the lift lever is activated. 2 Valve Control Card Adjustment (1) P1 Potentiometer. (2) P2 Potentiometer. 4. Turn potentiometer P1 (1) fully counterclockwise unitl a clicking sound is heard (roughly 20 turns). 2. Loosen setscrew (4). 5. Turn potentiometer P2 (2) fully counterclockwise until a clicking sound is heard (roughly 20 turns). 3. Adjust screw (3) to make clearance (A) 1.0mm (.039 in) between lift sensor (1) and magnet (2) when the lift lever is activated fully (pulled all the way back). 6. Turn potentiometer P2 (1) 15 full turns clockwise. 7. Position the lift lever just prior to the hydraulic valve opening. Adjust P1(1) clockwise until a flashing “1” is obtained on the display. 4. Tighten setscrew (4). Check lift sensor circuit. The valve control card may need adjusting. MicroController Control Systems 121 Testing And Adjusting 8. Pull the lift lever all the way back. A flashing “3” must be displayed. Tilt and Auxiliary Switches 9. If a flashing “3” is not displayed, adjust P2 (2) clockwise until it is. Because each tilt and auxiliary switch can turn on the pump motor, it is recommended that only one be connected to start with. After adjusting the first switch proceed with the next one. 10. Release the lift lever and adjust P1 counterclockwise until a “0” is displayed. 1. Disconnect the battery and discharge the head capacitor. Disconnect all but one switch connector. 11. Repeat steps 9 and 10 until “0” to “3” speeds correct. 12. Put the lift truck back in the run mode so the actual hydraulics can be tested. 13. Connect the battery, close the seat switch and turn the key to ON. 14. Pull the lift lever back until the pump motor turns on. The forks must not move. Adjust P1 so the motor starts just before the valve opens. 1 If the valve opens before the motor turns on, adjust P1 (1) clockwise. 2 If the motor turns on too far in advance of the valve opening, adjust P1 (1) counterclockwise. Tilt and Auxiliary Switch Adjustment (1) Screw. (2) Screws. 2. With valve spool in neutral position, loosen screws (2) and adjust screw (1) to center the switch roller on cam. 3. After adjusting switch in or out to obtain correct switch point, tighten screws (1) and (2) to lock switch into position. 4. Connect the battery, close the seat switch and turn the key to on. Readjust switch if needed, so that the pump motor turns on before the control valve opens. This must be adjusted for each lever direction (pushed or pulled). 5. Connect the next switch and repeat this proccdure. MicroController Control Systems 122 Testing And Adjusting Rapid Tune-Up Procedure 3) VR6 : Bypass Dropout Current Potentiometer 5 4 Fully counterclockwise (CCW) and then slowly turn VR6 (13 full turns) clockwise (430A). 3 2 1 4. Make the final adjustments as specified in each of the Testing And Adjusting procedures before putting the truck into service. Perform these procedures in the order listed below: Lacation of Potentiometers (1) Current limit potentiometer VR1. (2) Plugging Current limit potentiometer VR2. (3) BDI adjustment potentiometer VR5. (4) Bypass drop out adjustment potentiometer VR6. (5) Electric Assist Brake adjustment potentiometer VR8. 1) Battery Discharge Indicator (BDI) 2) Current Limit 3) Plugging Current Limit 5. Turn off the key switch. The rapid tune-up procedure establishes a starting point for logic card adjustments. The following procedure allows the truck to run without damage to the truck or its components. Battery Discharge Indicator (BDI) Adjustment WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 1 3 2 1. Turn off the key switch. 2. Place direction lever to reverse or forward or seat switch open. Logic Board Layout (1) Jumper JP1. (2) Jumper JP2. (3) Potentiometer VR5 3. Turn on the key switch and then wait until display “EE” (SRO) or “EE” flashing shows on the LCD and the line contactor will be opened. Accurate adjustment of the BDI is only possible with a battery of the same voltage that the truck is going to operate at, and at a voltage within the range of the display. If a lift interrupt has occurred, with a “EL” on the display, it may be necessary to reprogram Feature “10” to select TYPE1, and then make the necessary adjustments. If 48 volt European tubular batteries are used, it is recommended that logic board is programmed TYPE1 on Programmable Feature “10”. 1) VRI : Drive Motor Current Limit Potentiometer Fully counterclockwise (CCW) and then slowly turn VR1 (9 full turns) clockwise (270A). 2) VR2 : Plugging Current Limit Potentiometer Fully counterclockwise (CCW) and then slowly trun VR2 (8 full turns) clockwise (250A). MicroController Control Systems 123 Testing And Adjusting Battery Table of the Closed Circuits BDI Adjustment Battery Terminal Voltage 1. Disconnect the battery and discharge the head capacitor. Remove logic cover and verify the DIAG/RUN/SETUP switch is in the RUN position. 2. Make sure the jumper connector is in the correct place for the lift truck battery used. Place the jumper on the following. JP1=36V, JP2=48V 3. Set the multimeter to measure battery voltage. Connect the multimeter positive lead to the battery positive cable at the line contactor. Connect the multimeter negative lead to the battery negative cable. 4. Put the direction lever in neutral and connect the battery. Bar Symbols Display Type 1(OPT) : Closed Voltage 6 above 37.2 5 36.8 to 37.2 4 36.4 to 36.7 3 36.0 to 36.3 2 35.6 to 35.9 1 35.2 to 35.5 1* 25.8 to 35.1 0/EL below 25.8 36V 1*=Display is flashing 5. Close the seat switch and turn the key to ON. The BDI display must show the correct bar for the voltage measured. To correct values are shown in the charts that follow. Battery Terminal Voltage Bar Symbols Display Type 1(STD) : Closed Voltage EXAMPLE: If the measurement is 37.2 volts for a 36 volt battery, the bar display should be at “5”. 6 above 37.2 5 36.8 to 37.2 6. If the display is not correct, turn the key to OFF and make an adjustment to potentiometer VR5. Turn VR5 clockwise to increase and counterclockwise to decrease the bar display. Approximately a 1/2 turn of VR5 will change the display one bar. Turn the key to OFF between adjustments otherwise the display WILL NOT CHANGE. 4 36.4 to 36.7 3 35.9 to 36.2 2 35.4 to 35.8 1 35.0 to 35.3 1* 34.5 to 34.9 0/EL below 34.5 36V 1* = Display is flashing 7. If the voltage was 37.2V, VR5 should be turned to find the transition point between 6 and 5 on the bar display. This will assure that the BDI is calibrated at a high 5. 6 : The highest position Battery Terminal Voltage : Max. Charged Status 5: 4: 3: 2: 1: : (A) Not flashing (B) Flashing - 80% discharge warning MicroController Control Systems 124 Bar Symbols Display Type 1(OPT) : Closed Voltage 6 above 37.2 5 36.9 to 37.2 4 36.6 to 36.8 3 35.3 to 36.5 2 35.9 to 36.2 1 35.6 to 35.8 1* 35.3 to 35.5 0/EL below 35.3 36V Testing And Adjusting NOTE: Closed Voltage means that line contactor close and idle operation in hydraulic system. 7. If the voltage is higher than 37.2V, adjust the BDI as example. EXAMPLE: If the measurement is 38.8V, adjust bar display at a low 6 and then turn VR5 to 1 TURN CW. (1 TURN CW = 1.6V increase) BDI Adjustment with display at “EL” If the logics has already gone into lift interrupt (display = “EL”) it is not possible to adjust the BDI until a battery above a certain programmed voltage is connected to the vehicle. The factory default setting to reset the lift interrupt is any voltage equivalent to a bar display of 3 or higher. This level can be adjusted. See Program Feature “3”. By reprogramming Feature “3”, from the factory default code of 3, to a temporary code of 0, it will become possible to adjust the BDI with a battery with a voltage less than a 3 on the bar display . After adjustment of the BDI, reprogram Feature “3” back to the default setting of 3. MicroController Control Systems 125 Testing And Adjusting Current Limit Test and Adjustment 4. Engage the park brake. Connect the park brake connector of harness to hold the closed circuit. 5. Connect the battery. Close the seat switch and turn the key to ON. 6. Select a direction and depress the service brake so that the wheels do not turn. Depress the accelerator to 80% pulsing. To prevent bypass operation ensure that the accelerator is not depressed all the way down. To get an accurate current reading the wheels must not slip. 1 Ammeter Connection (1) Digital Ammeter. NOTICE Damage to the drive motor will result. Do not stall the drive motor for longer than absolutely necessary. To protect the drive motor from excessive currents, and “F0” can occur during current limit setting. Allow for the motors to cool between stalls, and let the motor run between stalls. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 7. The current measurement must be within specification. Adjust logic potentiometer VR1 clockwise to increase the current and counterclockwise to decrease the current. 36V between 240 and 270 amps. NOTE : Current limit is preset at the factory and should not be adjusted unless the truck malfunctions, or the logic board is replaced. Only qualified service personnel with the correct instrumentation should adjust current limits. 8. Repeat steps 6 and 7 until setting is correct. 9. Don’t forget to re-engage the service brake switch and park brake switch prior to putting the vehicle back into operation. 1. Put blocks of wood under the frame so both drive wheels are free to turn. 2. Connect clamp-on ammeter (1) around the LA1 cable to measure drive motor current. Use multimeter to read current remotely from the operator’s seat. Ensure that option feature “9” is default setting to prevent bypass operation. 3. Remove the floor plate, and disconnect the service brake switch connector. MicroController Control Systems 126 Testing And Adjusting Electrical Braking (Plugging) Current Test and Adjustment Bypass Dropout Adjustment - Stall Protection WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 1 The stall protection feature helps protect the drive motor from abuse, and can also prevent unnecessary line fuse failures. Adjustment or checking of this current setting is not recommended unless drive motor or fuse failures have occurred, or an “F0” occurs during bypass operation. Factory settings are as follows: Ammeter Connection (1) Digital Ammeter. 1. Make sure current limit is adjusted to specification before adjusting Electrical Braking current. 2. Connect clamp-on current probe (1) around LA1 cable to measure drive motor current. Use multimeter to read current remotely from the operator’s seat. 36V between 420 and 440 amps Fully counterclockwise (CCW) and then slowly turn VR6 (20 full turns) clockwise (430A). 3. Move the lift truck FORWARD at full speed. Keep the accelerator pedal fully depressed and change the direction to REVERSE. If “F0” occurs during bypass operation, the application should be investigated for incorrect operation, and maximum currents should be measured. Adjusting VR6 clockwise will increase the maximum current allowed in bypass. For maximum motor protection, VR6 can be adjusted counterclockwise, until a “F0” occurs in bypass, then adjust the potentiometer clockwise 1 turn. 4. The current measured during the electircal braking (plugging )must be 250 amps L 5%. 5. If the correct current is not measured, disconnect the battery and discharge the head capacitor. Remove the logic cover and adjust potentiometer VR2. Turn the potentiometer adjustment screw counterclockwise to decrease the plugging current. NOTE : Though the plugging distance (Recommended plugging distance is approximately 5 meters) is an application specific adjustment, plugging current should not exceed 250 amps. If the recommended current produces a short stopping distance, the distance may be lengthened by turning potentiometer VR2 counterclockwise to reduce plugging current. MicroController Control Systems 127 Testing And Adjusting Programmable Features There are 17 programmable features that effect the operation of the lift truck. A table of these features, the default setting, the minimum setting and the maximum setting are shown below: Feature Minimum Maximum Default Number Setting With the desired Feature Number being shown, move the direction lever to forward or reverse and then neutral. The display will flash the preset data value. To increase the value, cycle the direction lever to forward and then back to neutral. The display will increment number. Repeat this cycle until the desired value for this feature is flashed. Description Setting Setting 0 1 5 4 Creep Speed 1 1 6 4 Maximum Steering Speed 2 1 2 0 Electrically Assisted Braking 3 0 6 3 Discharged Battery Reset Value 4 0 6 5 0 Top Travel Speed Limit P Auto Plugging 6 0 4 2 Wait Timer (seconds) 7 1 2 1 Discharged Battery Drive Speed 8 1 5 4 Acceleration Travel Speed Time 9 1 3 1 Excessive Drive Motor Current 10 1 3 2 Battery Type Selection 11 1 6 3 Maximum Idle Speed 12 1 6 3 Maximum Lift1 Speed 13 1 6 1 Maximum Lift2 Speed 14 1 6 3 Maximum Tilt Speed 15 1 9 4 Maximum Auxiliary Speed 16 1 5 3 Hydraulic Ramp Timer To save a new setting, pull the tilt lever to maximum position and then release slowly while holding a wanted setting. The display will show the next feature number. 3. Repeat again on the above NO.2 until static display, 16 will show. A “PE” indicates the end of the feature list and can be cycled to return to the beginning of the feature list. Activating Default Settings All of the programmable features can be set to the factory default settings by the following procedure. 1. Turn the key switch to OFF. Setting Procedure Option Features 2. Seat switch must be open. The programming procedures are described on the following. 3. Move the direction lever to reverse. 4. Place the DIAG/RUN/SETUP switch to SETUP. 1. Initial conditions 5. Park brake must be released. Move the DIAG/RUN/SETUP switch to “SETUP” and then turn on the key switch. 6. Depress the accelerator pedal to maximum. Wait until display “0” shows on the LCD. This code indicates that truck is in the SETUP mode. 7. Turn the key switch to ON. 8. After the display performs the LCD test, a “d” (Flashing) will be displayed. This indicates that the default settings have been programmed. 2. Programming methods To change the Programmable Feature Numbers, pull the tilt lever to maximum position and then release once. The display will show Feature Number 1. NOTE: When you change voltage jumper (JP1 JP2), you should do the default setting on page 129 Cycling the tilt switch advances the display to the next Feature Number. Cycle the tilt switch until the Feature Number of the parameter to be programmed is shown on the display. MicroController Control Systems 128 Testing And Adjusting Programmable or Settable Option Features The logics contains a number of features which are either settable or programmable. The following is a list of the features, however the “Service Manual” or your Daewoo Dealer should be consulted in determing which options may be beneficial to the application. Note : Marked means default setting. FEATURE NO. DESCRIPTIONS • • Creep Speed •B • 0 Creep Speed Selection provides for slower creep speed control, especially at high mast application. Depending on truck chassis configuration and customer preference, the creep speed can be selected. The default setting of 2 gives improved creep speed control, especially at higher mast. The higher “number” makes more faster creep speed. Data Codes 1 2 3 4 5 On-Duty (%) 20 23 26 29 32 • • Maximum Steering Speed •B • This can be used to limit the maximum steering speed of the truck. These values are on-duty ratio of the pump main transistor base. 1 Data Codes 1 2 3 4 5 6 On-Duty (%) 17 20 23 26 29 32 • • Electrically Assisted Braking B • 2 To automatically activate plugging braking when the service brake is depressed and accelerator pedal is released. Data Codes 0 1 Comments Not used Used • • Discharged Battery Reset Value •B • 3 This feature sets the level of battery charge required to enable the hydraulics after a lift interrupt occurs. The battery discharge indicator (BDI) must read a level greater than the value set in this feature to enable the hydraulics after a lift interrupt occurs. (1* = Display is flashing) Data Codes 0 1 2 3 4 5 6 On-Duty (%) 1* 1 2 3 4 5 6 • • Top Travel Speed Limit •B • 4 The value of this feature is set to select the drive motor top speed. Values between 1 and 5 allow for varying speeds, 1 being the slowest and 5 being the fastest without using the bypass contactor. 0 being the normal travel and bypass operation. Data Codes 0 1 2 3 4 5 Speed(%) 100 : Bypass operation 43 50 60 75 90 MicroController Control Systems 129 Testing And Adjusting FEATURE NO. DESCRIPTIONS • • Auto Plugging •B • 5 If selected, this feature will automatically activate auto plugging braking when the accelerator is released during driving. Data Codes P Time (Sec) Pass • • Wait Timer •B • 6 This feature varies the time before the line contactor drops out after the truck has been inactive (wait mode-no operator requests, and direction lever in neutral). The delay may be set in 6 second increments between 0 and 12 seconds. Data Codes 0 1 2 3 4 Time (Sec) 0 3 6 9 12 • • Discharged Battery Drive Speed •B • 7 This feature sets the drive motor top speed during lift interrupt, battery lock-out. If the display shows “EL”, the logics limits the drive motor top speed to the value set in this feature. Data Codes Comments 1 2 1. Max.speed=70% 1. Normal operation. 2. No bypass operation. 2. Bypass operation. • • Acceleration Travel Speed Time •B • 8 This feature allows for varying amounts of time until the bypass contactor close when accelerator pedal has been depressed from zero to max. position. Data Codes 1 2 3 4 5 Time (Sec) Slowest Slower Normal Faster Fastest • • Excessive Drive Motor Current •B • 9 This prevents the truck from entering bypass when the truck is in current limit, thus extending the life of the bypass contactor tips, reducing line fuse failures, and extending drive motor brush life. If the motor is stalled for longer than the timer is set for, the vehicle will failsafe to prevent motor damage and an “F0” will be displayed. Data Codes Comments 1 2 3 This is to protect drive This is to protect drive motor from excessive motor from excessive current in either pulsing current in only bypass or bypass modes. modes. Not used • • Battery Type Selection •B • 10 Due to different voltage characteristics of battery technologies, specifically european tubular designs, it may be necessary to use a battery voltage chart with a reduced voltage range. Data Codes 1 2 3 Battery Voltage (Volt) Max.37.2/Min.25.8 Max.37.2/Min.34.5 Max.37.2/Min.35.3 MicroController Control Systems 130 Testing And Adjusting FEATURE NO. DESCRIPTIONS • • Maximum Idle Speed •B • 11 This can be used to limit the maximum idle speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 1 2 3 4 5 6 On-Duty (%) 7 9 11 13 15 17 • • Maximum Lift 1 Speed •B • 12 This can be used to limit the maximum lift 1 speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 1 2 3 4 5 6 On-Duty (%) 25 30 35 40 45 50 • • Maximum LIft 2 Speed •B • 13 This can be used to limit the maximum lift 2 speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 1 2 3 4 5 6 On-Duty (%) 50 60 70 80 90 95 • • Maximum Tilt Speed •B • 14 This can be used to limit the maximum tilt speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 15 1 2 3 4 5 6 On-Duty (%) 30 • •B • • Maximum Auxiliary Speed 40 50 60 70 80 This can be used to limit the maximum aux. speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 1 2 3 4 5 6 7 8 9 Time (Sec) 30 35 40 45 55 65 75 85 95 • • Hydraulic Ramp Timer •B • 16 When the hydraulic switches are activated, the time which is to take to maximum pulsing can be adjusted. Data Codes 1 2 3 4 5 On-Duty (%) Slowest Slower Normal Faster Faster Quick Procedure for Programmable Features An alternative method of entering option programmable features has been programmed into the logics. This will enable quick option programmable features without removing the controller room, line fuse, or placing the DIAG/RUN/SET switch to the “Set Up” position. To enter quick option programmable features, open the seat switch and place the direction lever to reverse and ensure that the park brake is released. While depressing the accelerator to maximum position other than OFF, and key switch to ON. Display will go to a solid “O”, indicating that you have entered option programmable features and you are ready for setting: Place the direction lever to neutral and release accelerator pedal.You can set the option programmable features. See programmable or Settable Option Features on page 129-132. MicroController Control Systems 131 Testing And Adjusting SB4101E00 Sep. 2003 Specifications Systems Operation Testing & Adjusting MicroController Control Systems Models : B13T-2, B15T-2, B18T-2, B20T-2(48V) EMOFB-00001~UP EMOFC-00001~UP EMOFD-00001~UP EMOD7-00001~UP (48V P/N A244300) for Electric Lift Trucks Important Safety Information Most accidents involving product operation, maintenance and repair are caused by failure to observe basic safety rules or precautions. An accident can often be avoided by recognizing potentially hazardous situations before an accident occurs. A person must be alert to potential hazards. This person should also have the necessary training, skill and tools to perform these functions properly. Improper operation, Iubrication, maintenance or repair of this product can be dangerous and could result in injury or death. Do not operater or perform any lubrication, maintenance or repair on this product, until you have read and understood the operation, lubrication, maintenance and repair information. Safety precautions and warnings are provided in this manual and on the product. If these hazard warnings are not heeded, bodily injury or death could occur to you or other persons. The hazards are identified by the “Safety Alert Symbol” and followed by a “Signal Word” such as “WARNING” as shown below. WARNING The meaning of this safety alert symbol is as follows : Attention! Become Alert! Your Safety is Involved. The message that appears under the warning, explaining the hazard, can be either written or pictorially presented. Operations that may cause product damage are identified by NOTICE labels on the product and in this publication. DAEWOO cannot anticipate every possible circumstance that might involve a potential hazard. The warnings in this pulication and on the product are therefore not all inclusive. If a tool, procedure, work method or operating technique not specifically recommended by DAEWOO is used, you must satisfy yourself that it is safe for you and others. You should also ensure that the product will not be damaged or made unsafe by the operation, lubrication, maintenance or repair procedures you choose. The information, specifications, and illustrations in this publication are on the basis of information available at the time it was written. The specifications, torques, pressures, measurements, adjustments, illustrations, and other items can change at any time. These changes can affect the service given to the product. Obtain the complete and most current information before starting any job. DAEWOO dealers have the most current information available. MicroController Control Systems 1 Specifications Index Specifications Component Measurements....................................... Console ..................................................................... Contactors................................................................. Control Panel (Layout) .............................................. Current Measurements ............................................. 5 7 8 9 5 Location of Control Panel Components .................. 16 Logic Unit ................................................................ 17 Operational Circuit Elements .................................. 18 Accelerator Control ............................................. 23 Battery Discharge Indicator (BDI)....................... 22 Central Vehicle Monitoring System..................... 18 Contactors .......................................................... 21 Current Sensor ................................................... 21 CVMS International Pictorial Symbols................ 20 On Board “Run Time” Diagnostics (Fault Detection) ................................................. 18 Steer Angle Control ............................................ 23 Wait Mode........................................................... 21 Direction Switch ........................................................ 7 Display Layout .......................................................... 7 Fuses ........................................................................ 8 Head Capacitor ......................................................... 8 Instrument Panel ....................................................... 7 Thermal Switch - Control Panel ................................ 8 Transistor Connections ............................................. 6 Transistor Measurements ......................................... 6 Symbol Library ........................................................ 15 Testing And Adjusting Systems Operation Accessory Circuits .................................................. DC - DC Converter ............................................. Horn Circuit......................................................... Hour Meter Circuit .............................................. Built-In Diagnostic Operation .................................. 46 Accessing Stored Error Codes ........................... 51 Erased Stored Error Codes ................................51 “Run Time” Diagnostics (Lift Truck in Operation) ...................................... 46 Quick Diagnostic Procedure ............................... 52 Saving Service Records ..................................... 51 “Self” Diagnostics (Lift Truck not in Operation) ................................ 48 Stored Error Codes............................................. 52 24 24 24 24 Actuation Circuit ...................................................... 25 Drive Circuit ............................................................ Bypass Circuit..................................................... Control Circuit ..................................................... Current Limit ....................................................... Electrical Braking (Plugging) .............................. Failure Protection Circuit .................................... Flyback Circuit .................................................... Power Circuit ...................................................... Thermal Protection Circuits ................................ 33 38 33 37 39 41 36 34 41 Component Tests .................................................. 104 Capacitor (Head) .............................................. 107 Conductor and Switch Continuity ..................... 107 Contactors ........................................................ 108 Contactor Components..................................... 108 Current Sensor.................................................. 110 Diode Replacement........................................... 111 Diodes ............................................................... 111 Driver Board (Off Vehicle) ................................. 115 Driver Board (On Vehicle)................................. 112 Logic Unit Quick Reference Voltage Check ..... 104 Resistors (DR1, DR2, and PR1) ....................... 118 Thermal Switch ................................................. 119 Transistors DTR1, DTR2 and PTR1 ................. 117 Transistors Replacement DTR1, DTR2 and PTR1.................................... 117 General Information ................................................ 17 Glossary .................................................................. 11 Hydraulic Pump Motor Circuit ................................. 26 Flyback Circuit .................................................... 31 Lift Circuit............................................................ 27 Lift Control Circuit ................................................32 Power Steering Circuit .........................................26 Power Steering Idle .............................................28 MicroController Control Systems 3 Index Control and Power System Operational Checks .................................................................... 45 Electrical System Adjustments ...............................120 Accelerator Control Linkage ..............................120 BDI Adjustment ..................................................123 Bypass Dropout Adjustment ..............................127 Current Limit Test and Adjustment.....................126 Electrical Braking (Plugging) Current Test and Adjustment ..........................................127 Lift Sensor..........................................................121 Parking Brake Switch.........................................120 Rapid Tune - Up Procedure...............................123 Tilt and Auxiliary Switches .................................122 Valve Control Card Adjustment..........................121 Preparation Tests and Checks .................................42 Programmable Features ........................................128 Activating Default Settings.................................128 Programmable or Settable Option Features.............................................................129 Setting Procedure Option Features ...................128 System Tests and Adjustments ..............................101 Discharging Head Capacitor (HEAD CAP) ......................................................101 Logics Removal .................................................102 “Run Time” Tests................................................102 Test Equipment ..................................................101 Troubleshooting........................................................42 Troubshooting Problem List ....................................53 MicroController Control Systems 4 Index Specifications Component Measurements Component Meter Meter Positive Meter Negative Scale (+) Test Lead (-) Test Lead Desired Indication DIODES (voltage indication) All Diode Anode Cathode 0.3 to 0.9 volts All Diode Cathode Anode OL RESISTORS (resistance indication) Panels with D557003(927566) Transistor & D557065 Transistor DRI, DR2, PR1 200Ω 90 ohms L 5% R2, R5, R8 200Ω 7.5 ohms L 5% HEAD CAPACITOR (resistance indication) Head capacitor 200Ω Positive side of Negative side of 0 then change to capactior (+) capactior (-) above 10K ohms CONTACTOR COILS (resistance indication) Direcitional 200Ω X Y 40 to 50 ohms Line 200Ω X Y 95 to 115 ohms Bypass 200Ω X Y 60 to 95 ohms Current Measurements CURRENT VALUES (AMPS) Transistor Current Limit Plugging Limit D557003 (927566) 270 L 10A 250 L 10A MicroController Control Systems 5 Specifications Transistor Measurements SPECIFICATIONS Multimeter (+) (-) D557003 (927566) Setting Test Lead Test Lead Results Resistance Emitter Base 45 to 135 ohms Diode Base Collector .3 to .9V Diode Collector Base OL Diode Emitter Collector .3 to .9V Diode Collector Emitter OL Transistor Connections A154972 - for Drive A154973 - for Hydraulic 1 2 E B 1 E E 3 3 E 3 BX 2 3 B BX (1) Emitter connection (2) Base connection (3) Collector connection MicroController Control Systems 6 Specifications Display Layout Console 1 Instrument Panel (1) Tighten bolts that fasten the cover to a torque of ............................1.5 to 2.5 N•m (13 to 22 lb•in) Direction Switch 1 1 2 (1) Tighten screws that fasten the instrument panel to a torque of ....................................0.5 to 0.7 N•m (4 to 6 lb•in) (1) Torque bolts that hold bracket to steering column to ................2.8 to 3.4 N•m (25 to 31 lb•in) (2) Torque bolts that hold bracket to switch to ............................143.4 to 3.9 N•m (31 to 35 lb•in) MicroController Control Systems 7 Specifications Head Capacitor Thermal Switch - Control Panel Contacts open at ................81 to 89°C (178 to 192˚F) Contacts close at................69 to 77°C (156 to 171˚F) 1 3 2 Contactors Torque for nuts that hold contactor bridge assembly .........................................2.2 N•m (20 lb•in) 4 5 Fuses Line .....................................................................600A Key ....................................................................... 10A Horn...................................................................... 10A Voltage Converter................................................. 10A Light...................................................................... 10A Back up ................................................................ 10A NOTE : Proper torque and assembly of capacitor hardware is critical. Avoid disassembly unless capacitor has to be replaced. (1) Tighten capacitor terminal bolt to a torque of ................................4.5 to 5.5 N•m (40 to 50 lb•in) (2) Spring washer D917069. (3) Ring terminal of wire assembly. (4) Lockwasher D917071. (5) Head capacitor terminal. MicroController Control Systems 8 Specifications Control Panel (Layout) Control Panel 3 10 4 1 2 2 6 5 8 9 12 2 2 MicroController Control Systems 7 11 2 2 2 9 Specifications NOTE : Apply a small amount of D557047 Thermal Joint Compound on the surface of the transistor, diode or thermal switch that contacts the heatsink. (1) Control panel plate. Apply a small amount of D557047 Thermal Joint Compound on control panel plate and mating surface prior to assembly. (2) Apply Sealant (Loctite catalogue No. and nameNo. 242, Adhesive/Sealant) on the threads of all screws that are used to fasten components on the control panel. (3) Apply Sealant (Loctite catalogue No. and nameNo. 242, Adhesive/Sealant) to the bolts used to tighten the positive heatsink to the control panel to a torque of ..........10 to 14 N•m (90 to 125 lb•in) (4) Use a backup wrench to hold nuts and tighten bolts the fasten bus bars to the power transistors to a torque of ...............4 to 6 N•m (35 to 55 lb•in) (5) Tighten screws that fasten power transistors to positive heatsink to a torque of ......................................4 to 6 N•m (35 to 55 lb•in) (6) Tighten screws that fasten wires to the base of the power transistors to a torque of .............................1.3 to 1.7 N•m (11.5 to 15 lb•in) (7) Tighten diodes DD1, DD2, DD3, DD4 and PD to a torque of ......................9 to 11 N•m (81 to 99 lb•in) (8) Tighten Head Capacitor terminal bolts to a torque of ............................4.5 to 5.5 N•m (40 to 50 lb•in) (9) Tighten all bolts that fasten bus bars of cables to either heatsink to a torque of ................................5.5 to 9.5 N•m (50 to 85 lb•in) (10) Tighten bolts that hold the negative heatsink to the control panel to a torque of ..............................10 to 14 N•m (90 to 125 lb•in) (11) Apply Sealant (Loctite catalogue No. and nameNo. 242, Adhesive/Sealant) on portion of setscrew threads that are in the insulator and control panel plate. Tighten bolts to a torque of ................................5.5 to 9.5 N•m (50 to 85 lb•in) (12) Use a backup wrench to hold bolts and tighten the nuts that fasten the cables or bus bars to the contactors to a torque of ....................................4 to 6 N•m (35 to 55 lb•in) MicroController Control Systems 10 Specifications Systems Operation Glossary NAME DESCRIPTION Accelerator A device that converts mechanical movement into a analog voltage pattern to the logics for variable drive motor speed. Activate Word used with a component or circuit. To change from the normal condition to the “activated” condition because of an application of force or electricity. Ammeter An electric meter used to measure current flow in amperes. Ampere (or Amp) The unit of measurement of current flow. The amount of current that one volt can push through a resistance of one ohm. Analog to Digital Converter A device that converts an analog voltage into a pattern of digital HIGH and LOW voltage signals. Anode The positive (+) side of a diode. Armature The rotating portion of an electric motor or generator. Base The terminal of a transistor through which control current flows (see Transistor). Battery Two or more cells connected together for a supply of electric current. BDI Battery Discharge Indicator - An electrically controlled display showing the operator the state of battery charge. Brush A conductor, normally a block of carbon, that makes sliding contact between the stationary and moving part of the motor or generator. Bus Bar A heavy electrical conductor to which other smaller wires are connected. Capacitor Device used to store electrical energy for short periods of time. Cathode The negative (-) side of a diode. CVMS Central Vehicle Monitoring System. Circuit A way for current to go from the positive (+) side of an electrical power source to the negative (-) side of an electrical power source. This can be through wires and electrical components. Coil A component made from many circles or turns of wire used to concentrate a magnetic field. Collector A terminal of a transistor through which main current flows (see Transistor). Commutator An armature component used to transfer current from the brushes to the armature windings. Conduct To allow the flow of current. Conductor A material that provides a path for current flow. Connector Part of a wire assembly or harness that connects with another wire assembly or harness. Used for ease of assembly and disassembly. MicroController Control Systems 11 Systems Operation NAME DESCRIPTION Contactor Assembly An electrical component consisting of an electromagnetic coil and a set of heavy contact tips. Control current passes through the coil, building a magnetic field which closes or opens the contact tips. Contactor Coil An electromagnet used to close or open contact tips in a contactor assembly. Contact Tips or Contacts The portion of a switch, relay or contactor where the circuit can be opened or closed. Continuity Having the ability to allow current flow. Control Circuits The wires and components carrying low current used to signal the logic unit, turn on main components, or support auxiliary circuits (indicated by narrow lines on a schmatic). Counter Electromotive Force (CEMF) An opposing voltage set up by a collapsing or increasing magnetic field within a coil. Current The movement or flow of electricity through a conductor. A circuit must be complete for current to flow. Current Limit The maximum allowable armature current of a stalled drive motor during pulsing. Current Sensor A hall-effect sensor in the drive motor circuit that produces an increasing voltage output as the drive motor current increases. Deactivate To change from the activated condition back to the normal (deactivated) condition. It can be caused by the application of force, the removal of force,or the removal of electricity. Digital Signal A signal in which the elements may be either of two distinct values. For example high voltage, low voltage. Diode A semiconductor device that allows current to flow in one direction, from the anode to the cathode. Display An electrical device that converts voltage inputs to a visual output. Electrical Braking Electrically trying to rotate the drive motor opposite to the direction of truck movement. Electromagnet A coil of wire, most often wound on an iron core, which produces a strong magnetic field when current is sent through the coil. Electromotive Force (EMF) The force that causes an electric current to flow in a circuit. This force is measured in volts. Emitter A terminal of a transistor through which low control current and main current flow (see Transistor). Field Windings The stationary coils that produce a magnetic field in motors and generators. Filter An electrical device or component for restriction or suppression of undesired voltage spikes. Fuse A component in an electrical circuit that will open the circuit if too much current goes through it. Harness An assembly made of two or more wires that are held together. Heatsink A mounting frame used for semiconductor cooling. MicroController Control Systems 12 Systems Operation NAME DESCRIPTION Hour Meter An electrically activated device used to record the amount of usage a truck receives. Indicator LCD that gives an indication of some vehicle condition when it turns on or flashes. Input A voltage change at the incoming connection of a component. Insulator A material that has a very large resistance so that it will not let current flow through it. LCD Liquid Crystal Display. Logics or Logic Unit The main printed circuit board containing a microprocessor and circuits to condition the voltage signals that go into or come out of the logics. It electronically monitors and controls the truck's functions. Magnetic Field The area around a magnet where magnetic forces can be detected. Microprocessor A small computer chip preprogrammed to control the various electrical functions on a lift truck. Normal Condition Words used with a switch or relay. Their normal condition is their condition when they are not controlled by the application of force, temperature, pressure, or electricity. Normally Close (N.C.) A switch or relay whose contacts are closed in the normal condition. Normally Open (N.O.) A switch or relay whose contacts are opened in the normal condition. OFF-Time The amount of time current does not flow through a transistor. Ohm The unit of measurement of resistance. The amount of resistance that will let one volt push only one ampere of current through it. ON-Time The amount of time current flows through a transistor. Open Circuit Wiring or components of a circuit that have no continuity. Output The current flow from a component which initiated from a voltage change at the component's input. Overload The presence of voltage or current which is greater than an electrical circuit or component is designed to handle. Pin The male contact of a connector that fits into a female contact (socket) of another connector. Plugging A portion of electrical braking where the generated current is directed back through the armature. Plugging Current Limit The maximum allowable current at the drive motor armature during the plugging portion of electrical braking. Potentiometer An adjustable resistor to preset electronic controls for proper specifications. Power Circuits The main current carrying components and conductors (indicated by the heavy lines on a schematic). Power Transistor A component in the power circuit which allows main motor current to pass through when turned on. Pulsing Current flow in a circuit being turned on and off. MicroController Control Systems 13 Systems Operation NAME DESCRIPTION Relay An electrical component consisting of an electromagnetic coil and a set of small contact tips. Control current passes through the coil, building a magnetic field which closes or opens the contact tips. When the contact tips are closed, low current can flow in a separate isolated circuit. Resistor A component made of a material that has a specific resistance to the flow of current. Schematic A line drawing of an electrical or electronic assembly which uses symbols to show individual components. It shows how the components, wires and connectors function electrically. Semiconductor Components such as, transistors, diodes, thyristors, etc. Having electrical characteristics between a conductor and an insulator. Series Wound Motor A motor in which the armature is connected in series with the field windings. Short Circuit An electrical connection between two or more components that is not desired. Socket The female contact of a connector that slips over a male contact (pin) of another connector. Solid State Reference to semiconductor components or circuits that use semiconductor components that have no moving parts, such as diodes and transistors. Switch A component used to control an electric circuit . It can close or open a circuit. Systems The electrical components, circuits, and connections that deliver power to perform specific tasks. Terminal An electrical connection point on an electrical component. Thermal Switch A switch that activates at a set temperature. Transistor A semiconductor component used in electric lift trucks as an electronic switch. A transistor most often has three terminals, a base (B), a collector (C) and an emitter (E). The main current flow is between the collector and emitter. This main current flow is controlled by a much smaller current flow between the base and emitter. Turn ON When an electrical component conducts current. Varistor A component terminated across the horn connections to eliminate voltage spikes when the horn is activated. Volt The unit of measurement of electromotive force. One volt is the force needed to make one ampere of current flow through one ohm of resistance in a circuit. Watt The unit of measurement of power. The amount of power used when one volt pushes one ampere of current through a resistance of one ohm. The result of amperes (current) multiplied by volts (voltage) is watts (power). Wire A conductor used to provide a path for current to flow to and from electrical components. Wiring Diagram A drawing using visual representation of components the way they actually look. It is used to show the locations of components and the connections between them. Zener Diode A special diode used to regulate voltage or as an overvoltage (too high a voltage) protector. MicroController Control Systems 14 Systems Operation Symbol Library 2 3 4 6 5 9 16 7 8 1 10 17 21 11 12 13 18 14 15 20 19 Schematic Symbols (1) Power Transistor. (2) Zener Diode. (3) NPN Transistor. (4) PNP Transistor. (5) Thermal Switch. (6) Battery. (7) Resistor. (8) Diode. (9) Normally Close Contacts. (10) Normally Open Contacts. (11) Male Terminal of Connector (pin). (12) Female Terminal of Connector (socket). (13) Wire Connection. (14) No Wire Connection. (15) Contactor Coil. (16) Current Sensor. (17) Armature. (18) Field Windings. (19) Capacitor. (20) Fuse. (21) Switch. MicroController Control Systems 15 Systems Operation Location of Control Panel Components Control Panel 1 3 2 4 5 6 Behind Logic Unit 8 11 12 13 19 7 10 9 18 17 16 15 14 MicroController Control Panel (1) Logic Unit (Logics). (2) DR1, DR2, PR1. (3) Line Fuse. (4) Line Contactor. (5) Right Dir. Contactor. (6) Left Dir. Contactor. (7) Driver Board. (8) PTR1 (Pump Transistor 1). (9) DTR1 (Drive Transistor 1). (10) DTR2 (Drive Transistor 2). (11) Head Capacitor. (12) PD (Pump Flyback Diode). (13) DD4 (Drive Plugging Diode 4). (14) DD2 (Drive Plugging Diode 2). (15) DD3 (Drive Flyback Diode 3). (16) DD1 (Drive Flyback Diode 1). (17) Bypass Contactor. (18) Key Fuse. (19) Current Sensors. MicroController Control Systems 16 Systems Operation General Information The speed of the hydraulic pump motor is controlled by switch inputs to and outputs from the logics. Outputs pulses the hydraulic pump power transistor. The power transistor pulse to control the speed of the hydraulic pump motor. To provide full speed the logics turns the power transistor ON 100%. The hydraulic pump system includes a failure protection circuit to protect against malfunctions of the power circuit. The MicroControl Panel is the control center and the Logic Unit (logics) is the decision making part of the MicroController System. The logics provide a self contained Battery Discharge Indicator (BDI) with lift interrupt and built-in diagnostic capabilities. The battery charge state and built-in diagnostic are monitored by the logics and displayed by the Central Vehicle Monitoring System (CVMS) located on the steer console. Thermal protection circuits are used on the hydraulic pump motor, the drive motor and the control panel to prevent permanent damage caused by over heating. NOTICE Damage to all motors and control panels will result. The motors and control panels are 48 volt unit and must be operated at their designed voltage. The voltage can not be changed without changing motors and control panel. Logic Unit The steering system is activated when the truck is powered up and the line contactor closes. The truck uses a combined power steering/hydraulic system where the hydraulic fluid for steering is provided by a DC series hydraulic motor, pump, and priority valve. 1 12 The drive motor and the hydraulic pump motor are controlled by pulsing transistors ON and OFF and controlling contactor operation. The speed and direction of the drive motor are controlled by voltage inputs to and outputs from the logics. Inputs to the logics are generated by the accelerator control and direction switch. Outputs from the logics control contactor coils and drive transistor pulsing. 4 2 5 6 7 Components on Logic Unit (1) Connector P1 (2) Connector P2 (3) Connector P9 (4) Connector P8 (5) DIAG/RUN/SETUP (6) Jumper JP1 - 36 V (7) Jumper JP2 - 48 V (8) VR1 potentiometer - Drive current limit adjustment (9) VR2 potentiometer - Plugging current limit adjustment (10) VR5 potentiometer - BDI adjustment (11) VR6 potentiometer - Bypass dropout adjustment (12) VR8 potentiometer - ELEC. Brake (EAB) adjustment The drive circuit pulses transistors to provide travel speed control up to 90% of full speed, after which the bypass contactor closes to provide full speed. The drive circuit includes a failure protection circuit which detects malfunctions of the drive power circuit, a plugging circuit to provide electrical braking and a current limit circuit to prevent excessively high currents during transistor pulsing. MicroController Control Systems 11 10 9 8 3 17 Systems Operation Operational Circuit Elements On Board “Run Time” Diagnostics (Fault Detection) Central Vehicle Monitoring System “Run Time” diagnostics use letters and numbers on the seven segment LCD portion of the CVMS, International Pictorial Symbols and LCD to signal both improper operating sequences and truck circuit defects. The Central Vehicle Monitoring System (CVMS) is located on the steering console. It is a self contained, solidstate instrument panel with two seven segment liquid crystal displays, warning and system condition segments. The LCD consists of seven segments which are turned on or off to form numbers and letters. Display = “EE” Static Return to Off (SRO) The logics has a Static Return to Off (SRO) circuit which assures that the direction switch has been returned to neutral and the accelerator returned to the full up position after the key and seat switch are closed. This safeguards against an accidental actuation of direction and speed when an operator resumes operation of an idle truck. If SRO occurs, the direction lever can be moved to neutral and the accelerator pedal released. The direction can now be reselected and the accelerator pedal depressed to start normal lift truck drive operation. Display = “EE” (Flashing) Seat Circuit Problem Anytime the battery is connected, the key is turned to ON and no one is in the seat longer than 6 seconds the letter “EE” will flash on and off. The truck will not operate until the seat switch is closed. Seven Segment Display Layout The Central Vehicle Monitoring System interacts with the logics and failure detection circuits. It functions as a battery discharge indicator (BDI) and provides on-board diagnostic data on the operational condition of the truck. During normal operation it provides “Run Time” diagnostics, and during troubleshooting it provides “Self” diagnostics. Display = “E1” Drive Motor Brush Problem The logics monitor the length of the brushes in the drive motors. As the brushes wear, a wire built into the brushes moves down and makes contact with the commutator. A wire from each motor brush set is connected to the logics. If any brushes wear down to a preset limit, an “E1” will display on the LCD. Display = “E2” Pump Motor Brush Problem The logics monitor the length of the brushes in the pump motor. As the brushes wear, a wire built into the brushes moves down and makes contact with the commutator. A wire from each motor brush set is connected to the logics. If any brushes wear down to a preset limit, an “E2” will display on the LCD. MicroController Control Systems 18 Systems Operation Display = “EL” Battery Lock-out Display = “F5” Drive System Problem (Left) When the battery is discharged, the CVMS displays “EL” and pump motor will not operate. If key switch turn off and then on, pump will operate for only 3 seconds. Drive motor speed will not exceed 70% of the max. regardless of an accelerator’s output voltage. The logics at P9-5 uses wire #L64 from the emitter of the left drive transistor to detect battery negative. The logics sends a test pulse out to the left drive transistor when power up. This test pulse is detected at P9-5 also. If battery negative is present or the test pulse is not detected, the line contactor will be deactivated and an “F5” will display on the LCD. Display = “F2” Drive System Problem (Left) Display = “F5” (Flashing) Drive System Problem (Right) The logics at P9-5 uses wire #L64 from the emitter of the left drive transistor to detect if the left drive transistor, bypass contactor tips or the driver board are shorted. In normal operation P9-5 has battery voltage only when the logics is pulsing the left drive transistor or the bypass contactor is activated. When a failure occurs the line contactor will be deactivated and an “F2” will display on the LCD. The logics at P9-6 uses wire #R64 from the emitter of the right drive transistor to detect battery negative. The logics sends a test pulse out to the right drive transistor when power up. This test pulse is detected at P9-6 also. If battery negative is present or the test pulse is not detected, the line contactor will be deactivated and an “F5” will flash on the LCD. Display = “F2” (Flashing) Drive System Problem (Right) Display = “F6” Pump System Problem The logics at P9-7 uses wire #74 from the emitter of the pump transistor to detect battery negative. The logics sends a test pulse out to the pump transistor when power up. This test pulse is detected at P9-7 also. If battery negative is present or the test pulse is not detected the line contactor will be deactivated and an “F6” will display on the LCD. The logics at P9-6 uses wire #R64 from the emitter of the right drive transistor to detect if the right drive transistor, bypass contactor tips or the driver board are shorted. In normal operation P9-6 has battery voltage only when the logics is pulsing the right drive transistor or the bypass contactor is activated. When a failure occurs the line contactor will be deactivated and an “F2” will flash on the LCD. Display = “F7” Drive and Pump System Problem Display = “F3” Pump System Problem The logics will release the line contactor and display “F7” on the LCD when BOTH wires #64 and #74 detect battery negative or do not detect the proper pulsing. See “F5”, “F5” (Flashing) and “F6”. The logics at P9-7 uses wire #74 from the emitter of the pump transistor to detect if the pump transistor or the driver board are shorted. In normal operation P9-7 has battery voltage only when the logics is pulsing the pump transistor is activated. When a failure occurs the line contactor will be deactivated and an “F3” will display on the LCD. Display = “FA” Angle Circuit Problem Steer angle commands are monitored by the logics. If steer angle switch has defects or each wires #50, 51, 52 and 53 is shorted/opened, the line contactor will be deactivated and an “FA” will display on the LCD. Display = “F4” Drive and Pump System Problem The logics will release the line contactor and display “F4” on the LCD when BOTH wires #64 and #74 detect battery voltage when it should not be present. See “F2”, “F2” (Flashing) and “F3”. MicroController Control Systems 19 Systems Operation Display = “Fb” Battery Mismatch Central Vehicle Monitoring System (CVMS) International Pictorial Symbols The motors and control panels are 48 volt units and must be operated at 48 volt. If battery condition is abnormal, an “Fb” will display on the LCD. Park Brake Symbol Display = “Fd” Pressure Switch Problem The logics at P 2-1 uses wire #41 from the pressure switch to detect if the pressure switch is opened for more than 10 seconds after the key switch ON. The “Fd” will be displayed and the truck will be operated normally. Park Brake Symbol If the park brake is applied, the park brake symbol will turn on to warn the operator that the brake is applied, and drive operation will be prevented. Overtemperature Symbol Normally closed thermal switches are constantly monitored by the logics and the CVMS. All these thermal switches are normally closed, so must open for the LCD to turn on. Truck performance will automatically be cut back by the logics, and the CVMS will light the LCD until the component cools. Control Panel Overtemperature Symbol Control Panel Overtemperature Symbol Two thermal switches (HYD and MAIN control panels) are connected in series to the logics. If any of the control panels overheat, the thermal switch in the center of the positive heatsink will open. The logics will slow lifting speeds and reduce drive speed. Truck acceleration will decrease. The overtemperature symbol and “Ec” will display on until the controller cools. “Ec” will be saved as stored error code. MicroController Control Systems 20 Systems Operation Drive Motor Overtemperature Symbol Wait Mode If the seat switch is closed, key turned to ON and the direction lever is left in neutral with no other operator requests, the line contactor will deactivate after approximately six seconds. The LCD will display “PP”. The lift truck will remain in this condition until the operator activates the direction switch, accelerator pedal or a control valve lever. The line contactor then reactivates and the truck is ready for normal operatation. Drive Motor Overtemperature Symbol Current Sensor The drive motor thermal switch, held against the drive motor field, will open if the motor gets too hot. The logics will reduce drive pulsing and prevent the bypass contactor from pulling in. The truck speed and acceleration will be reduced. The overtemperature symbol and “Ed” will display on until the motor cools. “Ed” will be saved as stored error code. The left current sensor mounts around the cable that carries left drive motor current. The logics supplies a constant voltage to one lead of the current sensor at P1-16 wire #25 (12V). A second lead of the current sensor is connected to battery negative at the negative heatsink. When current passes through the cable, the third current sensor lead wire #L22 causes the voltage to change at logic P1-12. As the current passing through the cable increases, the voltage at logic P1-12 increases. The logics uses the voltage at P1-12 to determine the amount of current flowing through the left drive motor. Pump Motor Overtemperature Symbol The right current sensor, similar to the left current sensor, mounts around the cable that carries right drive motor current. A third lead of the right current sensor is connected to logics at P1-13 #R22. The logics uses the voltage at P1-13 to determine the amount of current flowing through the right drive motor. Pump Motor Overtemperature Symbol Contactors The pump motor thermal switch, similar to the drive motor thermal switch, will open if the motor gets too hot. The logics will reduce pump motor speeds. The overtemperature symbol and “EP” will display on until the pump motor cools. “EP” will be saved as stored error code. MicroController Control Systems The control panel is equipped with intermittent duty contactors. The logics controls the voltage supplied to the coils. When a contactor is first activated, full battery voltage is supplied to the coil. After the contactor tips have closed, the logics will pulse the coil to reduce the voltage across the coil to between 18 and 36 volts. 21 Systems Operation Battery Discharge Indicator (BDI) BATTERY TERMINAL VOLTAGE BAR SYMBOLS The logics monitors the battery voltage during truck operation and shows the level of battery charge on the LCD. If the battery voltage is below 40.0V or above 60.0V, this is a battery mismatch or misconnection. If these voltages are monitored, the display will show “Fb” on the LCD and no lift truck operate. TYPE 1 (OPT) : Closed Voltage DISPLAY Full 6 bars on the LCD indicates a fully charged battery. As the battery discharges, the bars decreases to 5, 4 etc, down to 1st bottom bar. When the battery nears the 80% discharge level, the 1st bar continuously flashes. This is a warning that lift interrupt is near. The operator should complete the current lift operation and travel to the battery replacement or charge area. If the truck is kept in operation, the display go to a “EL”. The lift, tilt and auxiliary functions will be vastly reduced in speed, operating only with steering flows and the vehicle travel speed will be cut in harf. At this point the battery is greater than 80% discharged. The logics will now remember that the battery has been discharged to lift interrupt and require a fully charged battery to reset the remembered interrupt. See Programmable Option Features “3”. 36V 48V 6 above 37.2 above 49.1 5 36.8 to 37.2 48.6 to 49.1 4 36.4 to 36.7 48.0 to 48.5 3 36.0 to 36.3 47.5 to 47.9 2 35.6 to 35.9 47.0 to 47.4 1 35.2 to 35.5 46.5 to 46.9 1* 25.8 to 35.1 33.8 to 46.4 O/EL below 25.8 below 33.8 1* = Display is flashing BATTERY TERMINAL VOLTAGE BAR SYMBOLS TYPE 2 (STD) : Closed Voltage DISPLAY Due to different voltage characteristic of battery technologies, it may be necessary to use the battery voltage chart as shown below. You can choose a type in Programmable Option Features “10”. 36V 48V 6 above 37.2 above 49.1 5 36.8 to 37.2 48.4 to 49.1 4 36.3 to 36.7 47.7 to 48.3 3 35.9 to 36.2 47.1 to 47.6 2 35.4 to 35.8 46.4 to 47.0 1 35.0 to 35.3 45.9 to 46.3 1* 34.5 to 34.9 45.0 to 45.8 O/EL below 34.5 below 45.0 1* = Display is flashing Descriptions of BDI symbol on the LCD Bar Symbols BATTERY TERMINAL VOLTAGE BAR SYMBOLS 6 : The highest position : Max. charged status TYPE 3 (OPT) : Closed Voltage DISPLAY 5: 36V 48V 6 above 37.2 above 49.1 4: 5 36.9 to 37.2 48.3 to 49.1 3: 4 36.6 to 36.8 47.4 to 48.2 3 36.3 to 36.5 46.6 to 47.3 2 35.9 to 36.2 45.7 to 46.5 1 35.6 to 35.8 44.9 to 45.6 1* 35.3 to 35.5 44.0 to 44.8 O/EL below 35.3 below 44.0 2: 1: : A) Not flashing B) Flashing - 80% discharge warning. 1* = Display is flashing MicroController Control Systems 22 Systems Operation Accelerator Control Steer Angle Control Accelerator Table OUTPUT VOLTAGE REMARKS OVER ACCELERATOR CIRCUIT 11.00 DEFECT 9.60 BYPASS OPERATION DRIVE SPEED (100%) 9.02 8.44 7.86 7.28 6.70 6.12 5.54 4.96 4.38 3.80 3.22 2.64 2.06 1.48 0.90 0.00 Two drive motors are controlled independently according to steer wheel position. A direction of drive motors is determined with wheel angle as shown in the chart. WHEEL ANGLE DRIVE SPEED STEP 14 DRIVE SPEED STEP 13 **DEAD ZONE I** DRIVE SPEED STEP 12 DRIVE SPEED STEP 11 DRIVE SPEED STEP 10 ON - TIME(%) P2-17 P2-18 P2-19 P2-20 -90° LOW HIGH HIGH HIGH -75° LOW HIGH HIGH -45° LOW HIGH L 25° LOW +45° HIGH LEFT RIGHT (-)50 50 LOW 0 75 LOW LOW 75 100 LOW LOW LOW 100 100 LOW LOW LOW 100 75 +75° HIGH HIGH LOW LOW 75 0 +90° HIGH HIGH LOW HIGH 50 (-)50 DRIVE SPEED STEP 9 (–) means that the motor will turn opposite direction. DRIVE SPEED STEP 8 DRIVE SPEED STEP 7 DRIVE SPEED STEP 6 DRIVE SPEED STEP 5 DRIVE SPEED STEP 4 DRIVE SPEED STEP 3 DRIVE SPEED STEP 2 DRIVE SPEED STEP 1 DRIVE SPEED STEP 0 **DEAD ZONE II** i) DEAD ZONE I In order to eliminate the bypass contactor chattering, the bypass contactor will be engaged if the accelerator output voltage is over than 9.6V. But the bypass contactor should be disengaged if the accelerator output is less than 9.02V. ii) DEAD ZONE II In order to eliminate the direction contactors chattering, the direction contactors will be engaged if the accelerator output voltage is over than 1.48V. But the direction contactors should be disengaged if the accelerator output is less than 0.9V. MicroController Control Systems 23 Systems Operation Accessory Circuits Horn Circuit The 12 volt output of the converter is protected against short circuits and overloading by an internal 15 amp current limit circuit. A fuse on the converter protects it from reverse connection of the battery voltage. The horn will operate when the battery is connected and the horn button is pushed. Current flows from battery positive through horn fuse, horn switch and horn, back to battery negative. Refer to Problem 31 in Troubleshooting section. Hour Meter Circuit NOTICE Do not connect the 12volt negative output of the DC-DC converter to battery negative. Damage to system components could occur. The hour meter, dependent on marketplace, can be wired a number of different ways. Battery voltage is always supplied from the key switch to the positive terminal of the hourmeter. The negative terminal of the hourmeter can go to seat switch to record seat switch hours, or can be wired into the drive motor armature through a diode assembly to record drive motor hours. DC-DC Converter DC-DC Converter Circuit System The DC-DC converter changes the lift truck battery voltage to 12 volts. This 12 volts is used to power accessories such as floodlights, brakes/side lights and backup alarms. The positive of the 12 volt output is common to the positive of the battery voltage. The negative of the 12 volt output is pulsed to maintain a steady 12 volt supply. MicroController Control Systems 24 Systems Operation Actuation Circuit Actuation Circuit When the battery is connected and the key switch is closed, current flows from battery positive through the key fuse, key switch, wire #5 to the logic connector P1-1 and P1-2. The logic connection to battery negative is at P1-19 and P1-20. The logic circuits are powered up to accept voltage inputs and create voltage outputs whenever the battery is connected and the key is turned to ON. NOTE: The circuit diagrams have shaded lines for illustration of current flow in each circuit. Other circuits can be activated at the same time, but each one is shown separately to illustrate current flow in each individual circuit. This circuit supplies power to the MicroController Control System and the Central Vehicle Monitoring System (CVMS). It must be activated before power steering, hydraulics or drive will operate. MicroController Control Systems 25 Systems Operation The Central Vehicle Monitoring System (CVMS) is also powered at this time. The CVMS first does a “LCD test” which will light all the warning lights through 6 shield wires, wire #101(5V) and wire #108 (B-) for approximately five seconds. Hydraulic Pump Motor Circuit Only one hydraulic pump motor (series winding) is used for all power steering, lift, tilt and auxiliary hydraulic functions. To activate the pump circuit, the seat switch, key switch and line contactor must be closed first as explained in the topic, Actuation Circuit. The logics will start to perform a set of “Run Time” diagnostic checks. The letter “EE” will flash on the CVMS display indicating the key is ON with no operator in the seat. When the seat switch is closed, current will flow from the logic P2-7 through the seat switch to battery negative. The logics then activates the line contactor by allowing current to flow from P1-3 through the line contactor coil and P1-4 back to battery negative. Power Steering Circuit With the line contactor tips closed the logics continues its checks for any “Run Time” faults. If no faults are detected the display will indicate the battery charge level, the power steering (IDLE) system operates, the pump and drive power circuits receive battery voltage and the logics receives battery voltage on wire #4 at P9-9. Followings are standard PTR1 pulsing rates of the signal at the logics. The power steering (PS) circuit has two speeds (PS idle and PS boost-up) independent of the lifting speeds. Motor Speed PTR1 Pulsing Rate Logic Pin# IDLE 11% – POWER STEERING 17% P2-1 TILT 50% P2-2 LIFT1 35% LIFT2 50% LIFT3 95% AUX. 45% P2-3 & P2-4 P2-16 The above pulsing rate can be adjustable in “Programmable Option Features”. NOTE: The circuit diagrams have shaded lines for illustration of current flow in each circuit. Other circuits can be activated at the same time, but each one is shown separately to illustrate current flow in each individual circuit. MicroController Control Systems 26 Systems Operation Lift Circuit Lift Circuit When the lift lever is pulled to lift speed 1 the logics will pulse the pump transistors PTR1. If the streeing wheel is turned, hydraulic pressure increases and a pressure switch (PRESSURE SW) located in the steering gear load sensing hose, will open. This causes the voltage at logic connector P2-1 to change from a LOW (less than one volt) to a HIGH (12 volts). When a HIGH is present the logics knows that more hydraulic flow is required and will supply a pulse from P9-3 to PTR1 at rate of 17% “on-time” for 48 volt trucks. The pump motor speed will increase. MicroController Control Systems As shown in the chart under Lift Control Circuit, if the lift lever is pulled to lift speeds 2 through 3 the pump transistors are pulsed with a higher percent “on-time”. The pump motor armature will turn faster. 27 Systems Operation Power Steering Idle Transistor PTR1 Pulsing TR6 Base Input Signal logics is ON at TR6, TR6 will be ON. When the base signal is OFF, TR6 will be OFF. After the line contactor is closed the logics generates a positive pulsing signal (approximately 0.7 volts) on P9-3 to the base of transistor TR6. This is a rapidly changing signal that can only be viewed on an oscilloscope. Because TR6 is a NPN type transistor, the positive signal into the base causes current flow through the base/emitter junction. When current flows through the base/emitter junction the transistor turns ON and main current will flow through the collector/emitter junction. If the base signal from the MicroController Control Systems 28 Systems Operation TR5 Base Input Signal, TR6 ON When TR6 is ON, current flows through the emitter/base junction of transistor TR5, through PR1 and TR6 to battery negative. Because TR5 is a PNP type transistor, the current flow to battery negative through the emitter/base junction causes TR5 to turn ON. When TR6 is OFF, TR5 is OFF. MicroController Control Systems 29 Systems Operation PTR1 Base Input Signal, TR5 and TR6 ON When TR5 is ON, current flows through TR5 into the base of transistor PTR1. This puts a voltage signal at the base of PTR1 causing PTR1 to turn ON. With PTR1 ON, high amperage motor current can flow through PTR1, motor armature and motor field to battery negative. When TR5 and TR6 are OFF, PTR1 is OFF. The percent “on-time” of the signal at the logics is also the percent “on-time” of PTR1. PTR1 is pulsed at 11% “on-time” supplying 11% of battery voltage to the pump motor (IDLE). MicroController Control Systems 30 Systems Operation Flyback Circuit Flyback Circuit PD is a flyback diode for the power steering and hydraulic motor circuit. This circuit uses the current created by the collapsing magnetic field of the field windings in the pump motor to keep current flowing when transistor PTR1 is OFF. When PTR1 is OFF all current from the field goes through P2, PD, P1 and pump motor armature (ARM) back to the field. When PTR1 is pulsing the flyback circuit causes the average pump motor current to be greater than the average battery current through PTR1. MicroController Control Systems 31 Systems Operation Lift Control Circuit 1 Location of Components (1) Valve Control Card. This control panel accept a three speed lift control signals and tilt/aux lever signals. The three speed lift control system is controlled by valve control card (1) mounted at the top of the control valve. When the operator pulls the lift lever, magnet (3) moves closer to the lift sensor (2). The sensor detects the increasing magnetic field and sends an increasing voltage to the valve control card. The valve control card produces voltage changes which input to the logics at P2-3 and P2-4 The logics uses these changing voltages to determine what speed to operate the pump motor. The logics then controls the pump transistor PTR1. The pump motor lift speed as shown in the chart. The valve control card uses a hall-effect transducer (LIFT SENSOR) and a magnet to sense lift lever movement. The closer the magnet is to the transducer the greater the hydraulic pump motor speed. 2 Motor Speed P2-3 P2-4 PTR1 Remark 0 12V 12V Steering Variable 1 0.2V 12V 35% Pulsing Variable 2 0.2V 0.2V 50% Pulsing Variable 3 12V 0.2V 95% Pulsing Preset 3 Location of Components (2) Lift Sensor. (3) Magnet. MicroController Control Systems 32 Systems Operation Drive Circuit Control Circuit Drive Control Circuit Selecting a direction will change the voltage from HIGH to LOW on P2-5 for forward or P2-6 for reverse. Depressing the accelerator pedal will cause the accelerator analog voltage on P1-15. With the forward direction selected current flows from the logics P1-3 through forward direction contactor coil to logics P1-5 and P1-7 back to battery negative. The forward contactors tips close. NOTE: The circuit diagrams have shaded lines for illustration of current flow in each circuit. With the actuation circuit complete the logics supplies a HIGH voltage (12volts) to the direction (F/R) switch at P2-5 and P2-6. A HIGH voltage is also supplied to the power of accelerator at P1-16. Releasing the park brake closes the park brake switch and provides a path to battery negative. MicroController Control Systems 33 Systems Operation Power Circuit TR2 and TR4 Base Input Signal The logics generates a positive pulsing voltage (approximately 0.7 volts) on P9-1 and P9-2, to the base of transistors TR2 and TR4. These pulses turn ON TR2 and TR4 which turn ON TR1 and TR3. A more complete description of this transistor turn on circuit can be found in : Hydraulic Pump Motor Circuit under Power Transistor Pulsing. NOTE: The circuit diagrams have shaded lines for illustration of current flow in each circuit. Other circuits can be activated at the same time, but each one is shown separately to illustrate current flow in each individual circuit. The high amperage current, which provides the power and torque necessary to drive the lift truck, flows in this circuit. The speed of the drive motor is controlled separately from the pump motor circuit by the MicroController Control System. MicroController Control Systems 34 Systems Operation Power Transistors, TR1, TR2, TR3 and TR4 all ON The percent “on-time” of the voltage at logics P9-1 and P9-2 is also the percent “on-time” of the power transistors. As the “on-time” increases, the average voltage applied to the drive motor increases which increases the speed of the lift truck. The percent “on-time” out of the logics is determined by how far the accelerator is depressed. When TR1 and TR3 are ON, current flows through TR1 and TR3 emitter/collector into the base of drive power transistors (DTR1 and DTR2). This puts a HIGH voltage at the base of the power transistors causing them to turn ON. With the power transistors ON, high amperage motor current can flow through them, the field, forward contact tips, armatures, forward contact tips and current sensors back to battery negative. When TR1 and TR3 are OFF, the power transistors are OFF. MicroController Control Systems 35 Systems Operation Flyback Circuit Flyback Circuit Because of this, the average drive motor armature current will be greater than the average battery current. Refer to following Average Current Flow chart. When the drive power transistors (DTR1 and DTR2) are ON, battery current flows through the field windings of the drive motor and a magnetic field is created around the windings. When the power transistors are turned OFF battery current through the windings stops and the magnetic field collapses. This collapsing magnetic field induces current which is used to power the drive motor while the power transistors are OFF (during pulsing). Induced current flows from the field windings through the forward contact tips, armature, forward contact tips, current sensor and diodes DD1, DD3 back to the field windings. MicroController Control Systems 36 Systems Operation Average Current Flow Current Limit through the sensor and will increase or decrease as current changes. The logics uses this voltage to monitor the current in the circult. When the current has increased too high, the logics decreases the pulse rate to the transistors to prevent current higher than the preset value. The logics monitors the current that flows through DTR1 and DTR2 and limit this current flow to a preset value. As this current flows through DTR1 and DTR2 the drive motor and the current sensors, a voltage is created by the sensor. This voltage is proportional to the current flowing MicroController Control Systems 37 Systems Operation Bypass Circuit Bypass Circuit Activated The bypass circuit bypasses DTR1 and DTR2 and connects the drive motor in series with the battery, applying full battery voltage to the drive motor. If the accelerator pedal is fully depressed, and the logics has pulsed DTR1 and DTR2 through 92% “on-time”, the logics will activate the BYPASS CTR after 1.5 seconds. MicroController Control Systems 38 Systems Operation Electrical Braking (Plugging) Plugging Circuit (Transistor DTR1, DTR2 “ON”) When DTR1 and DTR2 are ON, battery current flows through DTR1 and DTR2, field windings, direction contactor tips, armature, direction contactor tips and current sensor back to the battery. Current energizes the field and tries to turn the armature opposite the rotation caused by the truck’s motion. The current acts to electrically brake the truck. With the field energized and momentum of the truck turning the armature opposite the pulsed direction, the armature generates current. Plugging is an electrical braking mode which permits the lift truck operator to slow, stop and change the direction of travel electrically without using the service brake. Plugging begins when the operator selects a direction opposite the lift truck’s motion, while keeping the accelerator depressed. The logics will deactivate the bypass contactor (if activated) and change the direction contactors to the new direction selected. The momentum of the truck causes the drive motor to generate current, and the logics will puise the transistors at a slow rate. MicroController Control Systems 39 Systems Operation Plugging Circuit (Transistor DTR1, DTR2 ”OFF”) back to the field. This current continues the electrical braking action. As long as the truck momentum is turning the armature opposite the pulsed direction, the motor continues to act as a generator with armature generated current flowing through DD2, DD4 back into the armature. When the truck has come to a stop, the armature no longer is turning opposite the pulsed direction. The armature stops generating current and DD2, DD4 no longer conducts. The logics no longer detects a more negative voltage on plug sensing wire #32 than on wire #1, so normal drive operation begins in the opposite direction. The generated current flows from the armature through the direction contactor, current sensor and diode DD2, DD4, back to the armature. When armature generated current flows through DD2, DD4 wire #1 at P1-20 becomes a more positive voltage than plug sensing wire #32 at P1-10, P1-11, due to the voltage drop across DD2, DD4. The logics detects the voltage change at P1-20 and P1-10, P111, then reduces the tansistor pulsing to stay below the preset plugging current limit. When DTR1 and DTR2 are OFF, flyback current from the collapsing motor field flows through the direction contactor tips, armature, direction contactor tips, current sensor and diode DD1, DD3, MicroController Control Systems 40 Systems Operation Thermal Protection Circuits Control Panel Hydraulic Pump Motor If the power transistors overheat, a thermal switch mounted in the transistor heatsink will open at a predetermined temperature. When it opens, voltage at logic connection P2-11 will go HIGH (12 volts). The Central Vehicle Monitoring System will display a “Run Time” diagnostic symbol. The logics will decrease the pulsing of the drive system and restrict the hydraulic circuit pulsing to 50%. The amount of current allowed to flow through the power transistors is decreased to permit them to cool. When the heatsink cools off and the thermal switch closes, the truck will return to normal operation. Drive system bypass is not affected by an overheated control panel, but due to the reduced pulsing acceleration performance will be decreased. An “Ec” is stored in memory. If the hydraulic pump motor overheats a thermal switch mounted in the pump motor housing will open at a predetermined temperature. When it opens, voltage at logic connection P2-13 will go HIGH. The Central Vehicle Monitoring System will display a “Run Time” diagnostic symbol. To decrease the amount of current allowed to flow through the pump motor, the logics will reduce the hydraulic pump motor to 50% pulsing. When the hydraulic pump motor cools off and the thermal switch closes, the truck will return to normal operation. An “EP” is stored in memory. Failure Protection Circuit If the logics detects an improper voltage at P9-5 wire #L64 (left drive circuit) and/or P9-6 wire #R64 (right drive motor) or P9-7 wire #74 (pump circuit), the line contactor will be deactivated and a “Run Time” diagnostic code (display = “F2” through “F7”) will display. Current is also monitored in the drive motor, and should it exceed preset limits in either pulsing or bypass the truck will shut down and display an “F0”. The logics will monitor the four steering angle switch signals, wires #50, 51, 52 and 1 to determine if there is an out of sequence problem. An “FA” will be displayed if this should occur. If the battery voltage is mismatched, the “Fb” will display. The logics will monitor the two current sensor signals, wires #L22 and #R22 to determine if there is an wrong voltage pattern. An “F5” will be displayed. Once a failure has been detected the truck must be repaired before normal operation can resume. Drive Motor If the drive motor overheats a thermal switch mounted in the drive motor housing will open at a predetermined temperature. When it opens, voltage at logic connection P2-12 will go HIGH. The Central Vehicle Monitoring System will display a “Run Time” diagnostic symbol. To decrease the amount of current allowed to flow through the drive motor, the logics will reduce the pulsing and disable the bypass contactor. When the drive motor cools off and the thermal switch closes, the truck will return to normal operation. Drive system acceleration performance and top travel speed is affected by an overheated drive motor. An “Ed” is stored in memory. MicroController Control Systems 41 Systems Operation Testing And Adjusting Troubleshooting NOTICE Damage can be caused to the control panel. Do not switch the direction lever from one direction to the other (plug the lift truck) when the drive wheels are off the ground and in rotation at full speed. The following Troubleshooting Check List is an aid in troubleshooting MicroController lift trucks. The troubleshooting check list, “Run Time” diagnostic indications, “Self” diagnostic tests, problem list and problem flow charts will assist in: 1. Defining the problem and verifying a problem exists. Troubleshooting Check List 2. Performing the checks in a logical order. 1. Perform Preparation Tests and Checks. 3. Making the necessary repairs. 2. Correct any display problems and “Run Time” diagnostic faults. 4. Verifying the problem has been resolved. 3. Correct the “Self” diagnostic faults. 4. Perform Operational Checks. WARNING The lift truck can move suddenly.Battery voltage and high amperage are present. Injury to personnel or damage to the lift truck is possible. Safely lift both drive wheels off the floor. Put blocks of wood under the frame so the drive wheels are free to turn. During any test or operation check, keep away from drive wheels. Before any contact with the control panel is made, disconnect the battery and dis- charge HEAD CAP. Ring's, watches and other metallic objects should be removed from hands and arms when troubleshooting, the MicroController Control System. 5. Correct “Failure Code Problems” in the Troubleshooting Problem List. NOTICE Damage can be caused to the test equipment. Make resistance and continuity checks only after the battery is disconnected. 1. Verify proper polarity at the battery connector and the MicroController panel. Positive cable should be at the line contactor and negative at the negative heatsink. 6. Perform Operational Checks to verify repairs. Preparation Tests and Check Battery Tests A weak battery can cause or contribute to problems in the MicroController and power circuits. Verify the battery is good before investigating other possibilities. 2. If the lift truck is operational, perform a battery load test. 3. If the truck is not operational and the battery is suspected, perform a cell voltage or specific gravity test. NOTICE Damage can be caused to the control panel. Do not use steam or solvent to clean the controls. Use pressure from an air hose with a maximum pressure of 205 kPa (30 psi) to clean the control panel when necessary. Make sure the air pressure supply is equipped with a water filter. MicroController Control Systems 42 Testing And Adjusting Battery Load Test Hydrometer Test 1. Turn the range switch on the multimeter to read battery voltage. Test each cell of the battery with a hydrometer. If the specific gravity indication is below 1.140, the battery must be charged. The battery is fully charged if the indication is 1.265 to 1.285. 2. Connect the battery. NOTE : The indication between cells should not differ more than .020. If it does, the battery needs an equalizing charge or needs to be repaired. 2 Battery Maintenance NOTE : It is important that all batteries be charged and maintained according to the battery manufacturers instructions. 1 The care and maintenance of batteries is most important to maximize battery life and efficient truck operation. Periodic inspection and service will increase the life of batteries. Special attention should be given to the rules that follow: Battery Voltage Test. (1) Positive cable connection. (2) Negative cable connection. 1. Keep batteries clean at all times. Cleaning will prevent corrosion, current leakage and shorts to chassis. Tighten all vent plugs, wash the battery with water and a brush, then dry with an air hose. It may be necessary to use a baking soda solution if water alone will not clean the top of the battery. 3. Connect the multimeter leads between positive (+) cable connection (1), and negative (-) cable connection (2). 4. In a safe area, operate the hydraulic system, (hold tilt lever to maximum position momentarily) while reading the voltage indicated on the multimeter. 2. Add enough water to cover the plates before charging. This will ensure the proper chemical reaction over the entire plate surface. After charging is complete, add water until it is about 12.7 mm (.50 in) above the plates. Use distilled water or water that has tested free from minerals. 5. If the indication is less than 44.2 volts, the battery needs to be charged or repaired before continuing to troubleshoot. 3. Charge the battery correctly. A battery should be discharged to 80% of its capacity then fully recharged. It should cool four to eight hours to allow the voltage to stabilize before being put back in use. The battery should have an equalizing charge (an extra three or four hour charge at a low finish rate) once a month to make sure all cells are in a fully charged condition. Properly charged batteries should be identified to prevent low batteries from being installed in trucks. Cell Voltage Test With the truck powered up and the power steering motor running, measure the voltage at each cell. Normal voltage should be between 1.95V and 2.12V per cell. If the voltage on each cell is below 1.95V the battery must be charged or repaired before continuing to troubleshoot. NOTE : The indication between cells should not differ more than 0.05 volts. If it does, the battery must have an equalizing charge or be repaired. MicroController Control Systems 4. Operation with a low battery must be prevented. Low battery operation may damage the battery and will cause higher than normal current in the electrical system. High current draw due to a low battery will damage contactor tips and shorten motor brush life. 43 Testing And Adjusting 5. The battery's maximum temperature is critical. The electrolyte temperature should never exceed 43°C (110˚F) either while operating or charging. Overcharging a battery will cause over heating and warp the battery plates. Maximum battery life will result from maintaining 25˚C (77˚F) electrolyte temperature. Most of the charging equipment is fully automatic but should be checked periodically to assure proper working order. Resistance to Chassis Checks Resistance between any point in the truck wiring and the chassis should be a minimum of 10,000 ohms or more. Many malfunctions are caused by shorts to chassis. Usually, two shorts must exist before a malfunction will occur. But, since batteries can have chassis leakage, only one short to chassis in the truck wiring can cause problems. To prevent problems because of shorts, do the following: 6. Keep accurate battery records. Regular battery readings should be taken with a battery tester or voltmeter and a written record kept. Specific gravity and voltage of each cell should be checked and recorded at least once each month. This inspection should be made after an equalizing charge. Readings should never be taken directly after water has been added. Records of all battery maintenance should be made and filed so it will be known which batteries are being abused or wearing out. 1. Disconnect the battery and discharge the HEAD CAP. 2. Randomly measure any component connection or wiring connection in respect to the lift truck chassis for a minimum resistance of 10,000 ohms. Any test point with low resistance must have the short to chassis removed. Repairs should be made immediately otherwise the battery may become damaged. Batteries stored in a discharged condition may be difficult to recharge due to sulfate formation. 3. Always keep batteries clean to minimize current leakage to the chassis. 4. Routinely clean the brush dust from the motors. 5. Be sure that all attachments, such as horns and lights are designed for no chassis connection (a two wire system). Visual Checks 1. Verify all components and wires are in their proper place. Check fuses, components, contactor tips, wires and connections. Verify that they are not burned, broken or loose. Removal of Shorts to Chassis When a short is found, it must be cleared even if the machine has normal operation. It is necessary to narrow the field of possible problem areas before inspection of individual wires and components. 2. Verify there is no mechanical binding or interference in the contactors. 3. Visually check the parking brake switch, the lift switch and accelerator linkage for adjustment or interference problems. MicroController Control Systems When a low resistance circuit is located, it should be opened at various points. This will permit the shorted wire or component to be pin-pointed for repair or replacement. 44 Testing And Adjusting Control and Power System Operational Checks All operational checks are to begin with the battery connected, directional switch in neutral, drive wheels off the ground and the accelerator and parking brake released. 4. Depress the accelerator fully. The forward contactors should remain activated. The bypass contactors should activate. The drive wheels will turn forward at full speed. NOTE: Perform all operational checks before returning to the Troubleshooting Check List. Check 5: Reverse Drive Performance Check 1: Key Switch, Seat Switch and Power Steering 1. Select reverse direction and depress the accelerator slightly. The reverse contactors should activate and the drive wheels should turn in reverse slowly. 1. Activate the key and seat switch. The line contactor activate and the hydraulic pump motor should turn on at slow speed (idle). 2. Slowly increase the amount of accelerator depression. The reverse contactors should remain activated. The drive wheels should turn in reverse and slowly increase in speed. 2. Turning the steering wheel will increase the hydraulic pump motor speed (boost-up). 3. Depress the accelerator fully. The reverse contactors should activated. The bypass contactors should activate. The drive wheels will turn in reverse at full speed. 3. After five to ten seconds the line contactor deactivates and the motor turns off. Check 2: Lift Performance Check 6: Electrical Braking (Plugging) Performance 1. Pull the lift lever half way. The hydraulic pump motor activates slowly to a preset speed. 2. Pull the lift lever to maximum. The hydraulic pump motor activates full speed. NOTICE Do not perform this check with the lift truck in bypass mode. Damage to the Drive Train can result. Check 3: Tilt and Auxiliary Performance 1. Slowly pull and push the tilt and auxiliary levers. The hydraulic pump motor activates to one of the preset speeds with each lever movement. 1. Select forward direction and depress the accelerator to the point before bypass occurs. While continuing to depress the accelerator, change the direction switch to reverse. The forward contactors should deactivate and the reverse contactors should activate. There should be a smooth deceleration of forward tire rotation. After the forward tire rotation stops, there is a smooth acceleration of reverse tire rotation. Check 4: Forward Drive Performance 1. Engage the parking brake. Select forward direction and depress the accelerator slightly. The forward contactor should NOT activate and the drive wheels should NOT turn. 2. Release the parking brake, select forward direction and depress the accelerator slightly. The forward contactors should activate and the drive wheels should turn forward slowly. 2. Continue to depress the accelerator while in reverse direction. Change the direction switch to forward. The reverse contactors should deactivate and the forward contactors should activate. There should be a smooth deceleration of reverse tire rotation. After the reverse tire rotation stops, there is a smooth acceleration forward tire rotation. 3. Slowly increase the amount of accelerator depression. The forward contactors should remain activated. The drive wheels should turn forward and slowly increase in speed. MicroController Control Systems 45 Testing And Adjusting Built-In Diagnostic Operation The logics and the display provide built-in diagnostic analyzer functions. Several diagnostic functions occur while the lift truck is in operation. These are called “Run Time” diagnostics. The other diagnostics are called “Self” diagnostics. They are performed when the lift truck is not in operation by using a switch located in the logics. Display =“Ec” Lift truck will not operate, see Troubleshooting Problem 20. Possible cause, control panel thermal problem. The overtemperature indication will display on LCD. Display =“Ed” Lift truck will not operate, see Troubleshooting Problem 21. Possible cause, drive motor thermal problem. The overtemperature indication will display on LCD. Central Vehicle Monitoring System (CVMS) Problems Display =“EP” Lift truck will not operate, see Troubleshooting Problem 22. Possible cause, pump motor thermal problem. The overtemperature indication will display on LCD. If the display does not work, or it’s operation seems incorrect see Troubleshooting Problems 1, 2, 3 and 4. “Run Time” Diagnostics (Lift Truck in Operation) Display =“EL” Lift truck will not operate, see Troubleshooting Problem 23. Possible cause, low battery voltage. The diagnostic functions that follow would occur during normal lift truck operation and are shown on the seven segment display. Display =“F0” Lift truck operates, then shuts down during travel. See Troubleshooting Problem 32. Possible cause, excessive currents in drive motor. NOTE: Improper lift truck operation with normal battery indication, should be checked with “Self” diagnostics. Display =“F2” Lift truck will not operate, see Troubleshooting Problem 33. Possible cause, a failed left drive power transistor (DTR1). Display =“F2” (Flashing) Lift truck will not operate, see Troubleshooting Problem 34. Possible cause, a failed right drive power transistor (DTR2). Display =“F3” Lift truck will not operate, see Troubleshooting Problem 35. Possible cause, a failed pump power transistor (PTR1). Display =“F4” Lift truck will not operate, see Troubleshooting Problem 36. Possible cause, failed pump and drive power transistors. Display =“F5” Lift truck will not operate, see Troubleshooting Problem 37. Possible cause, left drive flyback diode DD1 failed. Display Layout Display =“EE” No Lift truck operation, see Troubleshooting Problem 17. Possible cause, static return to off. Display =“F5” (Flashing) Lift truck will not operate, see Troubleshooting Problem 38. Possible cause, right drive flyback diode DD3 failed. Display =“EE” (Flashing) Lift truck will not operate, see Troubleshooting Problem 18. Possible cause, seat switch open. Display =“F6” Lift truck will not operate, see Troubleshooting Problem 39. Possible cause, pump flyback diode PD failed. Display =“E1” or “E2” Lift truck will operate, see Troubleshooting Problem 19. Possible cause, pump or drive brush problem. MicroController Control Systems 46 Testing And Adjusting Display =“F7” Lift truck will not operate, see Troubleshooting Problem 40. Possible cause,pump and drive flyback diodes (DD1,DD3 and PD) failed. Display =“FA” Lift truck will not operate, see Troubleshooting Problem 41. Possible cause, steer angle switch failure or harness problem. Display =“Fb” Lift truck will not operate, see Troubleshooting Problem 42. Possible cause, abnormal battery condition. Display =“Fd” Lift truck will operate, see Troubleshooting Problem 43. Possible cause, pressure switch failure or harness problem. MicroController Control Systems 47 Testing And Adjusting “Self” Diagnostics (Lift Truck not in Operation) The diagnostic procedure should be used to aid in troubleshooting after a problem occurs. It will help to find the faulty circuit or component. Complete all the tests before returning to the MicroController Troubleshooting Check List. Before testing, do the steps that follow : 3 1. Turn the key to off. 2 2. Disconnect the battery and discharge the head capacitor below 5 volts by holding the discharge resistor in place for 10 seconds. Removing Cover from Logic Unit (Logics) (2) Screws. (3) Cover. 5. Loosen four screws (2) to remove logic cover (3). 4 Location of Fuse (1) Line fuse. 3. Disconnect line fuse (1) to prevent lift truck movement. DIAG/RUN/SETUP Switch Location (4) Switch. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Disconnect the battery and disconnect the line fuse to prevent lift truck movement. 6. Move switch (4) to “DIAG” position. This places the controller in diagnostics when the battery is connected and key is turned to ON. 7. Connect the battery and turn key to ON. 4. Release the parking brake to close the park brake switch. MicroController Control Systems 48 Testing And Adjusting Test 4 : Lift Switch Circuit Display = “blank” See Troubleshooting Problems 1 or 2. Pull lift lever slowly. Display now shows the speed that the lift lever is set to. As lever is pulled back, 0 throngh 3 will be shown. Display = “F” Logics has a failure. Replace logics. This indicates at what position the lift lever changes the pump motor speed. Display = “d” Line fuse is not disconnected or discharge the head capacitor. Return to step 2. If still “A0” lift switch circuit defect, see Troubleshooting Problem 10. Display = “8b” Direction lever is in the reverse position. Move direction lever to neutral. Test 5 : Tilt Switch Circuit Pull tilt lever to maximum. Display = “A6” Tilt switch circuit OK. NOTE: This test does not check all the logics circuit, so the logics may pass this test and still have a failure. Release tilt lever. Display = “A0” Tilt switch circuit OK. The LCD will display all symbols about 2 seconds. Display = “A0” Ready for test 1. If still “A0” or “A6”, tilt switch circuit defect, see Troubleshooting Problem 11. Test 1 : Seat Switch Test 6 : Auxiliary Switch Circuit Press seat to close seat switch. Display = “A1” Seat switch circuit OK. Pull auxiliary lever to maximum. Display = “A7” Auxiliary switch circuit OK. Release seat to open seat switch. Display = “A0” Seat switch circuit OK. Release auxiliary lever. Display = “A0” Auxiliary switch circuit OK. If still “A0” or “A1”, see Troubleshooting Problem 8. If still “A0” or “A7”, auxiliary switch circuit defect, see Troubleshooting Problem 12. Release the park brake lever. Test 2 : Reverse Direction Switch Test 7 : Parking Brake Switch Move direction switch from neutral to reverse. Display = “A2” Direction switch circuit OK. Pull park brake lever to maximum. Display = “A9” Park brake circuit OK. Move direction switch from reverse to neutral. Display = “A0” Direction switch circuit OK. Release Park brake lever. Display = “A0” Park brake circuit OK. If still “A0” or “A1”, see Troubleshooting Problem 9. If still “A0” or “A9”, Park brake circuit defect, see Troubleshooting Problem 13. Test 3 : Forward Direction Switch Move direction switch from neutral to forward. Display = “A3” Direction switch circuit OK. Move direction switch from forward to neutral. Display = “A0” Direction switch circuit OK. If still “A0” or “A3”, see Troubleshooting Problem 9. MicroController Control Systems 49 Testing And Adjusting Test 8 : Accelerator Control Contactor Test Press accelerator pedal to maximum. Display = The speed symbols will increase from 0 to 10 on the LCD, Accelector circuit OK. Test 9 through 14 may be activated in regular sequence by movement of the DIAG/RUN/SETUP (4) to “Run” then back to “Diagnostic” position, and “AC” will display on the LCD. Release accelerator pedal. Display = The speed symbols will decrease from 10 to 0 on the LCD, Accelector circuit OK. Test 9 : Line Contactor Test 10 : Bypass Contactor If the speed symbols is not full on the LCD, see Troubleshooting Problem 14. Test 11 : Left Forward Direction Contactor Test 1 through 8 may be checked without sequence and there are repeatable checkings to adjust switches and levers. Test 12 : Right Forward Direction Contactor Test 13 : Left Reverse Direction Contactor Test 14 : Right Reverse Direction Contactor If the above actions do not occur, see Troubleshooting Problem 15. 5 This completes the built-in diagnostic test. Contactor test may be repeated contiune by movement of the DIAG/RUN/SETUP to “Run” then back to “Diagnostic” position. After running through the contactor testing, pull tilt lever and then release to netural position will access the stored error codes. See Accessing Stored Error Codes. Contactor Locations (5) Line contactor. 7 8 6 Contactor Locations (6) Bypass contactor. (7) Right direction contactor. (8) Left direction contactor. MicroController Control Systems 50 Testing And Adjusting Accessing Stored Error Codes Saving Service Records The B18X series of trucks remembers the last 24 error codes. This is useful in case the truck has had an intermittent problem, but the operator cannot remember which code appeared on the display. Also by analyzing the contents of the last 24 error codes, it may be possible to determine what sort of application the truck has been working in. To save service records, the following procedures are used at the end of self diagnostics and service records are numbered from 1 to 9. 1. Access all of the error codes until display shows static “E” on the LCD. 2. Move the direction lever to the forward then display will show static “8d”. The stored error codes are accessed at the end of diagnostics by using the following procedure: 3. Move the DIAG/RUN/SETUP switch to “SETUP” and back to “DIAG” two times. 1. Access the self diagnostics procedure as usual. 2. Either step through the self diagnostics procedure, or override each test by moving the DIAG/RUN/SETUP switch from DIAG to RUN and back to DIAG until the contactor testing is completed. 4. Pull the tilt lever to maximum position and then release. 3. Cycle the DIAG/RUN/SETUP switch once more, and cycle through the contactor testing again. After the right reverse contactor drops out, now the display will indicate a “AC”. 6. Wait until the display will show a flashing “8d”, the display indicates that a service record have been saved. 5. A saved service records will show for a few second. 7. Turn OFF the key switch. The error codes can now be accessed one at a time by pulling tilt lever and then release. This will display the most recent error code. By cycling the tilt lever more times, more error codes will appear on the display, up to a total of 24. When the display shows a solid “E”, it will indicate that all of the stored error codes have been displayed. It is possible that the “E” will appear immediately, indicating no error codes have been encountered. Erased Stored Error Codes To erase all of the error codes, the following procedures are used at the start of self diagnostics. 1. Move the direction lever to the reverse and the DIAG/RUN/SETUP switch to the DIAG position. 2. Turn on the key switch and wait until display shows a solid “8b”, then move the DIAG/RUN/SETUP switch to the SETUP position and back to DIAG two times. 3. Move the direction lever to neutral. 4. Wait until the display will show a “A0”, the display indicates that all error codes have been erased. 5. Turn off the key switch. MicroController Control Systems 51 Testing And Adjusting Stored Error Codes Quick Diagnostic Procedure The following are possible error codes stored in memory. Most error codes are identical to the ones displayed during RUN. An alternative method of entering diagnostics has been programmed into the logics. This will enable quick diagnostics of some of the components without removing the controller room, line fuse, or placing the DIAG/RUN/SET switch to the “Diagnostic” position. Contactors and seat circuit will NOT be energized. E1 : Drive motor brush problem. E2 : Hydraulic motor brush problem. Ec : Control panel thermal problem. Ed : Drive motor thermal problem. EL : Battery lock out. EP : Pump motor thermal problem. F0 : Excessive drive motor current in pulsing or bypass operation. F2 : Left drive problem, voltage on left drive transistor emitter (wire #L64). F2 (Flashing) : Right drive problem, voltage on right drive transistor emitter (wire #R64). F3 : Pump problem, voltage on pump transistor emitter (wire #74). F4 : Both F2 and F3 problems together. F5 : Left drive problem, no voltage on left drive transistor emitter (wire #L64). F5 (Flashing) : Right drive problem, no voltage on right drive transistor emitter (wire #R64). F6 : Pump problem, no voltage on pump transistor emitter (wire #74). F7 : Both F5 and F6 problems together. FA : Steer angle problem. Fb : Battery mis-match. Fd : Pressure switch problem. MicroController Control Systems To enter quick diagnostics. Open the seat switch and place the clirection lever to forward and eusure that the park brake is released. While depressing the accelerator to maximum posistion other than OFF, and key switch to on. Display will go to a solid “A3” and the speed symbols will increase from 0 to 10 on the LCD, indicating that you have entered diagnostics and you are ready for Test: You can test the direction control lever, all hydraulic levers, the park brake switch and the accelerator. See Built-In Diagnostic Operation on page 49-51. NOTE : This test enables a salesman to demonstrate some of the diagnostic procedure without ever having to open up the controller room. 52 Testing And Adjusting Troubleshooting Problem List TROUBLESHOOTING PROBLEM LIST Problem # CENTRAL VEHICLE MONITORING SYSTEM (CVMS) PROBLEMS 1 CVMS does not work, with no lift truck operation. 2 CVMS does not work at all, lift truck operation normal. Display portion of CVMS seems random or wrong. 3 4 Lift truck operation normal. Display portion of CVMS works until seat switch is closed then blank, no lift truck drive or pump motor operation. “SELF” DIAGNOSTIC PROBLEMS 5 Display = “d”, no lift truck operation or “Self-diagnostics” operation. 6 Display = “F”, no lift truck operation. 7 Display = “8b”, no lift truck operation. 8 Seat switch circuit defect. 9 Direction switch circuit defect. 10 Lift switches circuit defect. 11 Tilt switch circuit defect. 12 Auxiliary switch circuit defect. 13 Park brake switch circuit defect. 14 Accelerator circuit defect. 15 Incorrect contactor operation. 16 Any contactor closes when key switch is activated. “RUN TIME” DIAGNOSTIC PROBLEMS 17 Display = “EE”, no lift truck drive operation. 18 Display = “EE” (Flashing), no lift truck drive operation. 19 Display = “E1”, or “E2” lift truck operation normal. 20 Overtemperature is ON and display = Lift truck accelerates slower than normal. Lifting speed is slower than normal. Overtemperature is ON and display = 21 Bypass contactor will not close. Pump and steering operation normal. Acceleration slow. Overtemperature is ON and display = 22 Lifting speed slow. Drive and power steering operation normal. 23 Display = “EL”. No hydraulic (lift and tilt). Steering normal. 24 Hourmeter does not work. 25 Normal hydraulic operations, display is normal and no drive operations. 26 Current limit adjustment cannot be made. 27 Slow steering, but pump motor does turn. Drive system operation normal. Pump motor runs continously when neutral is selected. Pump motor turns at high power steering 28 speed continuously. Drive motor does not operate or operates with low power or is erratic. 29 30 Pump and power steering systems operation normal. Horn does not function correctly. Lift and drive operation normal. Auxiliary lighting and/or alarm does not function correctly. 31 Lift and drive operation normal. MicroController Control Systems 53 Testing And Adjusting TROUBLESHOOTING PROBLEM LIST Problem # FAILURE CODE PROBLEMS 32 Display = “F0”, no lift truck operation. 33 Display = “F2”, no lift truck operation. 34 Display = “F2” (Flashing), no lift truck operation. 35 Display = “F3”, no lift truck operation. 36 Display = “F4”, no lift truck operation. 37 Display = “F5”, no lift truck operation. 38 Display = “F5” (Flashing), no lift truck operation. 39 Display = “F6”, no lift truck operation. 40 Display = “F7”, no lift truck operation. 41 Display = “FA”, no lift truck operation. 42 Display = “Fb”, no lift truck operation. 43 Display = “Fd”, lift truck operation normal. MicroController Control Systems 54 Testing And Adjusting PROBLEM 1 Central Vehicle Monitoring System (CVMS) does not work, with no lift truck operation. POSSIBLE CAUSE Battery polarity not correct on control panel; Key fuse open circuit; Key switch defect; Logics defect. CHECKS With battery connected, check control panel battery connections for correct polarity. Positive battery connected to line contactor and negative battery connected to negative heatsink. If correct If not correct Push horn buttton to close horn switch. Make correction to cables. Horn work Horn does not work Does CVMS pass self test at actuation of key and seat switches. Yes Disconnnect battery and check the horn fuse for continuity. NO Continuity See Problem 2, CVMS does not work, lift truck operation normal. Check for shorts and replace fuse. Check continuity from horn fuse holder to control panel battery positive connection at the line contactor. Also check continuity from key fuse holder to wire #3 on key switch Close key switch. Measure voltage on P1-1 and P1-2. Battery voltage No continuity Less than Battery voltage Continuity Replace key switch or repair broken wire #5 between key switch and P1-1 and P1-2. Repair horn circuit. No continuity Repair or replace open wire. Check continuity from negative heatsink to logics P1-19 and P1-20. Continuity Replace logics. No continuity Repair or replace open wire. MicroController Control Systems 55 Troubleshooting PROBLEM 2 CVMS does not work at all, lift truck operation normal. If only part of CVMS works, replace the CVMS. POSSIBLE CAUSE Disconnected logic connector P8; Open circuit from P8-1 to CVMS connector PIN 1; Open circuit from P8-8 to CVMS connector PIN 8; CVMS defect. CHECKS Make sure CVMS connector is connected to CVMS. If connected If not connected Connect multimeter positive lead to P8-1 wire #101 and negative lead to P8-8 wire #108. Measure the voltage. 5 volts Replace the CVMS module. MicroController Control Systems Connect CVMS connector. 0 volt Repair or replace open circuit between 8 wires from logics to CVMS. 56 Troubleshooting PROBLEM 3 Display portion of the CVMS module seems random or wrong. Lift truck operation normal. POSSIBLE CAUSE Connection defect; Wiring defect; Logics defect; Display defect. CHECKS Check continuity from logics to CVMS connector (wire #101/WH/YL/GN/BU/BK/RD/108). Continuity No Continuity Check for shorts to battery negative from PIN 2 to PIN 7 on CVMS connector. No shorts found Repair or replace open wire. Shorted Replace logics. MicroController Control Systems Repair or replace shorted wire. 57 Troubleshooting PROBLEM 4 Display portion of CVMS works until seat switch is closed then blank, no lift truck drive or pump motor operation. POSSIBLE CAUSE Line contactor defect; Line fuse open circuit; Wire #4 at P9-9 open circuit; Logics defect. CHECKS Does the line contactor close and remain closed ? Yes No Check voltage at bottom of line fuse with line contactor activated. Battery voltage See Problem 15. Incorrect contactor operation. Less than Battery voltage Check voltage at top of line fuse with line contactor activated. Battery voltage Repair or replace line contactor tips or power connections. Less than Battery voltage Check voltage at logic connector P9-9, wire #4 with line contactor activated. Battery voltage Check for possible shorts in the power circuit (Head Capacitor, diode, shorted cables) and replace line fuse. If repeat failures occur, check drive motor current limit and/or lift truck application. Less than Battery voltage Replace logics. MicroController Control Systems Repair open circuit between line fuse and P9-9, wire #4. 58 Troubleshooting PROBLEM 5 Display = “d”, no lift truck or “Self-diagnostics” operation. POSSIBLE CAUSE Logic DIAG/RUN/SETUP switch in DIAG position with line fuse installed; Head capacitor not discharged below 5 volts; Logics defect. CHECKS Trying to run “Self-Diagnostics” ? Trying to operate lift truck ? Disconnect battery, discharge head capacitor below 5 volts, remove line fuse, set DIAG/RUN/SETUP switch to DIAG position, reconnect the battery and recycle key switch. Display remains at “d” Measure voltage on P9-9. Disconnect battery, remove logic cover, set DIAG/RUN/SETUP switch to RUN position, reconnect the battery and recycle key switch. “Self-diagnostic” Operation OK Display remains at “d” Continue with “SelfDiagnostics” operation. Replace logics. Lift Truck Operation OK Place lift truck into operation. Below 5V. Replace logics. MicroController Control Systems 59 Troubleshooting PROBLEM 6 Display = “F”, no lift truck operation. POSSIBLE CAUSE Wiring defect; Logics defect. CHECKS With the key on, check the voltage at logic P1-1 and P1-2, wire #5. Battery voltage No voltage Check continuity from control panel battery negative to logic P1-19 and P1-20. Continuity Replace logics. Repair or replace open wire. No continuity Repair or replace open wire. MicroController Control Systems 60 Troubleshooting PROBLEM 7 Display = “8b”, no lift truck operation. POSSIBLE CAUSE Wiring defect; Direction switch defect; Logics defect. CHECKS Does the DlAG/RUN/SETUP switch in “Diagnostic” position ? NO YES Does the direction switch in neutral ? YES NO Check continuity from logic P2-6 to battery negative. No continuity Replace logics. Move switch to “Run” position. Move switch to neutral. Continuity Repair or replace short wire or direction switch. MicroController Control Systems 61 Troubleshooting PROBLEM 8 Seat switch circuit defect. POSSIBLE CAUSE Seat switch defect; Wiring to seat defect; Logics defect. CHECKS Disconnect the battery and remove logic cover. Disconnect P2 connector. Check continuity from P2-7 harness connector to negative heatsink with multimeter in diode test position. Should be closed circuit when seat is pressed on and open circuit when seat is released. No continuity Constant continuity Disconnect seat switch connector. Push on the seat and check the continuity across the seat switch. Continuity No continuity Replace seat switch. Check OK Replace logics. Disconnect seat switch connector. Check continuity from logic harness connector P2-7 to control panel battery negative with multimeter in diode test position. Continuity No continuity Check continuity from terminal #1 of seat switch to control panel battery negative. Replace seat switch. Continuity No continuity Repair or replace open wire Check wiring for short circuits between harness connector P2-7 and control panel battery negative. Repair any short circuit found. Check continuity from terminal #2 of seat switch to logic harness connector P2-7 with multimeter in diode test position. Repair or replace open wire. MicroController Control Systems 62 Troubleshooting PROBLEM 9 Direction switch circuit defect. POSSIBLE CAUSE Direction switch defect; Wiring to direction switch defect; Logics defect. CHECKS Release park brake. Disconnect the battery and remove logic cover. Disconnect P2 connector. Disconnect service brake switch connector. Check continuity from control panel battery negative to P2-5 logic connector; With direction lever in forward should have a closed circuit, in neutral should be open. Check OK Check failed Check continuity from control panel battery negative to logic connector P2-6. With direction lever in reverse should have a closed circuit, in neutral should be open. Check OK Disconnect direction switch connector. Check continuity of wire #27. Continuity Check failed Repair or replace wire. Replace logics. Check continuity from terminal #2 of direction switch harness connector to control panel battery negative. Disconnect direction switch connector. Check continuity of wire #28. Continuity No continuity Continuity No continuity No continuity Replace direction switch. Repair or replace wire. Repair or replace open wire. Check continuity from terminal #2 of direction switch harness connector to control panel battery negative. Continuity No continuity Replace direction switch. MicroController Control Systems Repair or replace open wire. 63 Troubleshooting PROBLEM 10 Lift sensor circuit defect. POSSIBLE CAUSE Lift sensor not adjusted properly or defective; Lift sensor wiring defect; Valve control card (board) defect; Logics defect. CHECKS Disconnect the tilt and auxiliary switch connectors. Retest lift sensor circuit in self diagnostics. Circuit passes “Self-Diagnostics” Perform Problem 11,12 Tilt or auxiliary circuit defect. Circuit fails “Self-Diagnostics” Disconnect PV connector at the valve control board. Connect multimeter negative lead to PV-5 and the positive lead to PV-2. Measure the voltage. Battery Voltage Measure each voltage from : PV-1, PV-3 to battery negative PV-5. All = 11.5 to 12.5 Any/All = 0V 0 Volt Repair or replace broken wire between key switch and PV-2 (wire #5) or between PV-5 and battery negative(-). Reconnect PV and adjust the lift sensor and valve control card to specifications. Measure each voltage from P2-3, P2-4 to battery negaive. Display does not change 0 to 3 All = 11.5 to 12.5 Display changes 0 to 3 Repair or replace broken wire between P2 logic connector and PV connector. Perform “Self-Diagnostics”. Lift circuit should work. Measure each voltage from P2-3, P2-4 to battery negative as the lever is pulled. 11.5 to 12.5 and .2v Measured on each Replace logics. Any one or all 0V Remove P2 logic connector. Check P2-3, P2-4 for shorts to negative. 11.5 to 12.5 and .2V NOT measured on each If shorted Replace valve Control Card. Replace or replace wire. No shorts Replace logics. NOTE : Before lift truck is placed into service, connect tilt and auxliary switches and verify proper adjustment. MicroController Control Systems 64 Troubleshooting PROBLEM 11 Tilt switch circuit defect. POSSIBLE CAUSE Tilt switch defect; Wiring defect; Logics defect. CHECKS Disconnect the battery and remove logic cover. Disconnect P2 connector. Pull tilt lever to maximum. Check continuity from P2-2 logic connector to control panel negative. Continuity No continuity Replace logics. Check continuity of wire #49. Continuity Check continuity from tilt switch terminal of wire #1 to control panel negative. Continuity Replace tilt switch. MicroController Control Systems No continuity Repair or replace wire. No continuity Repair or replace wire. 65 Troubleshooting PROBLEM 12 Auxiliary switch circuit defect. POSSIBLE CAUSE Wiring defect; Auxiliary switch defect; Logics defect. CHECKS Disconnect the battery and remove logic cover. Disconnect P2 connector. Pull auxiliary lever to maximum. Check continuity from P2-16 logic connector to control panel negative. Continuity No continuity Replace logics. Check continuity of wire #46. Continuity Check continuity from Aux. switch terminal of wire #1 to control panel negative. Continuity Replace Aux. switch. MicroController Control Systems No continuity Repair or replace wire. No continuity Repair or replace wire. 66 Troubleshooting PROBLEM 13 Park brake switch circuit defect. POSSIBLE CAUSE Park brake switch defect; Wiring defect; Logics defect. CHECKS Disconnect the battery. Check continuity from wire #71 to #1 on the park brake switch; With park brake released should have a closed circuit; With park brake applied should have an open circuit. Check park brake switch to make sure it is activated by the park lever. Check OK Check failed Check continuity from wire #1 on the park brake to control panel battery negative. Continuity Replace park brake switch. No continuity Check continuity from wire #71 on the park brake switch to logic P2-8 Continuity Repair or replace wire. No continuity Replace logics. MicroController Control Systems Repair or replace wire. 67 Troubleshooting PROBLEM 14 Accelerator circuit defect. POSSIBLE CAUSE Wiring defect; Accelerator defect; Logics defect. CHECKS With the key switch on, the seat switch closed, park brake released and connect multimeter positive lead to P1-16, negative lead to P1-20. Measure the voltage. 12 volts Other voltage Connect multimeter positive lead to P1-15, negative lead to P1-20. Measure the voltage accelerator pedal released : 0 volt. Press accelerator pedal to max. : 9.6 to 11 volts. Check OK Replace logics. Check failed Disconnect P1 logic connector. Check continuity of wire #18. Continuity Replace accelerator. No continuity Check continuity from terminal #1 of accelerator harness connector to logic harness connector P1-16. Continuity No continuity Check continuity from terminal #3 of accelerator harness connector to logic harness connector P1-20. Continuity Replace logics. Repair or replace wire. Repair or replace wire. No continuity Repair or replace wire. MicroController Control Systems 68 Troubleshooting PROBLEM 15 Incorrect contactor operation. POSSIBLE CAUSE Wiring defect; Contactor defect; Logics defect. CHECKS During the “Self-Diagnostic” test, which of the following occurs? Contactor does not activate or does not remain activated. A contactor activates whenever the key switch is closed through all tests. Disconnect the battery. Check for free mechanical movement of contactor tips Movement OK See Problem 16. “Any contactor closes when key switch is closed”. Movement not free Remove logic cover. Disconnect P1. Check continuity from P1-3 (wire #15) to terminal of the contactor with incorrect operation. Continuity No continuity Measure continuity from the appropriate P1 socket to the coil terminal of the contactor that has incorrect operation. Determine the P1 socket with respect to the contactor that has incorrect operation as follows: Line ....................................................P1-4, wire #33 Forward direction left .........................P1-5, wire #L34 Reverse direction left .........................P1-6, wire #L35 Forward direction right .......................P1-7, wire #R34 Reverse direction right .......................P1-8, wire #R35 Bypass ..............................................P1-9, wire #36 Continuity Repair or replace wire. No continuity Check the contactor coil resistance. See Component Measurements in Specifications section. Check OK Replace contactor. Repair or replace wire. Check not OK Connect P1 and run “Self-Diagnostics” again. If contactor does not close, replace logics. MicroController Control Systems Replace contactor. 69 Troubleshooting PROBLEM 16 Any contactor closes when key switch is activated. POSSIBLE CAUSE Wiring defect; Logics defect. CHECKS Connect the battery. Does the line contactor close when the key switch is closed ? Yes No Did the seat switch pass “Self-Diagnostics”? No Yes See Problem 8 Seat Switch Circuit Defect. With contactor closed ? Disconnect the battery. Remove logic cover and disconnect logic P1 connector. Check for a short circuit from control panel battery negative to P1 harness connector socket. Determine the P1 socket with respect to the contactor that closed as follows: Line................................................................P1-4 Forward direction left.....................................P1-5 Reverse direction left ....................................P1-6 Forward direction right ..................................P1-7 Reverse direction right ..................................P1-8 Bypass...........................................................P1-9 Short circuit Repair or replace shorted wire. MicroController Control Systems 70 Open circuit Replace logics. Troubleshooting PROBLEM 17 Display = “EE”, no lift truck drive operation. POSSIBLE CAUSE Static Return to Off (SRO) circuit activated by improper operation sequence; Direction switch defect; Accelerator linkage not fully released; Accelerator control defect; Logics defect. CHECKS Check for SRO by release of accelerator, release park brake, move the direction lever to neutral, reselect direction and press the accelerator. No change Run “Self-Diagnostics” to find faulty circuit or component. Lift Truck Operation OK Inform operator of correct start–up procedure. Also, that the direction lever must be left in neutral when leaving the truck. If no faulty component is found, replace logics. MicroController Control Systems 71 Troubleshooting PROBLEM 18 Display = “EE” (Flashing), no lift truck drive operation. POSSIBLE CAUSE No opterator in seat; Seat switch defect; Open wiring; Logics defect. CHECKS See Problem 8, seat switch circuit defect. MicroController Control Systems 72 Troubleshooting PROBLEM 19 Display = “E1”, or “E2” lift truck operation normal. POSSIBLE CAUSE Worn brushes; Short wiring; Display defect. CHECKS If “E1” displays, drive motor brush wear. If “E2” displays, hydraulic motor brush wear. Disconnect the respective wire from the motor. Wire #31 for drive motor or wire #72 for pump motor. Connect the battery and close the key switch and seat switch. Does the LCD go out ? No Yes Disconnect the battery. Check continuity of the respective wires to the logics. Continuity Check the brushes and replace as necessary. No continuity Replace or repair wires. Disconnect logic P2 and check for shorts from logic P2-14 and P2-15 to battery negative. Shorted Repair wires. MicroController Control Systems Opened Replace logics. 73 Troubleshooting PROBLEM 20 Overtemperature is ON and Display = . Lift truck accelerates slower than normal. Lifting speed is slower than normal. Power steering operation normal. POSSIBLE CAUSE Control panel overheated; Control thermostat (thermal switch) defect; Open wiring; Display defect; Logics defect. CHECKS Let the truck cool for 15 minutes. Overtemperature indicator ON Disconnect the battery. With the controller at close to room temperature, disconnect the control thermal switch connectors P10. Check continuity of thermal switches. Should have continuity below 69°C (156°F) Continuity Control panel was overheated, resume normal operation. If repeats occur, check drive and pump motors current draw or operating cycle for excessive ramp climbing, towing or excessive lifting. No continuity Replace thermal switch. Check continuity of wire #69 between themostat connector P10 and thermal SW Continuity No continuity Check continuity of wire #1 at thermostat to negative heatsink (control panel negative). Continuity Repair or replace wire. No continuity Remove logic cover. Check continuity of wire #69 at P10-7 to logic P2-11. Continuity Replace logics. Normal display Repair or replace wire. No continuity Repair or replace wire. MicroController Control Systems 74 Troubleshooting PROBLEM 21 Overtemperature is ON and Display = . Bypass contactor will not close. Pump and power steering operation normal. Acceleration slow. POSSIBLE CAUSE Drive motor overheated; Drive motor thermostat (thermal switch) defect; Open wiring; Display defect; Logics defect. CHECKS Let the truck cool for 15 minutes. Overtemperature indicator ON Disconnect the battery. With the drive motor at close to room temperature, disconnect the drive motor thermal switch connector. Check continuity of thermal switch. Should have continuity below 123°C (253°F) Continuity Drive motor was overheated, resume normal operation. If repeats occur, check drive motors current draw or operating cycle for excessive ramp climbing or towing. No continuity Replace thermal switch. Check continuity of wire #43 between left and right drive motor thermal switch. Continuity No continuity Check continuity of wire #1 at left drive motor thermal switch to negative heatsink. Continuity Repair or replace wire. No continuity Remove logic cover. Check continuity of wire #43 at right drive motor thermal switch to logic P2-12. Continuity Replace logics. Normal display Repair or replace wire. No continuity Repair or replace wire. MicroController Control Systems 75 Troubleshooting PROBLEM 22 Overtemperature is ON and Display = . Lifting performance slow. Drive and power steering operation normal. POSSIBLE CAUSE Pump motor overheated; Pump motor thermostat (thermal switch) defect; Open wiring; Display defect; Logics defect. CHECKS Let the truck cool for 15 minutes. Overtemperature indicator ON Disconnect the battery. With the pump motor at close to room temperature, disconnect the pump motor thermal switch connector. Check continuity of thermal switch. Should have continuity below 123°C (253°F). Continuity Pump motor was overheated, resume normal operation. If repeats occur, check pump motor current draw or operating cycle for excessive lifting and tilting. No continuity Repair or replace switch. Check continuity of wire #1 at pump motor thermal switch to negative heatsink. Continuity No continuity Remove logic cover. Check continuity of wire #42 at pump motor thermal switch connector to logic P2-13. Continuity Replace logics. Normal display Repair or replace wire. No continuity Repair or replace wire. MicroController Control Systems 76 Troubleshooting PROBLEM 23 Display = “EL”. No hydraulic (lift and tilt). Steering normal. Battery discharge indicator (BDI) circuit defect. POSSIBLE CAUSE Battery discharged or has a defect; Logics defect. CHECKS Connect battery, turn on key switch, close seat switch and measure voltage from line contactor to negative heatsink. Voltage must be greater than 45 volts. Voltage OK Voltage low With key ON, seat switch and line contactor closed, measure voltage at P9-9. Battery voltage Check battery connections; Charge or replace battery. Less than battery Replace logics. MicroController Control Systems Repair shorted wire or high resistance connection causing the improper voltage. 77 Troubleshooting PROBLEM 24 Hourmeter does not work. POSSIBLE CAUSE The hourmeter requires battery voltage to run. Measure voltage at hourmeter to ensure that it is battery voltage. No voltage Battery voltage Check continuity from key switch to hourmeter positive (+) terminal. Continuity Replace hourmeter. No continuity Check continuity from hourmeter negative (-) to seat switch wire #45. Continuity Repair or replace wire. No continuity Repair or replace wire. Check continuity from seat switch to battery negative wire #1. No continuity Repair or replace wire. MicroController Control Systems 78 Troubleshooting PROBLEM 25 Normal hydraulic operations, display is normal and no drive operations. POSSIBLE CAUSE Service brake switch shorted. Short wires (#27, #28). Charged head capacitor. CHECKS Disconnect the battery connector and discharge the head capacitor fully. Check continuity from wire #27 (logic P2-5) to wire #28 (logic P2-6). Continuity No continuity Check service brake switch and wires #27, #28 from logics to service brake switch. Check direction switch. All checks OK Replace logics. Any checks failed Replace logics. MicroController Control Systems Repair or replace wire or switches. 79 Troubleshooting PROBLEM 26 Current limit adjustment cannot be made. POSSIBLE CAUSE Current sensor defect; Wiring defect; Logics defect. CHECKS Perform current sensor component check. Check OK Check failed Replace logics. MicroController Control Systems Repair wiring or replace current sensor. 80 Troubleshooting PROBLEM 27 Slow steering, but pump motor does turn. Drive system operation normal. POSSIBLE CAUSE Steering pressure switch defect; Wiring defect; Logics defect. CHECKS Check the battery, close the seat and key switches. Put the direction lever in forward. Disconnect pressure switch connector. Pump motor speed remains the same Pump motor speed increases Replace the pressure switch. Disconnect pressure switch connector. Check for a continuity between P2-1 and battery negative. No continuity Replace logics. Continuity Repair the wiring. MicroController Control Systems 81 Troubleshooting PROBLEM 28 Pump motor runs continuously when neutral is selected (no wait mode). Pump motor turns at high power steering speed continuously. POSSIBLE CAUSE Steering pressure switch defect; Pressure switch connector disconnected; Wiring defect; Logics defect. CHECKS Check steering pressure switch connector for proper connection. Connected Disconnected Disconnect the pressure switch connector. Place jumper wire between both pressure switch connector terminals. With the key ON, seat switch closed and a direction selected, the pump motor should run at slow speed. Remains at high speed Runs at slow speed Disconnect the battery and discharge the head capacitor. Check continuity from terminal #1 of pressure switch connector to the control panel negative. Also check continuity from terminal #2 of pressure switch connector to logic connector P2-1. Continuity Replace logics. Connect connector. Replace the pressure switch. No continuity Repair or replace open wire. MicroController Control Systems 82 Troubleshooting PROBLEM 29 Drive motor does not operate or operates with low power or is erratic. Pump and power steering systems operation normal. POSSIBLE CAUSE Accelerator defect; Direction control circuit defect ; Current limit set too low; Wiring defect ; Logics defect. CHECKS Perform self-diagnostics. Passed Does not pass See respective problem for defective circuit. Readjust current limit to specifications. Check DR1 and DR2 for correct resistance. Resistance is 90Ω L 5%. In specification Not in specification Check wire #L67, #L68, #R67 and #R68 for a good connection on DR1 and DR2. Check wires #L63 and #R63 to base of transistors DTR1 and DTR2. Check continuity of wire #L64 and #R64 from emitter of power transistors to logics P9-5 and P9-6. All OK Defective wiring Repair or replace defective wiring or connection. Check diode DD1, DD2, DD3 and DD4 for shorts or open circuit. Diode OK Defective diode Check drive motor, cables and contactor for open circuits. Check OK Replace logics. Replace resistor. Replace defective diode. Open circuit Repair open circuit or replace drive motor. MicroController Control Systems 83 Troubleshooting PROBLEM 30 Horn does not function correctly. Lift and drive operation normal. POSSIBLE CAUSE Open fuse; Faulty wiring; Defective switch; Horn defect. CHECKS With the faulty horn circuit activated, check for voltage on the load side of the horn fuse. Battery voltage No voltage Check for voltage on the load side of the horn switch. Battery voltage Check for short circuits; Replace horn fuse. 0 volt Repair or replace open wire from fuse or replace defective switch. Check for voltage at the negative connection of the load. 0 volt Battery voltage Repair or replace open wire from the horn switch or replace horn. MicroController Control Systems Repair or replace open wire going to battery negative. 84 Troubleshooting PROBLEM 31 Auxiliary lighting and/or alarm does not function correctly. Lift and drive operation normal. POSSIBLE CAUSE Open fuse; Faulty wiring; Defective switch; Shorted load; Open load; Loss of input voltage to DC-DC converter; Defective DC-DC converter. CHECKS Connect the battery and close the key switch. Measure from the DC-DC converter 12V positive terminal to the 12V negative terminal. No voltage output Voltage above 13V Con’d Next Page Voltage below 11V Con’d Next Page Con’d Next Page Voltage 11 to 13V With the faulty auxiliary circuit activated, check for voltage on load side of the auxiliary fuse. 11 to 13 volts Check for voltage on the load side of the auxiliary switch. 11 to 13 volts Check for short circuits; Replace auxiliary fuse. 0 volt Check for voltage at the negative connection of the load. 0 volt No voltage Repair or replace open wire from fuse or replace detective switch. 11 to 13 volts Repair or replace open wire from the auxiliary switch or replace the defective auxiliary component. Repair or replace open wire going to battery negative. MicroController Control Systems 85 Troubleshooting Problem 31 (continued) No voltage output. Measure the voltage from (POS INPUT) to (NEG INPUT). Battery voltage 0 volt Measure the voltage from (12V POS) terminal of the DC-DC converter to battery negative. Battery voltage Measure the voltage from the battery positive cable at the line contactor to the (NEG INPUT) terminal of the DC-DC converter. 0 volt Battery voltage Measure the voltage from (ENABLE) terminal of the DC-DC converter to battery negative. Battery voltage Replace the DC-DC converter. 0 volt Check for open fuse or wiring between the line contactor and the (POS INPUT) terminal of the DC-DC converter. 0 volt Repair open negative connection from converter (NEG INPUT) to battery negative. Open fuse Open wiring Repair or replace open wiring from the key sw to the (ENABLE) terminal of the DC-DC converter. Replace fuse and check wiring for shorts. If no shorts are found and the fuse continues to fail, replace the DC-DC converter. Repair or replace faulty wiring. Test the fuse at the DC-DC converter for continuity. Fuse good Fuse open Remove the load connections at the (12V POS) and (12V NEG) terminals of the DC-DC converter. Measure the voltage from the (12V POS) to the (12V NEG) terminals of the DC-DC converter. 11 to 13 volts <11 or >13 volts Replace the DC-DC converter. Check for a short circuit in each auxiary circuit. No shorts found Replace the DC-DC converter. MicroController Control Systems Replace fuse. If fuse continues to fail, replace the DC-DC converter. Shorts found Repair or replace faulty wiring or components. 86 Troubleshooting Problem 31 (continued) Voltage bellow 11 volts. Measure the voltage from (POS INPUT) or (+IN) terminal to the (NEG INPUT) or (-IN) terminal of the DC-DC converter. 36 volts or above Below 35 volts Remove all connections at the (12V POS) and(12V NEG) or the (+OUT) and (-OUT) terminals of the DC-DC converter. Measure the voltage from (12V POS) to (12V NEG) or (+OUT) to (-OUT). 11 to 13 volts Check the battery and DC-DC converter input connections from the battery. Battery low Poor connection Below 11 volts Charge or replace battery. Repair or replace faulty wiring or connections. Check for a short or low resistance in the auxiliary circuits and loads. NOTE : Excessive loading places the converter into current limit (12A maximum). DC-DC converter faulty. Replace converter. Voltage above 13 volts. Remove all connections at the (12V POS) and (12V NEG) or the (+OUT) and (-OUT) terminals of the DC-DC converter. Measure the voltage from (12V POS) to (12V NEG) or (+OUT) to (-OUT). 11 to 13 volts Above 13 volts Check the output load circuits for incorrect wiring or shorts to battery negative. MicroController Control Systems DC-DC converter faulty. Replace converter. 87 Troubleshooting PROBLEM 32 Display = “F0”, no lift truck operation. POSSIBLE CAUSE Logic potentiometers VR1 and VR6 out of adjustment. Excessive drive motor currents due to pushing or ramp application. Failed drive motor. Failed logics. Weak or discharged battery. CHECKS Adjust current limit to specification : 48 V - 270 amps OK Still “F0” Place lift truck into operation. Determine when the “F0” occurs. Before bypass During bypass Is there a steep ramp that the truck must stop on ? If so the Excessive Drive Motor Current option may not be applicable in this application. Set option Programmable Feature 9 to Data Codes 3. Determine if there is a steep ramp in the application. Adjust VR6 so that current is greater than maximum drive motor current going up the ramp. No ramp, or continues “F0” No ramp, or continues “F0” Does the “F0” occur due to excessive pushing or abuse. Ensure that the battery is not being deep discharged, causing high currents. Inspect the battery for poor maintenance or bad cells. Explain situation to the customer. If abuse continues, any drive failure will not be warranted. Discussion : The logic card monitors the current in the drive motors, and prevents high currents that may damage the drive motor, or possibly blow the line fuse. It uses two current limits settings for this purpose. Potentiomenter VR1 sets current limit for transistor pulsing, and if drive motor current exceeds the VR1 current setting for longer than 3 seconds, it will failsafe and display an “F0”. Similary, if the bypass contactor is closed, and the current exceeds the potentiometer VR6 setting for longer than 3 seconds, the truck will failsafe in a similar manner. In addition, the bypass operation will be prevented if the drive motor currents exceed the VR1 current limit. MicroController Control Systems 88 Troubleshooting PROBLEM 33 Display = “F2”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Shorted DTR1; Welded bypass contactor tips ; Open wiring; Driver board defect; Logics defect; Frame voltage on LS1 drive motor cable. CHECKS Disconnect the battery, check bypass contactor for welded tips. Check contactor for free tip movement. Not welded Welded Disconnect battery, remove logic cover, check continuity and connections of wire #L64 at DTR1 emitter to P9-5 on logics. Continuity No continuity Disconnect LS1 cable at panel and retry. Still “F2” Repair or replace contactor tips. Check BDI adjustment and battery Check current limit adjustment. Repair or replace wiring or connection. OK Investigate voltage present on LS1 cable. Check DTR1 for failure Test OK Test driver board (drive side only). Test OK Failed Replace transistor. Failed Replace logics. MicroController Control Systems Replace driver board. 89 Troubleshooting PROBLEM 34 Display = “F2” (Flashing), no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Shorted DTR2; Welded bypass contactor tips ; Open wiring; Driver board defect; Logics defect; Frame voltage on RS1 drive motor cable. CHECKS Disconnect the battery, check bypass contactor for welded tips. Check contactor for free tip movement. Not welded Welded Disconnect battery, remove logic cover, check continuity and connections of wire #R64 at DTR2 emitter to P9-6 on logics. Continuity Repair or replace contactor tips. Check BDI adjustment and battery. Check current limit adjustment. No continuity Disconnect RS1 cable at panel and retry. Still “F2” (Flashing) Repair or replace wiring or connection. OK Investigate voltage present on RS1 cable. Check DTR2 for failure Test OK Test driver board (drive side only). Test OK failed Replace transistor. Failed Replace logics. MicroController Control Systems Replace driver board. 90 Troubleshooting PROBLEM 35 Display = “F3”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Shorted PTR1; Open wiring; Driver board. defect; Open circuit pump motor or P1, P2 cables ; Logics defect. CHECKS Connect the battery, close the seat and key switches. Line contactor closes then opens, pump motor does not turn. Display = “F3” Line contactor closes then opens, pump motor turns a small amount. Display = “F3” Disconnect battery, remove logic cover, check continuity of wire #74 at emitter connector of PTR1 to P9-7 on logics. No continuity Check PTR1 for a short circuit. Not failed Failed Continuity Replace transistor. Repair or replace wiring Check continuity from P1 to P2 at panel. Continuity Replace logics. Check driver board (Pump side only). Not failed Failed No continuity Check motor and cables and repair. * Replace logics. Replace driver board (Pump side only) * * See Notice NOTICE Damage to the control panel could result. To prevent further damage, before PTR1 or driver board are replaced, complete the following checks: 1. 2. 3. 4. 5. Check Check Check Check Check the diode PD for a failure. Head capacitor for a failure. PTR1 for a failure. Driver board for a failure. for continuity from PTR1 emitter (wire #74) to logics P9-7. MicroController Control Systems 91 Troubleshooting PROBLEM 36 Display = “F4”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Bypass contactor tips shorted; Shorted DTR1, DTR2 and PTR1. Poor connection at logic P9 connector ; Driver board defect. CHECKS See Problems 33, 34 and 35, Display = “F2” or “F2” (Flashing) and “F3”. Do both procedures. MicroController Control Systems 92 Troubleshooting PROBLEM 37 Display = “F5”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Faulty wire connections; DTR1 failed; Current limit set to low; Failed DD1 or DD2; Failed driver board; Failed current sensor; Failed logics. CHECKS Disconnect the following wires, visually inspect them for burnt or discolored terminals; Loose connections; Smashed or compressed connectors; Corrosion or foreign material. Wire #L65 at P9-1. Wire #L64 at P9-5 and emitter bus bar of left drive power transistors. Wire #L67 and #L68 at resistor DR1. Wires #L63 at DTR1. Wire #4 from driver board to positive heatsink. Wire #1 from driver board to negative heatsink. Wire #L22 from logics P1-12 to current sensor. Wire #25 from logics P1-16 to current sensor. Current sensor PIN3 to negative heatsink. Repair any defects then reconnect the wires. Display = “F5” Display normal Test DTR1 for a failure. Not failed Return truck to operation. Failed Replace transistor. Make sure that the connecter of current sensor is connected. Measure the voltage at P1-12 with the key switch closed. If the voltage is over than 10V, replace the current sensor. * Test diodes DD1 and DD2 for a failure. Not failed Failed Measure voltage at P1-16 with the key switch closed. Voltage = 11 to 12V Any other voltage Perform Rapid Turn-Up procedure for current limit (VR1). Display “F5” Replace logics. Replace logics. * * Display normal Test driver board (drive) for a failure. Not failed Replace failed components. Recalibrate current limit to specifications. Recalibrate current limit adjustments to specifications. Failed Replace failed components. Recalibrate current limit to specifications. * * See Notice #1 MicroController Control Systems 93 Troubleshooting PROBLEM 38 Display = “F5” (Flashing), no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Faulty wire connections; DTR2 failed; Current limit set to low; Failed DD3 or DD4; Failed driver board; Failed current sensor; Failed logics. CHECKS Disconnect the following wires, visually inspect them for burnt or discolored terminals; Loose connections; Smashed or compressed connectors; Corrosion or foreign material. Wire #R65 at P9-2. Wire #R64 at P9-6 and emitter bus bar of right drive power transistors. Wire #R67 and #R68 at resistor DR2. Wires #R63 at DTR2. Wire #4 from driver board to positive heatsink. Wire #1 from driver board to negative heatsink. Wire #R22 from logics P1-13 to current sensor. Wire #25 from logics P1-16 to current sensor. Current sensor PIN3 to negative heatsink. Repair any defects then reconnect the wires. Display = “F5” (Flashing) Display normal Test DTR2 for a failure. Not failed Return truck to operation. Failed Replace transistor. Make sure that the connecter of current sensor is connected. Measure the voltage at P1-13 with the key switch closed. If the voltage is over than 10V, replace the current sensor. * Test diodes DD3 and DD4 for a failure. Not failed Failed Measure voltage at P1-16 with the key switch closed. Voltage = 11 to 12V Any other voltage Perform Rapid Turn-Up Procedure for current limit (VR1). Display “F5” (Flashing) Replace logics. Replace logics. * * Display normal Test driver board (drive) for a failure. Not failed Replace failed components. Recalibrate current limit to specifications. Recalibrate current limit adjustments to specifications. Failed Replace failed components. Recalibrate current limit to specifications. * * See Notice #2 MicroController Control Systems 94 Troubleshooting NOTICE #1 Damage to the control panel could result. To prevent further damage, before DTR1 or driver board are replaced, complete the following checks: 1. 2. 3. 4. 5. 6. Check Check Check Check Check Check the diode DD1 and DD2 for a failure. DTR1 for a failure. Driver board for a failure. Head capacitor for a failure. for continuity from DTR1 emitter (wire #L64) to logics P9-5. Current sensor for a failure. NOTICE #2 Damage to the control panel could result. To prevent further damage, before DTR2 or driver board are replaced, complete the following checks: 1. 2. 3. 4. 5. 6. Check Check Check Check Check Check the diode DD3 and DD4 for a failure. DTR2 for a failure. Driver board for a failure. Head capacitor for a failure. for continuity from DTR2 emitter (wire #R64) to logics P9-6. Current sensor for a failure. MicroController Control Systems 95 Troubleshooting PROBLEM 39 Display = “F6”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Failed Fuse - line Faulty wire connections; PD, PTR1 failed; Failed driver board ; Failed logics. CHECKS Check the continuity of Fuse - line. Disconnect the following wires, visually inspect them for burnt or discolored terminals, loose connections, smashed or compressed connectors, corrosion or foreign material. Wire #75 at P9-3. Wire #77 and #78 at resistor PR1. Wire from driver board to positive heatsink. Wire #1 from driver board to negative heatsink. Wire #73 at base of transistor PTR1. Repair any defects then reconnect the wires. Display = “F6” Display normal Check diode PD for a failure. Return truck to operation. Not failed Failed Check transistor PTR1 for a failure. OK * Replace transistor. * Replace driver board. * Failed Check driver board (Pump side only). Not failed Replace failed diode. Failed Replace logics. * See Notice NOTICE Damage to the control panel could result. To prevent further damage, before PTR1 or driver board are replaced, complete the following checks: 1. Check the diode PD for a failure. 3. Check PTR1 for a failure. 2. Check Head capacitor for a failure. 4. Check Driver board for a failure. 5. Check for continuity from PTR1 emitter (wire #74) to logics P9-7. MicroController Control Systems 96 Troubleshooting PROBLEM 40 Display = “F7”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Failure in both the drive and pump circuits. Incorrect wiring of wires #L67, #L68, #R67, #R68, #77 and #78. CHECKS See Problem 37, 38 and 39, Display = “F5” or “F5” (Flashing) and Display = “F6”. Do both procedures. MicroController Control Systems 97 Troubleshooting PROBLEM 41 Display = “FA”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Faulty wire connections; Failed steer angle switch; Failed logics. CHECKS Disconnect steer angle switch connector. Check continuity of wires #50, #51, #52 and #1 from logic P2-17 ~ 20 to steer angle switch connector. Continuity Not continuity Repair or replace wires. Check continuity wire #1 at steer angle switch connector to negative heatsink. Continuity No continuity Repair or replace wires. Put steer wheel in straight position. Key switch ON. Logic P2-17~20 should be low voltage. Low volt High volt Replace failed switches. Check steer angle switch operation by steer wheel position. (See steer angle control - page 23) Check OK Replace logics. MicroController Control Systems Failed Adjust steer angle switches. 98 Troubleshooting PROBLEM 42 Display = “Fb”, no lift truck operation, line contactor closes and opens. POSSIBLE CAUSE Battery defect; Logics defect. CHECKS Disconnect battery, measure voltage at battery connector terminal. Voltage must be higher than 40 volts and lower than 60 volts. Voltage OK Wrong voltage Check battery connections; Replace battery. With key on, seat switch and line contactor closed, measure voltage at logic P9–9. Battery voltage No battery voltage Replace logics. MicroController Control Systems Repair or replace wire. 99 Troubleshooting PROBLEM 43 Display = “Fd”, lift truck operation normal. POSSIBLE CAUSE Pressure switch defect; Wiring defect; Logics defect. CHECKS Disconnect the battery. Check continuity from wire #41 to #1 on the pressure switch. Continuity No continuity Check continuity from wire #1 on the pressure switch to control panel battery negative. Continuity No Continuity Check continuity from wire #41 on the pressure switch to logic P 2-1 Continuity Repair or replace wires. No Continuity Replace logics. MicroController Control Systems Repair or replace wires. Repair or replace wires. 100 Troubleshooting System Tests and Adjustments Potentiometer Adjustment Tool -Trimmer Test Equipment Available from most electronic suppliers, this insulated tool allows for fast and easy adjustments of potentiometers. Hydrometer Hydrometers are usually available from any battery supplier. Battery maintenance is a crucial part of maintaining the electric vehicle. The ability to measure specific gravity and adjust the battery discharge indicator to match battery manufacturers specifications is an important part in the total maintenance of the electric vehicle. Discharging Head Capacitor (HEAD CAP) There are various pieces of electric truck test equipment that Daewoo recommends for all service personnel. This equipment is available from a number of world wide manufacturers and local electronic suppliers. Contact your Daewoo dealer or the factory for further recommendations. WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. Handheld Multimeter A digital multimeter that measures DC voltage, resistance, and has a diode tester, is required. It is recommended that a high quality meter that is drop protected, or comes with a drop proof case, be purchased. Autoranging features, fast becoming an industry standard, are convenient for the service personnel, but are not required for servicing the lift truck. A variety of miniature test leads, alligator clips, and needle probes are also useful, and some of these usually come with the multimeter. Clamp-on Current Probe The electric lift truck testing and adjusting procedures require the measurement of average DC currents. Currents in excess of 600 amps may be present, so a clamp-on meter that will exceed this level is required. It is also highly recommeded that a device that has a voltage output, as well as a visible display, be used. This makes viewing and adjusting currents from the operator's seat possible. The jaws of the current probe should be able to accept at least a 19mm (.75 inch) cable diameter. 2 1 Discharging Head Capacitor (HEAD CAP) (1) Positive heatsink. (2) Negative heatsink. 1. Disconnect the battery and discharge the head capacitor. 2. Put a 82 ohm, 80 watt resistor Part No. 929315, in position between the positive (1) and negative (2) heatsinks. Hold the resistor in position for 10 seconds. This will discharge the capacitor below 5 volts. MicroController Control Systems 101 Testing And Adjusting Logics Removal 8 WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 7 Logics Removal (7) Nuts. (8) Logics. 1. Disconnect the battery and discharge the head capacitor. 5. Remove screws (7) which hold logics (8) to control panel. 6. Remove logics and replace logic cover to prevent damage. 2 “Run Time” Tests 1 WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. Component Location (1) Screws. (2) Logic Cover. 2. Loosen screws (1) that hold logic cover (2). 3. Remove the logic cover. WARNING 3 6 5 The lift truck can move suddenly. Battery voltage and high amperage are present. Injury to personnel or damage to the lift truck is possible. Safely lift both drive wheels off the floor. Put blocks of wood under the frame so the drive wheels are free to turn. During any test or operation check, keep away from drive wheels. 4 Key ON, No Operator Warning, Display =“EE” (Flashing) 1. Connect the battery. 2. Turn key to ON with no one on the seat. Connector Re4moval (3) Connector P1. (4) Connector P2. (5) Connector P8. (6) Connector P9. 3. The display should show the letter “EE” flashing on and off. 4. Disconnect connectors P1(3), P2 (4), P8 (5) and P9 (6). When disconnecting connectors pull on plastic connector housing, not on the wires. MicroController Control Systems 4. With an operator on the seat or by pressing on the seat the letter “EE” should stop flashing. 102 Testing And Adjusting Overtemperature Protection Static Return to Off (SRO), Display = “EE” 1. Connect the battery and sit on the seat. 2. Select a direction before turning key to ON. 3. Turn key to ON. An “EE” should appear on the display and the drive system should not operate. 4. Return the direction lever to neutral, then back to forward or reverse. The “EE” should disappear from the display and the drive system should operate. 5. Turn key to OFF. Depress and hold the accelerator pedal. To turn on overtemperature indicator. 6. Turn the key to ON. An “EE” should appear on the display and the drive system should not operate. 1. Disconnect the battery and discharge the head capacitor. 7. Release the accelerator padal. The “EE” should disappear from the display and the drive system should operate. 2. Disconnect the control panel thermal switch connector. 3. Connect the battery, close the seat switch and turn the key ON. The overtemperature indicator and “Ec” should be truned on. The drive and hydraulic speed will be reduced. “Ec” stored. Steps 1 through 3 can be repeated for the drive and pump motor thermal switches, the results should be: Drive – Drive pulse ratio reduced, bypass operation prevented, and “Ed” stored. Pump – Lifting performance reduced, and “EP” stored. MicroController Control Systems 103 Testing And Adjusting Logic Unit Quick Reference Voltage Check Component Tests The chart that follows is a quick reference of the expected voltages at the logic pin connectors. All voltage measurements are made with respect to battery negative. WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels. NOTICE Do not use steam or solvent to clean the controls. Damage can be caused to the control panel. Use pressure from an air hose with a maximum pressure of 205 kPa (30 psi) to clean the control panel when necessary. The air supply must be equipped with a water filter. 1. Put blocks of wood under the frame so both drive wheels are free to turn. 2. Disconnect the battery and discharge the head capacitor. NOTE: When control wires and power cables or bus bars are to be connected to the same bolt or stud, place all control wires together on the top of the bus bar or power cable. 3. Remove the logic cover. Use the electrical schematic referred to by name and number in the procedures that follow. All wires must be located as shown on the schematic. 5. Connect the multimeter negative lead to control panel battery negative. 4. Set the multimeter to the 200 volt DC range. 6. Use the multimeter positive lead with an Needle Tip to measure the voltages under normal and activated conditions as shown in the Logic Voltage Reference chart. Make sure the chart matches the control system being tested. 1 4 3 2 Connector Layout (1) Connector P1.(2) Connector P2. (3)Connector P8. (4) Connector P9. MicroController Control Systems 104 Testing And Adjusting LOGIC VOLTAGE CHECKS Normal Activated Voltage Voltage Logic Terminal P1-1 P1-2 Wire No. P1-3 15 P1-4 P1-5 P1-6 P1-7 P1-8 P1-9 P1-10 P1-11 P1-12 P1-13 P1-14 P1-15 33 L34 L35 R34 R35 36 L32 R32 L22 R22 18 Battery (+) from key switch Battery (+) to all CTR coils Line CTR coil Left-FWD coil Left-REV coil Right-FWD coil Right-REV coil Bypass CTR coil Left Plug sensor Right Plug sensor Left drive CT Right drive CT Not used Accelerator P1-16 25 12 Voltage (+) P1-17 P1-18 P1-19 P1-20 – – Not used Not used 1 Battery Negative P2-1 P2-2 P2-3 P2-4 P2-5 P2-6 P2-7 41 49 47 48 27 28 45 Pressure switch Tilt switch/AUX 1.Switch Lift 1 Switch Lift 2 Switch FWD switch REV switch Seat switch Low High High High High High High High Low Low Low Low Low Low P2-8 71 Park brake switch Low High P2-9 P2-10 20 24 High High Low Low P2-11 69 Low High P2-12 43 Low High P2-13 42 Low High P2-14 31 High Low P2-15 72 High Low P2-16 P2-17 P2-18 P2-19 P2-20 46 50 51 52 1 Height 1 switch Height 2 switch Control thermal switch Drive motor thermal switch Pump motor thermal switch Drive brush wear indicator sensor Pump brush wear indicator sensor AUX. switch ANGLE SWITCH 1 ANGLE SWITCH 2 ANGLE SWITCH 3 Battery Negative High High/Low High/Low High/Low Low Low High/Low High/Low High/Low Low 5 Function MicroController Control Systems B (+) B (+) B (+) B (+) B B B B B B (+) (+) (+) (+) (+) (+) 0 0 0 to 0.03 0 to 0.03 Low Low Low Low Low Low -0.8 to -0.2 -0.8 to -0.2 0.03 to 12 0.03 to 12 0 to 0.89 0.9 to 12 11 to 13 11 to 13 0 0 105 Test Function Procedure 0V: key switch OFF, B (+): key switch ON. B (+) to all coils with key ON, 0V key OFF. B (+): Line CTR open, 0V: closed B (+): Left FWD open, 0V: closed B (+): Left REV open, 0V: closed B (+): Right FWD open, 0V: closed B (+): Right REV open, 0V: closed B (+): Byp. CTR open, 0V: closed Voltage exchanges 0 to negative Voltage exchanges 0 to negative Voltage increases with current Voltage increases with current Activate pedal from full up to full down 0V = key switch OFF, 12V = key switch ON Logic board negative Activate steering wheel Activate lever from OFF to ON Activate by lever position Activate by lever position Activate lever from OFF to ON Activate lever from OFF to ON High: switch open, Low: closed Low: Park brake activated High: Park brake released Activate lever from OFF to ON (OPT) Activate lever from OFF to ON (OPT) Activated by overtemperature of control panel Activated by overtemperature of drive motor Activated by overtemperature of pump motor Activated by brush wear of drive motor Activated by brush wear of pump motor Activate lever from OFF to ON Turn steer wheel lock to lock Turn steer wheel lock to lock Turn steer wheel lock to lock Testing And Adjusting LOGIC VOLTAGE CHECKS Logic Wire Normal Activated Test Function Terminal No. Voltage Voltage Procedure P8-1 101 LCD: DC 5 Volt (+) 4.5 to 5.5 4.5 to 5.5 Key switch OFF: 0V, ON: 5V P8-2 WH LCD: DATA 0 High / Low 0V: segment OFF, High: On P8-3 YL LCD: DATA-bar 0 High / Low 0V: segment ON, High: OFF P8-4 GN LCD: CLOCK 0 High / Low 0V: segment OFF, High: On P8-5 BU LCD: CLOCK-bar 0 High / Low 0V: segment ON, High: OFF P8-6 BK LCD: LOAD 0 High / Low 0V: segment OFF, High: On P8-7 RD LCD: LOAD-bar 0 High / Low 0V: segment ON, High: OFF P8-8 108 Battery negative 0 0V P9-1 L65 0 0.1 to 1.3 Activated as drive TR pulses (Left TR) 0 0.1 to 1.3 Activated as drive TR pulses P9-2 R65 P9-3 75 P9-4 – P9-5 L64 P9-6 R64 P9-7 74 P9-8 – P9-9 4 Function Logic board negative Pulse drive TR base (Left motor) Pulse drive TR base (Right motor) (Right TR) Pulse pump main TR base 0 0.1 to 1.3 0 1.5 to B (+) 0 1.5 to B (+) 0 1.5 to B (+) Activated as pump TR pulses Not used Drive TR emitter sensor (Left) Voltage increases as drive TR pulses Drive TR emitter sensor (Right) Voltage increases as drive TR Pump main TR emitter Not used faster (Left TR) pulses faster (Right TR) Voltage increases as pump TR pulses faster 0 B(+) from positive heatsink 0 B (+) B (+) with line contactor closed NOTE : “Normal” ; battery connected, key switch and park switch closed. High voltage signal should be 9 to 12 volts. Low voltage signal should be 0 to 0.9 volt. MicroController Control Systems 106 Testing And Adjusting Conductor and Switch Continuity 1. Set the multimeter to the 200 Ω range. 2. Use the multimeter to perform the continuity test. lf continuity exists, the measurement will be less than 1 ohm. lf the measurement is more than this, continuity does not exist and the problem will have to be repaired. Capacitor (Head) WARNING 1 Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 2 5 4 3 Location of Components (1) Positive connection point. (2) Positive cable. (3) Negative connection point. (4) Negative cable. (5) Capacitor. 4. Disconnect positive cable (2) from the positive connection point (1). NOTICE Damage can be caused to the head capacitor. Do not remove bolts from capacitor to perform tests. Remove capacitor connecting cables at heatsink connections. 5. Disconnect negative cable (4) from the negative connection point (3). 6. Set the multimeter to the 20 KΩ range. Connect the multimeter positive lead to positive cable (2) of head capacitor (5). Connect the multimeter negative lead to negative cable (4) of head capacitor (5). lf the capacitor fails the Head Capacitor Test, then replace capacitor. 1. Disconnect the battery and discharge the head capacitor. 7. The meter must increment to above 10 KΩ. 2. Visually inspect the capacitor for bulges at the terminals. 8. If the head capacitor fails this test, then capacitor should be replaced. 3. Verify the plastic top is not melted around the terminals and that the blow plug is not leaking. See Head Capacitor in Specifications section for proper assembly order of the head capacitor connections and bolt torque specifications. WARNING Head Capacitor “blow plug” will rupture with reverse polarity. Vapors and contents of Head Capacitors are toxic, flammable and corrosive. Personal injury can be caused from breathing the fumes or if its contents make contact with the skin. Be sure to always connect the positive wire, from the positive heatsink, to the positive terminal of the Head Capacitor. MicroController Control Systems 107 Testing And Adjusting Contactors Contactor Components WARNING WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 1. Disconnect the battery and discharge the head capacitor. NOTICE Damage can be caused to the control panel. Do not switch the direction lever from one direction to the other (plug the lift truck) when the drive wheels are off the ground and in rotation at full speed. Coil Suppression Diodes 1. Connect the battery and close the seat switch. 1 35 2. Turn the key to ON and release the parking brake. The line contactor will close. 3. Select a direction and rapidly depress the accelerator pedal all the way to the floor. 246 4. Measure and record the time it takes the bypass contactor to close. This should be 1.5 to 2.5 seconds after the accelerator is fully depressed. 5. If the recorded value from Step 5 is less than 1.0 seconds, the logics may need to be replaced. (During normal operation this time will vary with the load on the truck). Suppression Diodes (1) D3-Line. (2) D4-Left Forward. (3) D5-Left Reverse. (4) D6-Right Forward. (5) D7-Right Reverse. (6) D8-Bypass. 6. If the recorded value from Step 5 is more than 2.5 seconds, check the bypass contactor tips for free movement. Check wiring for bad connections, and check current limit. 2. Disconnect the logic connector P1. 3. Set the multimeter to the diode test position. NOTE : The bypass contactor will not close if the accelerator linkage is not adjusted correctly. 4. Connect positive multimeter lead to anode, and the negative multimeter lead to cathode of diode in the logics. 5. The multimeter must indicate .3 to .9 volts. 6. Reverse the leads (positive multimeter lead to cathode and negative multimeter lead to anode). The meter must indicate OL. MicroController Control Systems 108 Testing And Adjusting Contactor Tips Coil Resistance 2. Disconnect all leads to both terminals of the coil. 3. Set the multimeter to the 200Ω range. 4. Measure the resistance of the coil at both teminals. If must be within specifications. See Component Measurements in Specifications section. 5. If the coil is not within specifications, the contactor assembly will be replaced. Coil Pulsing Checking Contactor Tip Gap 2. With the contactor coil leads and suppression assembly leads connected, set the multimeter to the 200 volts DC range. 2. Visually inspect the tips to verify they are not welded, melted, burned, or pitted. 3. Pull and release the tips quickly to verify there is no binding. 3. Connect the multimeter negative lead to the negative coil terminal wire #33 and the meter positive lead to the coil positive terminal wire #15. 4. Visually inspect the contactor assembly. Verify foreign objects don't interfere with normal contactor operation. 4. Connect the battery and activate the controls necessary for the contactor to be activated. 5. Check contactor tip gap with a feeler gauge as shown. Refer to Specifications section for correct settings. 5. After the contactor activates the multimeter must indicate 24 to 36 volts. If the voltage is not correct and the contactor passed the Coil Suppression Diodes test and the Coil Resistance test, the logics must be replaced. MicroController Control Systems 109 Testing And Adjusting Current Sensor 4. Check continuity from harness connector PIN2 wire #L22 to logic P1-12 (3) and connector PIN2 wire #R22 to logic P1-13 (4). Repair or replace any defective wires. WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery. The head capacitor (HEAD CAP) must be discharged before any contact with the control panel is made. Disconnect the battery and discharge HEAD CAP. 5. Set the multimeter to the 200V DC range. With connector P1 disconnected, connect the multimeter positive lead to logic P1-16 (5). Connect the multimeter negative lead to control panel battery negative. 1. Disconnect the battery, discharge the head capacitor, and remove the logic cover. 6. Connect the battery and turn the key to ON. The measurement must be 11 to 13 volts. If the measurement is not correct replace the logics. 7. Disconnect the battery and discharge the head capacitor. Connect P1. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 2 1 8. Set the multimeter to the 200V DC range and connect the positive lead to logic P1-12 (3) or P113(4) Location Of Components (1) Current Sensor - Right. (2) Current Sensor - Left. 2. Disconnect current sensor connector. 9. Connect the battery and turn the key to ON. The measurement must be 0 volts. 3. Make sure wire #1 from current sensors is connected to the negative heatsink. 3 10. Move the direction lever to forward and depress the accelerator. The voltage being measured should increase. If there is no voltage measured or the voltage being measured does not change, the current sensor must be replaced. 4 5 NOTE: If the current sensor is replaced current limit must be adjusted. P1 Connector Locations (3) P1-12. (4) P1-13. (5) P1-16. MicroController Control Systems 110 Testing And Adjusting Diodes Diode Replacement WARNING WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 10 7 9 11 Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 1. Disconnect the battery and discharge the head capacitor. 8 2. Remove the logics. 3. Disconnect the lead wire and remove the diode. 1 2 6 1 5 3 4 Location of Comporrents (1) DD1. (2) DD1cathode lead wire. (3) DD2. (4) DD2 cathode lead wire. (5) DD3. (6) DD3 cathode lead wire. (7) DD4. (8) DD4 cathode lead wire. (9) Battery negative heatsink. (10) PD. (11) PD cathode lead wire. Diode installation (1) Contact surfaces. 4. Wipe clean contact surfaces (1). Put a small amount of D557047 Thermal Joint Compound on contact surfaces (1), but not on the threads. DD1 (1) is shown in the procedure that follows. Use a similar procedure for the other diodes. DD1 (1), DD2 (3), DD3 (5), DD4 (7) and PD (10) have a cathode lead wire. 5. lnstall the diode and tighten to the specification listed in the chart that follows. Diode 1. Disconnect the battery and discharge the head capacitor. Torque DD1,DD2,DD3,DD4,PD 9 to 11 N•m (81 to 99 lb•in) 2. Disconnect DD1 cathode lead wire (2). 6. Connect all wires that were removed. 3. Set the multimeter to the diode test position. 4. Connect the negative multimeter lead on DD1 cathode lead wire (2). Connect the positive multimeter lead to battery negative (9). The multimeter should indicate .3 to.9 volts. 5. Reverse the multimeter leads. The multimeter should indicate OL. If any of the measurements are not correct, replace the diode. MicroController Control Systems 111 Testing And Adjusting Driver Board (On Vehicle) NOTE: Driver board components are soldered parallel to each other. The tests that follow may not be typical of individual components tests. The driver board must be replaced if any incorrect test results are obtained. WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. Drive Side Tests Refer to Driver Board Components and Connections. If any of the measurements that follow are incorrect the driver board must be replaced. NOTICE Damage to the control panel could result. To prevent further damage before the Driver Board is replaced, complete the check list that follow; 1. Disconnect the battery, discharge the head capacitor. 2. Disconnect CONN A from driver board - main. 3. Resistor R2 test. Set the multimeter to the 200Ω range. Connect the positive lead to CONN A-8. Connect the negative lead to CONN A-9. The measurement must be 7.1 to 7.9 ohms. 1. Check head capacitor for a failure. If the drive circuit failed: 2. 3. 4. 5. 6. Check diodes DD1, DD2. Check diodes DD3, DD4. Check transistors DTR1, DTR2. Check continuity of current sensor wires. Check continuity from DTR1 emitter (wire #L64) to logic connector P9-5 and DTR2 emitter (wire #R64) to logic connector P9-6. 4. Resistor R5 test. Set the multimeter to the 200Ω range. Connect the positive lead to CONN A-1. Connect the negative lead to CONN A-2. The measurement must be 7.1 to 7.9 ohms. 5. Transistor TR1 (collector/emitter) and ZD1 test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-8. Connect the negative lead to positive heatsink. The measurement must be .3 to .9 volts. If the hydraulic pump circuit failed: 2. Check diode PD. 3. Check transistor PTR1. 4. Check continuity from PTR1 emitter (wire #74) to logic connector P9-7. Reverse the test leads. The measurement must be OL. NOTE: Visually inspect the following connections to ensure proper connection and lack of corrosion. 6. Transistor TR3 (collector/emitter) and ZD2 test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-1. Connect the negative lead to positive heatsink. The measurement must be .3 to .9 volts. 1. Wire #L63 to the base of DTR1. 2. Wire #R63 to the base of DTR2. 3. Wire #73 to the base of PTR1. 4. Wire #74 to the emitter of PTR1. 5. Wire #4 to the positive heatsink. 6. Wire #1 to the negative heatsink. 7. Wires #L67 and #L68 to DR1. 8. Wires #R67 and #R68 to DR2. 9. Wires #77 and #78 to PR1. 10. Wires #L65, #R65 and #75 to connector P9–1, P9-2 and P9-3. Reverse the test leads. The measurement must be OL. 7. Transistor TR1 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-8. Connect the negative lead to CONN A-10. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. MicroController Control Systems 112 Testing And Adjusting 15. Transistor TR2 (emitter/base) and R3 test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-12. Connect the negative lead to CONN A-7. The measurement must be .3 to .9 volts as above 8. Transistor TR3 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-1. Connect the negative lead to CONN A-3. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. Reverse the test leads. The measurement must be almost same as above. 9. Transistor TR1 (emitter/base) and R1 test. Set the multimeter to the 200Ω range. Connect the positive lead to positive heatsink. Connect the negative lead to CONN A-10. The measurement must be 3.5 to 4.3 ohms. 16. Resistor R3 test. Set the multimeter to the 2 KΩ range. Connect the positive lead to CONN A-7. Connect the negative lead to CONN A-12. The measurement must be 1000 to 1400 ohms. 10. Transistor TR3 (emitter/base) and R4 test. Set the multimeter to the 200Ω range. Connect the positive lead to positive heatsink. Connect the negative lead to CONN A-3. The measurement must be 3.5 to 4.3 ohms. 17. Transistor TR4 (emitter/base) and R6 test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-5. Connect the negative lead to CONN A-5. The measurement must be .3 to .9 volts. 11. Transistor TR2 (collector/emitter) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-7. Connect the negative lead to CONN A-11. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be almost same as above. 18. Resistor R6 test. Set the multimeter to the 2 KΩ range. Connect the positive lead to CONN A-7. Connect the negative lead to CONN A-5. The measurement must be 1000 to 1400 ohms. Reverse the test leads. The measurement must be OL. 12. Transistor TR4 (collector/emitter) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-7. Connect the negative lead to CONN A-4. The measurement must be .3 to .9 volts. 19. Connect all disconnected connectors. Reverse the test leads. The measurement must be OL. 13. Transistor TR2 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-12. Connect the negative lead to CONN A-11. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. 14. Transistor TR4 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-5. Connect the negative lead to CONN A-4. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. MicroController Control Systems 113 Testing And Adjusting 8. Transistor TR5 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN B-1. Connect the negative lead to CONN B-4. The measurement must be .3 to .9 volts. Hydraulic Pump Side Tests Refer to Driver Board Components and Connections. If any of the measurements that follow are incorrect the driver board must be replaced. Reverse the test leads. The measurement must be OL. 1. Disconnect the battery, discharge the head capacitor. 9. Transistor TR5 (emitter/base) and R7 test. Set the multimeter to the 200 Ω range. Connect the positive lead to positive heatsink. Connect the negative lead to CONN B-4. The measurement must be 3.5 to 4.3 ohms. 2. Disconnect CONN A, CONN B from driver board main. 3. Transistor TR6 (collector/emitter) test. Set the multimeter to the diode test position. Connect the positive lead to CONN A-7. Connect the negative lead to CONN B-5. The measurement must be .3 to .9 volts. 10. Resistor R8 test. Set the multimeter to the 200 Ω range. Connect the positive lead to CONN B-1. Connect the negative lead to CONN B-2. The measurement must be 7.1 to 7.9 ohms. Reverse the test leads. The measurement must be OL. 11. Connect all disconnected connectors. 4. Transistor TR5 (collector/base) test. Set the multimeter to the diode test position. Connect the positive lead to CONN B-6. Connect the negative lead to CONN B-5. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. 5. Transistor TR6 (emitter/base) and R9 test. Set the multimeter to the diode test position. Connect the positive lead to CONN B-6. Connect the negative lead to CONN A-7. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be almost same as above. 6. Resistor R9 test. Set the multimeter to the 200Ω range. Connect the positive lead to CONN B-6. Connect the negative lead to CONN A-7. The measurement must be 1000 to 1400 ohms. 7. Transistor TR5 (collector/emitter) and ZD3 test. Set the multimeter to the diode test position. Connect the positive lead to CONN B-1. Connect the negative lead to positive heatsink. The measurement must be .3 to .9 volts. Reverse the test leads. The measurement must be OL. MicroController Control Systems 114 Testing And Adjusting Driver Board (Off Vehicle) Driver Board – Main 2 1 9 7 8 5 6 3 4 Driver Board Components and Connections (1) CONN A. (2) CONN B. (3) TR1. (4) TR2. (5) TR3. (6) TR4. (7) TR5. (8) TR6. (9) Positive heatsink. MicroController Control Systems 115 Testing And Adjusting DRIVER BOARD TEST (OFF VEHICLE) Component Multimeter Range + Lead - Lead Result DRIVE SIDE TR1 (C to E) Diode #R63-A8 +HEATSINK 0.3 to 0.9 volts TR1 (C to E) Diode +HEATSINK #R63-A8 OL TR1 (C to B) Diode #R63-A8 #R67-A10 0.3 to 0.9 volts TR1 (C to B) Diode #R67-A10 #R63-A8 OL TR1 (E to B) AND R1 200Ω +HEATSINK #R67-A10 3.5 to 4.5 ohms R2 200Ω #R63-A8 #R64-A9 7.1 to 7.9 ohms TR2 (C to E) Diode #1-A7 #R68-A11 0.3 to 0.9 volts TR2 (C to E) Diode #R68-A11 #1-A7 OL TR2 (C to B) Diode #R65-A12 #R68-A11 0.3 to 0.9 volts TR2 (C to B) Diode #R68-A11 #R65-A12 OL TR2 (E to B) AND R3 Diode #R65-A12 #1-A7 0.3 to 0.9 ohms R3 200Ω #R65-A12 #1-A7 1000 to 1400 ohms TR3 (C to E) Diode #L63-A1 +HEATSINK 0.3 to 0.9 volts TR3 (C to E) Diode +HEATSINK #L63-A1 OL TR3 (C to B) Diode #L63-A1 #L67-A3 0.3 to 0.9 volts TR3 (C to B) Diode #L67-A3 #L63-A1 OL TR3 (E to B) AND R4 200Ω +HEATSINK #L67-A3 3.5 to 4.3 ohms R5 200Ω #L63-A1 #L64-A2 7.1 to 7.9 ohms TR4 (C to E) Diode #1-A7 #L68-A4 0.3 to 0.9 volts TR4 (C to E) Diode #L68-A4 #1-A7 OL TR4 (C to B) Diode #L65-A5 #L68-A4 0.3 to 0.9 volts TR4 (C to B) Diode #L68-A4 #L65-A5 OL TR4 (E to B) AND R6 Diode #L65-A5 #1-A7 0.3 to 0.9 ohms R6 200kΩ #L65-A5 #1-A7 1000 to 1400 ohms PUMP SIDE TR5 (C to E) Diode #73-B1 +HEATSINK 0.3 to 0.9 volts TR5 (C to E) Diode +HEATSINK #73-B1 OL TR5 (C to B) Diode #73-B1 #77-B4 0.3 to 0.9 volts TR5 (C to B) Diode #77-B4 #73-B1 OL TR5 (E to B) AND R7 Diode #77-B4 +HEATSINK 0.3 to 0.9 ohms R8 200kΩ #73-B1 #74-B2 1000 to 1400 ohms TR6 (C to E) Diode #1-A7 #78-B5 0.3 to 0.9 volts TR6 (C to E) Diode #78-B5 #1-A7 OL TR6 (C to B) Diode #75-B6 #78-B5 0.3 to 0.9 volts TR6 (C to B) Diode #78-B5 #75-B6 OL TR6 (E to B) AND R9 200Ω #1-A7 #75-B6 3.5 to 4.3 ohms R9 200Ω #1-A7 #75-B6 7.1 to 7.9 ohms MicroController Control Systems 116 Testing And Adjusting 1. Check head capacitor for a failure. Transistors DTR1,DTR2 and PTR1 If drive circuit failed: WARNING 2. 3. 4. 5. 6. Check DD1,DD2 for a failure. Check DD3,DD4 for a failure. Check DTR1,DTR2 for a failure. Check driver board (drive side) for a failure. Check continuity from DTR1,DTR2 emitter bus bar (wire #L64, #R64) to logic P9-5, P9-6. 7. Perform Current Sensor test. Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. If the pump circuit failed: 1. Disconnect the battery, discharge the head capacitor and remove the logics. 2. 3. 4. 5. 2. Remove wires and bus bars from base and emitter terminals of the transistors to be tested. 1 2 E B Check PD for a failure. Check PTR1 for a failure. Check driver board (pump side) for a failure. Check continuity from PTR1 emitter (wire #74) to logic P9-7. Transistor Replacement DTR1, DTR2 and PTR1 E 3 3 WARNING BX Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. D557003 (927566) Transistor (1) Emitter. (2) Base. (3) Collectror. 9 TRANSISTOR SPECIFICATIONS Multimeter (+) (-) D557003 Setting Test Lead Test Results 8 7 Resistance Emitter Base 45 to 135 Ω Diode Base Collector .3 to .9V Diode Collector Base OL Diode Emitter Collector .3 to .9V Diode Collector Emitter OL 4 6 5 3 1 2 Location of Components (1) Bolt. (2) Bar. (3) Emitter wire #L64. (4) Base wire #L63. (5) Transistor DTR1. (6) Screw. (7) Screw (8) DTR2. (9) PTR1. NOTICE Damage to the control panel could result. To prevent further damage before a power transistor is replaced, complete the check list that follows: DTR1,DTR2 and PTR1 are all replaced in the same way. DTR1(5) is shown in the procedure that follows. MicroController Control Systems 117 Testing And Adjusting 1. Disconnect the battery, discharge the head capacitor, and remove the logics. Resistors (DR1, DR2 and PR1) 2. Remove bolt (1), bar (2) and emitter wire #L64 (3). WARNING 3. Remove screw (6) and base wire #L63 (4). Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. 4. Remove mounting bolts (7). NOTE : Look for visual breaks or cracks on resistors. 1. Disconnect the battery, discharge the head capacitor, and remove the logics. 8 Transistor Removal (8) Contact surface. 2 4 6 1 3 5 8 5 Transistor Removal (5) DTRI transistor, (8) Contact surtace. Location of Components (1) DR1. (2) Wire #L67. (3) DR2. (4) Wire #R67. (5) PR1. (6) Wire #77. 5. The contact surface (8) of transistor (5) is coated with D557047 Thermal Joint Compound. Carefully remove the transistor. 2. Disconnect wire #L67 (2) from resistor DR1 (1) and disconnect wire #R67 from resistor DR2 (3) and disconnect wire #77 from resistor PR1 (5) 6. To Replace the transistor, wipe clean contact surfaces. Put a small amount of D557047 Thermal Joint Compound on the contact surface (8). Coat transistor so that compound covers only the contact area. 3. Set the multimeter to the 200Ω range. Connect the multimeter leads to terminals on resistor (1) to check the resistance of DR1. Connect the multimeter leads to terminals on resistor (3) to check the resistance of DR2. Connect the multimeter leads to terminals on resistor (5) to check the resistance of PR1. 7. Install transistor (5) with mounting bolts (7). See Specifications section for proper torques. 4. The measurement for each resistor must be: 85 to 95 ohms. 8. Install base wire #L63 (4) with screw (6). See Specifications section for proper torques. 5. If the measurement is not correct, the resistor must be 9. Install bar (2) and emitter wire #L64 (3) with bolts (1). See Specifications section for proper torques. MicroController Control Systems 118 Testing And Adjusting Thermal Switch The Thermal Switch (1) will open circuit if the temperature is 81 to 89°C (178 to 192°F) and close circuit at 69 to 77°C (156 to 171°F). WARNING Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery and discharge the head capacitor (HEAD CAP) before any contact is made with the control panel. If the thermal switch is removed from the heatsink, it can be tested in an oven. See Troubleshooting Problem 20. Possible cause, pump or drive transistors overtemperature. Pump Motor and Drive Motor NOTICE Damage to the thermal switch will occur. Do not heat the thermal switch over an open flame. The Thermal Switch (1) will open circuit if the temperature is 144 to 156°C (291 to 313°F) and close circuit at 123 to 137°C (253 to 279°F). If the thermal switch is removed from the motor, it can be tested in an oven. Control Panel See Troubleshooting Problems 21 and 22. Possible cause, drive or pump motors overtemperature. 1 Location of Components (1) Thermal switch. MicroController Control Systems 119 Testing And Adjusting Electrical System Adjustments Accelerator Control Linkage Parking Brake Switch Method A (Mechanical) WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 1 4 63 2 3 2 1. Disconnect the battery and discharge the head capacitor. 3 2. Adjust length of lever (1) to 63 L 2 mm and tighten the nut (2). Fully depress accelerator pedal (4) until stopped by accelerator stopper (3). 1 4 3. Release accelerator pedal (4). Check for dimension. Parking Brake Switch Adjustment (1) Switch. (2) Plate. (3) Bolts. (4) Bracket. 1. Close the seat switch and turn the key to ON. Method B (Electrical) 2. Release the parking brake and put the truck in forward. 1. Enter diagnostics, through the specified procedure, the display is an “A0”. 3. Reposition plate (2) so the switch (1) actuator is against the bracket. Tighten bolts (3). 2. Depress the accelerator slowly to stop. The speed symbols will increase from 0 to 10 on LCD. 4. Engage the parking brake and the park brake symbol will be displayed. Repeat the procedure until adjustment is correct. 3. Release the accelerator, the display will be “A0”, disconnect the battery, and place the DIAG/RUN/SETUP switch back to RUN, and reinstall the line fuse. MicroController Control Systems 120 Testing And Adjusting Lift Sensor Valve Control Card Adjustment 1. Disconnect the battery and discharge the head capacitor. 1 WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safety lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 3 1. Verify the lift sensor clearance is adjusted correctly. 4 2 2. Disconnect all tilt and auxiliary switch connectors. 3. Place the lift truck in “Quick” or “Self” diagnostics so that the display is flashing the lift speed. Lift Sensor Adjustment (1) Lift Sensor(transducer) (2) Magnet. (3) Screw. (4) Setscrew. (A) 1.0 mm (.039 in) Clearance. NOTICE Lift sensor may be damaged. Do not allow the magnet (2) to make contact with the plastic bracket when the lift lever is activated. 1 2. Loosen setscrew (4). 3. Adjust screw (3) to make clearance (A) 1.0mm (.039 in) between lift sensor (1) and magnet (2) when the lift lever is activated fully (pulled all the way back). 2 Valve Control Card Adjustment (1) P1 Potentiometer. (2) P2 Potentiometer. 4. Turn potentiometer P1 (1) fully counterclockwise unitl a clicking sound is heard (roughly 20 turns). 4. Tighten setscrew (4). Check lift sensor circuit. The valve control card may need adjusting. 5. Turn potentiometer P2 (2) fully counterclockwise until a clicking sound is heard (roughly 20 turns). 6. Turn potentiometer P2 (1) 15 full turns clockwise. 7. Position the lift lever just prior to the hydraulic valve opening. Adjust P1(1) clockwise until a flashing “1” is obtained on the display. MicroController Control Systems 121 Testing And Adjusting 8. Pull the lift lever all the way back. A flashing “3” must be displayed. Tilt and Auxiliary Switches 9. If a flashing “3” is not displayed, adjust P2 (2) clockwise until it is. Because each tilt and auxiliary switch can turn on the pump motor, it is recommended that only one be connected to start with. After adjusting the first switch proceed with the next one. 10. Release the lift lever and adjust P1 counterclockwise until a “0” is displayed. 1. Disconnect the battery and discharge the head capacitor. Disconnect all but one switch connector. 11. Repeat steps 9 and 10 until “0” to “3” speeds correct. 12. Put the lift truck back in the run mode so the actual hydraulics can be tested. 13. Connect the battery, close the seat switch and turn the key to ON. 14. Pull the lift lever back until the pump motor turns on. The forks must not move. Adjust P1 so the motor starts just before the valve opens. 1 If the valve opens before the motor turns on, adjust P1 (1) clockwise. 2 If the motor turns on too far in advance of the valve opening, adjust P1 (1) counterclockwise. Tilt and Auxiliary Switch Adjustment (1) Screw. (2) Screws. 2. With valve spool in neutral position, loosen screws (2) and adjust screw (1) to center the switch roller on cam. 3. After adjusting switch in or out to obtain correct switch point, tighten screws (1) and (2) to lock switch into position. 4. Connect the battery, close the seat switch and turn the key to on. Readjust switch if needed, so that the pump motor turns on before the control valve opens. This must be adjusted for each lever direction (pushed or pulled). 5. Connect the next switch and repeat this proccdure. MicroController Control Systems 122 Testing And Adjusting 3) VR6 : Bypass Dropout Current Potentiometer Rapid Tune-Up Procedure Fully counterclockwise (CCW) and then slowly turn VR6 (20 full turns) clockwise (430A). 5 4) VR8 : Electrically assisted brake current limit potentiorneter. Fully counter clockwise (CCW) and then solwly turn VR8 (5 full turns) clockwise (170A). 4 3 2 1 4. Make the final adjustments as specified in each of the Testing And Adjusting procedures before putting the truck into service. Perform these procedures in the order listed below: Lacation of Potentiometers (1) Current limit potentiometer VR1. (2) Plugging Current limit potentiometer VR2. (3) BDI adjustment potentiometer VR5. (4) Bypass drop out adjustment potentiometer VR6. (5) EAB adjustment potentiometer VR8 1) Battery Discharge Indicator (BDI) 2) Current Limit The rapid tune-up procedure establishes a starting point for logic card adjustments. The following procedure allows the truck to run without damage to the truck or its components. 3) Plugging Current Limit 4) Electrically Assisted Brake Current Limit. 5. Turn off the key switch. WARNING Battery Discharge Indicator (BDI) Adjustment The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 1. Turn off the key switch. 1 3 2. Place direction lever to reverse or forward or seat switch open. 2 3. Turn on the key switch and then wait until display “EE” (SRO) or “EE” flashing shows on the LCD and the line contactor will be opened. Logic Board Layout (1) Jumper JP1. (2) Jumper JP2. (3) Potentiometer VR5 1) VRI : Drive Motor Current Limit Potentiometer Accurate adjustment of the BDI is only possible with a battery of the same voltage that the truck is going to operate at, and at a voltage within the range of the display. If a lift interrupt has occurred, with a “EL” on the display, it may be necessary to reprogram Feature “10” to select TYPE1, and then make the necessary adjustments. If 48 volt European tubular batteries are used, it is recommended that logic board is programmed TYPE1 on Programmable Feature “10”. Fully counterclockwise (CCW) and then slowly turn VR1 (9 full turns) clockwise (270A). 2) VR2 : Plugging Current Limit Potentiometer Fully counterclockwise (CCW) and then slowly trun VR2 (8 full turns) clockwise (250A). MicroController Control Systems 123 Testing And Adjusting Battery Table of the Closed Circuits BDI Adjustment Battery Terminal Voltage 1. Disconnect the battery and discharge the head capacitor. Remove logic cover and verify the DIAG/RUN/SETUP switch is in the RUN position. Bar Symbols Display 2. Make sure the jumper connector is in the correct place for the lift truck battery used. Place the jumper on the following. JP1=36V, JP2=48V 3. Set the multimeter to measure battery voltage. Connect the multimeter positive lead to the battery positive cable at the line contactor. Connect the multimeter negative lead to the battery negative cable. 4. Put the direction lever in neutral and connect the battery. Type 1(OPT) : Closed Voltage 36V 48V 6 above 37.2 above 49.1 5 36.8 to 37.2 48.6 to 49.1 4 36.4 to 36.7 48.0 to 48.5 3 36.0 to 36.3 47.5 to 47.9 2 35.6 to 35.9 47.0 to 47.4 1 35.2 to 35.5 46.5 to 46.9 1* 25.8 to 35.1 33.8 to 46.4 0/EL below 25.8 below 33.8 1*=Display is flashing 5. Close the seat switch and turn the key to ON. The BDI display must show the correct bar for the voltage measured. To correct values are shown in the charts that follow. Battery Terminal Voltage Bar Symbols Display Type 1(STD) : Closed Voltage 36V 48V EXAMPLE: If the measurement is 49.1 volts for a 48 volt battery, the bar display should be at “5”. 6 above 37.2 above 49.1 5 36.8 to 37.2 48.4 to 49.1 6. If the display is not correct, turn the key to OFF and make an adjustment to potentiometer VR5. Turn VR5 clockwise to increase and counterclockwise to decrease the bar display. Approximately a 1/2 turn of VR5 will change the display one bar. Turn the key to OFF between adjustments otherwise the display WILL NOT CHANGE. 4 36.4 to 36.7 47.7 to 48.3 3 35.9 to 36.2 47.1 to 47.6 2 35.4 to 35.8 46.4 to 47.0 1 35.0 to 35.3 45.9 to 46.3 1* 34.5 to 34.9 45.0 to 45.8 0/EL below 34.5 below 45.0 1* = Display is flashing 7. If the voltage was 49.1V, VR5 should be turned to find the transition point between 6 and 5 on the bar display. This will assure that the BDI is calibrated at a high 5. 6 : The highest position Battery Terminal Voltage Bar Symbols Display : Max. Charged Status 5: 4: 3: 2: 1: : (A) Not flashing (B) Flashing - 80% discharge warning MicroController Control Systems Type 1(OPT) : Closed Voltage 36V 48V 6 above 37.2 above 49.1 5 36.9 to 37.2 48.3 to 49.1 4 36.6 to 36.8 47.4 to 48.2 3 35.3 to 36.5 46.6 to 47.3 2 35.9 to 36.2 45.7 to 46.5 1 35.6 to 35.8 44.9 to 45.6 1* 35.3 to 35.5 44.0 to 44.8 0/EL below 35.3 below 44.0 1* = Display is flashing 124 Testing And Adjusting NOTE: Closed Voltage means that line contactor close and idle operation in hydraulic system. 7. If the voltage is higher than 49.1V, adjust the BDI as example. EXAMPLE: If the measurement is 50.7V, adjust bar display at a low 6 and then turn VR5 to 1 TURN CW. (1 TURN CW = 1.6V increase) BDI Adjustment with display at “EL” If the logics has already gone into lift interrupt (display = “EL”) it is not possible to adjust the BDI until a battery above a certain programmed voltage is connected to the vehicle. The factory default setting to reset the lift interrupt is any voltage equivalent to a bar display of 3 or higher. This level can be adjusted. See Program Feature “3”. By reprogramming Feature “3”, from the factory default code of 3, to a temporary code of 0, it will become possible to adjust the BDI with a battery with a voltage less than a 3 on the bar display . After adjustment of the BDI, reprogram Feature “3” back to the default setting of 3. MicroController Control Systems 125 Testing And Adjusting Current Limit Test and Adjustment 4. Engage the park brake. Connect the park brake connector of harness to hold the closed circuit. 5. Connect the battery. Close the seat switch and turn the key to ON. 6. Select a direction and depress the service brake so that the wheels do not turn. Depress the accelerator to 80% pulsing. To prevent bypass operation ensure that the accelerator is not depressed all the way down. To get an accurate current reading the wheels must not slip. 1 Ammeter Connection (1) Digital Ammeter. NOTICE Damage to the drive motor will result. Do not stall the drive motor for longer than absolutely necessary. To protect the drive motor from excessive currents, and “F0” can occur during current limit setting. Allow for the motors to cool between stalls, and let the motor run between stalls. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 7. The current measurement must be within specification. Adjust logic potentiometer VR1 clockwise to increase the current and counterclockwise to decrease the current. 48V between 265 and 275 amps. NOTE : Current limit is preset at the factory and should not be adjusted unless the truck malfunctions, or the logic board is replaced. Only qualified service personnel with the correct instrumentation should adjust current limits. 8. Repeat steps 6 and 7 until setting is correct. 9. Don’t forget to re-engage the service brake switch and park brake switch prior to putting the vehicle back into operation. 1. Put blocks of wood under the frame so both drive wheels are free to turn. 2. Connect clamp-on ammeter (1) around the LA1 cable to measure drive motor current. Use multimeter to read current remotely from the operator’s seat. Ensure that option feature “9” is default setting to prevent bypass operation. 3. Remove the floor plate, and disconnect the service brake switch connector. MicroController Control Systems 126 Testing And Adjusting Electrically Assisted Braking (EAB) Electrical Braking (Plugging) Current Test and Adjustment Refer to Program Feature #2. This is Default Setting. 1. Make sure current limit is adjusted to specification before adjusting EAB current. 2. Connect clamp-on current probe (1) around LA1 cable to measure drive motor current. Use multimeter to read current remotely from the operator’s seat. 3. Move the lift truck FORWARD at full speed. Just release the accelerator pedal. 1 4. The current measured during the Electrically Assisted Braking must be 170 ± 10 amps. Ammeter Connection (1) Digital Ammeter. 5. If the correct current is not measured, adjust potentiometer VR8. Turn the potentiometer adjustment screw counterclockwise to decrease this current. General Plugging with Direction Lever 1. Make sure current limit is adjusted to specification before adjusting Electrical Braking current. NOTE : This EAB current should be lowerer than above General Plugging current 250 amps. 2. Connect clamp-on current probe (1) around LA1 cable to measure drive motor current. Use multimeter to read current remotely from the operator’s seat. Bypass Dropout Adjustment - Stall Protection 3. Move the lift truck FORWARD at full speed. Keep the accelerator pedal fully depressed and change the direction to REVERSE. WARNING The lift truck can move suddenly. Injury to personnel or damage to the lift truck is possible. Safely lift the drive wheels off the floor. Put blocks of wood under the frame so both drive wheels are free to turn. Keep away from drive wheels that turn. 4. The current measured during the electircal braking (plugging )must be 250 ± 10 amps. 5. If the correct current is not measured, disconnect the battery and discharge the head capacitor. Remove the logic cover and adjust potentiometer VR2. Turn the potentiometer adjustment screw counterclockwise to decrease the plugging current. The stall protection feature helps protect the drive motor from abuse, and can also prevent unnecessary line fuse failures. Adjustment or checking of this current setting is not recommended unless drive motor or fuse failures have occurred, or an “F0” occurs during bypass operation. Factory settings are as follows: NOTE : Though the plugging distance (Recommended plugging distance is approximately 5 meters) is an application specific adjustment, plugging current should not exceed 250 amps. If the recommended current produces a short stopping distance, the distance may be lengthened by turning potentiometer VR2 counterclockwise to reduce plugging current. MicroController Control Systems 48V between 420 and 440 amps Fully counterclockwise (CCW) and then slowly turn VR6 (20 full turns) clockwise (430A). If “F0” occurs during bypass operation, the application should be investigated for incorrect operation, and maximum currents should be measured. Adjusting VR6 clockwise will increase the maximum current allowed in bypass. For maximum motor protection, VR6 can be adjusted counterclockwise, until a “F0” occurs in bypass, then adjust the potentiometer clockwise 1 turn. 127 Testing And Adjusting Programmable Features There are 17 programmable features that effect the operation of the lift truck. A table of these features, the default setting, the minimum setting and the maximum setting are shown below: With the desired Feature Number being shown, move the direction lever to forward or reverse and then neutral. The display will flash the preset data value. To increase the value, cycle the direction lever to forward and then back to neutral. The display will increment number. Repeat this cycle until the desired value for this feature is flashed. Feature Minimum Maximum Default Number Setting Description Setting Setting 0 1 5 4 Creep Speed 1 1 6 2 Maximum Steering Speed 2 0 2 1 Electrically Assisted Braking 3 0 6 3 Discharged Battery Reset Value 4 0 5 0 Top Travel Speed Limit 5 - - P Not Used 6 0 4 2 Wait Timer (seconds) 7 1 2 1 Discharged Battery Drive Speed 8 1 5 4 Acceleration Travel Speed Time 9 1 3 1 Excessive Drive Motor Current 10 1 3 2 Battery Type Selection 11 1 6 3 Maximum Idle Speed 12 1 6 3 Maximum Lift1 Speed 13 1 6 1 Maximum Lift2 Speed 14 1 6 3 Maximum Tilt Speed 15 1 9 4 Maximum Auxiliary Speed 16 1 5 3 Hydraulic Ramp Timer To save a new setting, pull the tilt lever to maximum position and then release slowly while holding a wanted setting. The display will show the next feature number. 3. Repeat again on the above NO.2 until static display, 16 will show. A “PE” indicates the end of the feature list and can be cycled to return to the beginning of the feature list. Activating Default Settings All of the programmable features can be set to the factory default settings by the following procedure. 1. Turn the key switch to OFF. Setting Procedure Option Features 2. Seat switch must be open. The programming procedures are described on the following. 3. Move the direction lever to reverse. 4. Place the DIAG/RUN/SETUP switch to SETUP. 1. Initial conditions 5. Park brake must be released. Move the DIAG/RUN/SETUP switch to “SETUP” and then turn on the key switch. 6. With depressing the accelerator pedal to maximum. Wait until display “0” shows on the LCD. This code indicates that truck is in the SETUP mode. 7. Turn the key switch to ON. 2. Programming methods 8. After the display performs the LCD test, a “d” (Flashing) will be displayed. This indicates that the default settings have been programmed. To change the Programmable Feature Numbers, pull the tilt lever to maximum position and then release once. The display will show Feature Number 1. Cycling the tilt switch advances the display to the next Feature Number. Cycle the tilt switch until the Feature Number of the parameter to be programmed is shown on the display. MicroController Control Systems 128 Testing And Adjusting Programmable or Settable Option Features The logics contains a number of features which are either settable or programmable. The following is a list of the features, however the “Service Manual” or your Daewoo Dealer should be consulted in determing which options may be beneficial to the application. Note : Marked means default setting. FEATURE NO. DESCRIPTIONS • • Creep Speed •B • 0 Creep Speed Selection provides for slower creep speed control, especially at high mast application. Depending on truck chassis configuration and customer preference, the creep speed can be selected. The default setting of 2 gives improved creep speed control, especially at higher mast. The higher “number” makes more faster creep speed. Data Codes 1 2 3 4 5 On-Duty (%) 20 23 26 29 32 • • Maximum Steering Speed •B • This can be used to limit the maximum steering speed of the truck. These values are on-duty ratio of the pump main transistor base. 1 Data Codes 1 2 3 4 5 6 On-Duty (%) 17 20 23 26 29 32 • • Electrically Assisted Braking •B • 2 To automatically activate plugging braking when the service brake is activated or accelerator pedal is released. Data Codes 0 1 2 Comments Not used Release Accel or Activate Service Brake Activate Servrice Brake • • Discharged Battery Reset Value •B • 3 This feature sets the level of battery charge required to enable the hydraulics after a lift interrupt occurs. The battery discharge indicator (BDI) must read a level greater than the value set in this feature to enable the hydraulics after a lift interrupt occurs. (1* = Display is flashing) Data Codes 0 1 2 3 4 5 6 On-Duty (%) 1* 1 2 3 4 5 6 • • Top Travel Speed Limit •B • 4 The value of this feature is set to select the drive motor top speed. Values between 1 and 5 allow for varying speeds, 1 being the slowest and 5 being the fastest without using the bypass contactor. 0 being the normal travel and bypass operation. Data Codes 0 1 2 3 4 5 Speed(%) 100 : Bypass operation 43 50 60 75 90 MicroController Control Systems 129 Testing And Adjusting FEATURE NO. DESCRIPTIONS • • Auto plugging •B • 5 If selected this feature will automatically activate auto plugging braking when the accelerator released during driving Data Codes P Time (Sec) Pass • • Wait Timer •B • 6 This feature varies the time before the line contactor drops out after the truck has been inactive (wait mode-no operator requests, and direction lever in neutral). The delay may be set in 6 second increments between 0 and 12 seconds. Data Codes 0 1 2 3 4 Time (Sec) 0 3 6 9 12 • • Discharged Battery Drive Speed •B • 7 This feature sets the drive motor top speed during lift interrupt, battery lock-out. If the display shows “EL”, the logics limits the drive motor top speed to the value set in this feature. Data Codes Comments 1 2 1. Max.speed=70% 1. Normal operation. 2. No bypass operation. 2. Bypass operation. • • Acceleration Travel Speed Time •B • 8 This feature allows for varying amounts of time until the bypass contactor close when accelerator pedal has been depressed from zero to max. position. Data Codes 1 2 3 4 5 Time (Sec) Slowest Slower Normal Faster Fastest • • Excessive Drive Motor Current •B • 9 This prevents the truck from entering bypass when the truck is in current limit, thus extending the life of the bypass contactor tips, reducing line fuse failures, and extending drive motor brush life. If the motor is stalled for longer than the timer is set for, the vehicle will failsafe to prevent motor damage and an “F0” will be displayed. Data Codes Comments 1 2 3 This is to protect drive This is to protect drive motor from excessive motor from excessive current in either pulsing current in only bypass or bypass modes. modes. Not used • • Battery Type Selection •B • 10 Due to different voltage characteristics of battery technologies, specifically european tubular designs, it may be necessary to use a battery voltage chart with a reduced voltage range. Data Codes 1 2 3 Battery Voltage (Volt) Max.49.1/Min.33.8 Max.49.1/Min.45.0 Max.49.1/Min.44.0 MicroController Control Systems 130 Testing And Adjusting FEATURE NO. DESCRIPTIONS • • Maximum Idle Speed •B • 11 This can be used to limit the maximum idle speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 1 2 3 4 5 6 On-Duty (%) 7 9 11 13 15 17 • • Maximum Lift 1 Speed •B • 12 This can be used to limit the maximum lift 1 speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 1 2 3 4 5 6 On-Duty (%) 25 30 35 40 45 50 • • Maximum LIft 2 Speed •B • 13 This can be used to limit the maximum lift 2 speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 1 2 3 4 5 6 On-Duty (%) 50 60 70 80 90 95 • • Maximum Tilt Speed •B • 14 This can be used to limit the maximum tilt speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 15 1 2 3 4 5 6 On-Duty (%) 30 • •B • • Maximum Auxiliary Speed 40 50 60 70 80 This can be used to limit the maximum aux. speed of the truck. These values are on-duty ratio of the pump main transistor base. Data Codes 1 2 3 4 5 6 7 8 9 Time (Sec) 30 35 40 45 55 65 75 85 95 • • Hydraulic Ramp Timer •B • 16 When the hydraulic switches are activated, the time which is to take to maximum pulsing can be adjusted. Data Codes 1 2 3 4 5 On-Duty (%) Slowest Slower Normal Faster Faster MicroController Control Systems 131 Testing And Adjusting SB4100E00 Sep. 2003 Specifications Systems Operation Testing & Adjusting Disassembly & Assembly Lift Trucks Power Train B15T-2, B18T-2, B20T-2 (36V) EMOD4-00001~UP EMOD5-00001~UP EMOD6-00001~UP B13T-2, B15T-2, B18T-2, B20T-2 (48V) EMOFB-00001~UP EMOFC-00001~UP EMOFD-00001~UP EMOD7-00001~UP Important Safety Information Most accidents involving product operation, maintenance and repair are caused by failure to observe basic safety rules or precautions. An accident can often be avoided by recognizing potentially hazardous situations before an accident occurs. A person must be alert to potential hazards. This person should also have the necessary training, skills and tools to perform these functions properly. Improper operation, Iubrication, maintenance or repair of this product can be dangerous and could result in injury or death. Do not operate or perform any Iubrication, maintenance or repair on this product, until you have read and understood the operation, Iubrication, maintenance and repair information. Safety precautions and warnings are provided in this manual and on the product. If these hazard warnings are not heeded, bodily injury or death could occur to you or other persons. The hazards are identified by the "Safety Alert Symbol" and followed by a "Signal Word" such as "WARNING" as shown below. WARNING The meaning of this safety alert symbol is as follows : Attention! Become Alert! Your Safety is Involved. The Message that appears under the warning, explaining the hazard, can be either written or pictorially presented. Operations that may cause product damage are identified by NOTICE labels on the product and in this publication. DAEWOO cannot anticipate every possible circumstance that might involve a potential hazard. The warnings in this publication and on the product are therefore not all inclusive. If a tool, procedure, work method or operating technique not specifically recommended by DAEWOO is used, you must satisfy yourself that it is safe for you and others. You should also ensure that the product will not be damaged or made unsafe by the operation, Iubrication, maintenance or repair procedures you choose. The information, specifications, and illustrations in this publication are on the basis of information available at the time it was written. The specifications, torques, pressures, measurements, adjustments, illustrations, and other items can change at any time. These changes can affect the service given to the product. Obtain the complete and most current information before starting any job. DAEWOO dealers have the most current information available. 1 Index Specifications Brake ......................................................................15 Drive Motor............................................................... 7 Final Drive ................................................................ 9 General Tightening Torques ..................................... 5 Motor and Transmission ..........................................13 Wheel Mounting...................................................... 11 Systems Operation Drive Motor ..............................................................18 Final Drive ...............................................................20 General Information.................................................17 Testing And Adjusting Brake ......................................................................36 Connecting The Brake Cable .............................36 Connecting The Hydraulic Brake System ..........36 Replenishing With Transmission Fluid ...............37 Drive Motor ..............................................................27 Armature Terminal Test ......................................32 Armature Tests ...................................................28 Brush Holder Test...............................................32 Brush Lift Estimate .............................................33 Commutator Inspection .....................................30 Field Coil and Terminal Tests .............................31 Motor Brushes ....................................................27 Thermal Switch Tests .........................................33 Motor and Transmission ..........................................34 Motor Transmission Unit and Vehicle Frame ..........35 Troubleshooting .......................................................22 Checks During Operation...................................22 Drive Motor....................................................22 Transmission .................................................26 Visual Checks.....................................................22 Disassembly and Assembly Drive Axle ................................................................38 B15/18/20T-2(36V) Disassemble Drive Axle ................................38 Assemble Drive Axle .....................................41 B13/15/18/20T-2(48V) Disassemble Drive Axle ................................49 Assemble Drive Axle .....................................55 Special Service Tools ..............................................65 Power Train 3 Index Specifications General Tightening Torques General tightening torque for bolts, nuts and taperlock studs The following charts give the standard torque values for bolts, nuts and taperlock studs of SAE Grade 5 or better quality. Exceptions are given in other sections of the Service Manual where needed. thread size inches 1/4 5/16 3/8 7/16 1/2 9/16 5/8 3/4 7/8 Use these torques for bolts and nuts with standard threads (Conversions are approximate) 1 1-1/8 1-1/4 1-3/8 1-1/2 standard thread Use these torques for bolts and nuts on hydraulic valve bodies. Use these torques for studs with taperlock threads. taperlock stud standard torque lbIft 9L3 18 L 5 32 L 5 50 L 10 75 L 10 110 L 15 150 L 20 265 L 35 420 L 60 640 L 80 800 L 100 1000 L 120 1200 L 150 1500 L 200 NIm* 12 L 4 25 L 7 45 L 7 70 L 15 100 L 15 150 L 20 200 L 25 360 L 50 570 L 80 875 L 100 1100 L 150 1350 L 175 1600 L 200 2000 L 275 5/16 3/8 7/16 1/2 5/8 13 L 2 24 L 2 39 L 2 60 L 3 118 L 4 20 L 3 35 L 3 50 L 3 80 L 4 160 L 6 1 5 3 7 1 9 5 3 7 5L2 10 L 3 20 L 3 30 L 5 40 L 5 60 L 10 75 L 10 110 L 15 170 L 20 260 L 30 320 L 30 400 L 40 480 L 40 550 L 50 7L3 15 L 5 30 L 5 40 L 10 55 L 10 80 L 15 100 L 15 150 L 20 230 L 30 350 L 40 400 L 40 550 L 50 650 L 50 750 L 70 1 1-1/8 1-1/4 1-3/8 1-1/2 *1 newton meter(NIm) is approximately the same as 0.1 mkg. Power Train 5 Specifications Metric fasteners metric ISO thread [Usually, material strength identification on bolt head is with numbers (i.e., 8.8, 10.9, etc.)] The chart on the right gives the torque for bolts and nuts with Grade 8.8. NOTICE : Caution must be taken to avoid mixing metric and standard (customary) fasteners. Mismatched or incorrect fasteners can result in vehicle damage or malfunction, or possible personal injury. Original fasteners removed from the vehicle should be saved for assembly when possible. If new ones are required, caution must be taken to replace with one that is of same part no. and grade or better. thread size (mm) (NIm)* M6 M8 M10 M12 M14 M16 M18 M20 M22 M24 M27 M30 M33 M36 12 L4 25 L7 55 L10 95 L15 150 L20 220 L30 325 L50 450 L70 600 L90 775 L100 1150 L150 1610 L200 2000 L275 2700 L400 torque (lbIft) 9 L3 18 L5 40 L7 70 L10 110 L15 160 L20 240 L35 330 L50 440 L65 570 L75 840 L110 1175 L150 1450 L200 2000 L300 ISO-International Standard Organization Hose clamps-worm drive band type intitial assembly torque on new hose clamp width (NIm)* 13.5 mm (.531 inch) 7.5 L0.5 4.5 L0.5 7.9 mm (.312 inch) 0.9 L0.2 15.9 mm (.625 inch) (lbIft) 65 L5 40 L5 8 L2 reassembly or retightening torque (NIm)* 4.5 L0.5 3.0 L0.5 0.7 L0.2 (lbIft) 40 L5 2 L5 6 L2 *1 newton meter(NIm) is approximately the same as 0.1 mkg. Power Train 6 Specifications Drive Motor (36V) 2 1 (48V) 2 1 Power Train 7 Specifications Drive Motor 1 Model BxxT-2 Voltage 36V 48V New Brush Thickness B Width B Length 2 Minimum New Commutator Brush Length* Diameter 12.5 mm B 32 mm B 35 mm (.49 in. B 1.25 in. B 1.37 in.) 18 mm (.70 in.) 80 mm (3.14 in.) Minimum Commutator Diameter** 78 mm (3.07 in.) *As measured on longest side. **All rough edges (burrs) must be removed after the commutator is machined. Machine chamfer on the commutator bars ...................................................... 0.40 mm (.016 in.) Maximum difference between commutator high and low point (out of round) ......... 0.03 mm (.001 in.) TIR Torque for the terminal bolts (not shown) that hold cable connections ............................. 12 NIm (9 lbIft) Maximum difference between bar to bar .......................................... 0.005 mm (.0002 in.) TIR Depth of the insulation below commutator bars .......................................................... 1.5 mm (.05 in.) Thermal switch Opening temperature.......... 155 L 4°C (311 L 10°F) Width of the insulation below commutator bars ........................................................ 0.8 mm (.031 in.) Power Train Closing temperature ........... 145 L 6°C (293 L 11°F) 8 Specifications Final Drive B15T-2, B18T-2, B20T-2(36V) IHPS002S (1) Tightening bolt. (2) Socket head bolt. (3) Tightening nut. (4) Hexagon bolt. (5) Plug. A. Clearance. (4) Torque for hexagon bolt that hold spring holder and disk carrier .......................... 34 NIm (25 lbIft) (1) Torque for bolt that hold wheel shaft ................................................. 9.6 NIm (7.1 lbIft) (5) Torque for fluid filling plug........... 22 NIm (16 lbIft) (2) Torque for socket head bolt that hold toothed disk ................................................... 67 NIm (49 lbIft) (6) Gear ratio.................................................. 18.2 : 1 (3) Torque for nut that hold motor shaft ....................................................55 NIm (41 lbIft) (A) Brake lever setting clearance ................................... 0.4~1.0 mm (.016~.039 in) Power Train 9 Specifications B13T-2, B15T-2, B18T-2, B20T-2(48V) 5 1 0 E 2 3 9 11 4 E 6 7 8 10 E E (1) Nut. (2) Flat head bolt. (3) Socket head loolt. (4) Socket head bolt. (5) Socket head bolt. (6) Air breather. (7) Socket head bolt. (8) Plug-oil level. (9) Plug. (10) Drain plug. (11) Socket head bolt. (1) Apply LOCTITE NO.277 (or 271) Thread Lock to thread of nut. Torque for nut that holds drive shaft ............................. 200 L 20 NIm (148 L 15 lbIft) (2) Apply LOCTITE NO.277 (or 271) Thread Lock to threads of bolts. Torque for flat head bolts that hold end plate ....................................8 L 3 NIm (5.9 L 2.2 lbIft) (3) Apply LOCTITE NO.277 (or 271) Thread Lock to threads of bolts. Torque for socket head bolts that hold carrier cover .............................30 L 7 NIm (22 L 5 lbIft) (4) Apply LOCTITE NO.277 (or 271) Thread Lock to threads of bolts. Torque for socket head bolts that hold ring gear stopper plate ...............55 L 10 NIm (41 L 7 lbIft) Power Train (5) Apply LOCTITE NO.277 (or 271) Thread Lock to threads of bolts. Torque for socket head bolts that hold housing ......................................25 L 7 NIm (18 L 5 lbIft) (6) Torque for air breather 70 L 10 NIm (52 L 7 lbIft) (7) Apply LOCTITE NO.277 (or 271) Thread Lock to threads of bolts. Torque for socket head bolts that hold housing ......................................30 L 7 NIm (22 L 5 lbIft) (8) Apply LOCTITE NO.572 to thread of oil level plug. Torque for plug ............70 L 10 NIm (52 L 7 lbIft) (9) Torque for plug that holds piston rod ....................................70 L 10 NIm (52 L 7 lbIft) (10) Apply LOCTITE NO.572 to thread of drain plug. Torque for plug ..........70 L 10 NIm (52 L 7 lbIft) (11) Apply LOCTITE No.277 (or 271) Thread Lock to thread of socket head bolt. Torque for bolt that holds nut ...................................8 L 3 nIm (5.9 L 2.2 lbIft) 10 Specifications Wheel Mounting B15T-2, B18T-2, B20T-2(36V) 1 2 IHPS003S (1) Nut. (2) Bolt. (1) Torque for drive wheel mounting nut ............................................... 180 NIm (133 lbIft) (2) Torque for bolt that hold housing to frame ............................................... 135 NIm (100 lbIft) Power Train 11 Specifications B13T-2, B15T-2, B18T-2, B20T-2(48V) 2 1 IOPS002I (1) Nut. (2) Bolt. (1) Torque for drive wheel mounting nut ............................................... 180 NIm (133 lbIft) (2) Torque for bolt that hold housing to frame ............................................... 200 NIm (148 lbIft) Power Train 12 Specifications Motor and Transmission B15T-2, B18T-2, B20T-2(36V) 2 1 4 3 IHPS004S (1) Lock nut. (2) Screw. (3) Hexagon screw. (4) Motor (1) Torque for nut that hold drive pinion to drive motor shaft ............................................ 55 NIm(41 lbIft) (2) Torque for screw that hold transmission and drive motor ........................................... 23 NIm(17 lbIft) (3) Torque for hexagon screw that hold transmission and drive motor ........................... 23 NIm(17 lbIft) (4) Axial run-out of the motor mating serface relative to the motor shaft ...............not to exceed 0.04mm (0.0015 in) Power Train 13 Specifications B13T-2, B15T-2, B18T-2, B20T-2(48V) 1 IOPS003I (1) Socket head bolt (1) Torque for socket head bolts that hold transmission and drive motor ..... 55 NIm (41 lbIft) Power Train 14 Specifications Brake B15T-2, B18T-2, B20T-2(36V) Actuating stroke for the hand brake cable a. in the operating condition b. limit of wear 120˚ dia. 3 M 10 B 1 10 77 1 54 a 5.7 12.2 b 2 3 All dimensions in mm IHPS005S (1) Bleeder valve. (2) Brake line (hydraulic line). (3) Brake cable. (a) In the operating condition. (b) Limit of wear. (1) Torque for bleeder valve ............. 50 NIm (37 lbIft) (2) Torque for brake line................... 50 NIm (37 lbIft) (3) Torque for brake cable................ 50 NIm (37 lbIft) (a) Stroke in the operating condition .................................................... .22 in (5.7 mm) (b) Limit of wear............................ 0.48 in (12.2 mm) Power Train 15 Specifications B13T-2, B15T-2, B18T-2, B20T-2(48V) Actuating stroke for the hand brake cable a. in the operating condition b. limit of wear 1 2 3 mm (1) Bleeder port. (2) Brake line (hydraulic line). (3) Brake cable. (a) In the operating condition. (b) Limit of wear. (1) Torque for bleeder port ............... 50 NIm (37 lbIft) (2) Torque for brake line................... 50 NIm (37 lbIft) (3) Torque for brake cable................ 50 NIm (37 lbIft) (a) Stroke in the operating condition ........................................3 ~ 5 mm (0.12~0.20 in) (b) Limit of wear ...................................8 mm (0.31 in) Power Train 16 Specifications Systems Operation General Information 2 1 IOPS005S Power Flow (1) Final drive. (2) Drive motor. The power train for the BT-2 MODEL Lift Trucks consist of two main components; drive motors (2) and final drives (1). Electric storage batteries are used as a power source for the drive motors (2). The drive motor turns final drive (1), which turn the drive wheels. Power Train 17 Systems Operation Drive Motor (36V) 2 3 1 6 5 7 4 8 3 (48V) 2 9 1 4 10 6 5 7 8 Drive Motor (1) Input gear. (2) Brush cover. (3) Thermal switch (thermostat). (4) Commutator. (5) Armature. (6) Field coils. (7) Frame. (8) Brush holder. (9) Fan. (10) Bearing. Power Train 18 Systems Operation Drive motor is protected from overheating by a thermal switch (thermostat) (3). The thermal switch opens at 154 L 4°C (311 L 10°F). It closes at 145 L 6°C (293 L 11°F). When the normally closed thermal switch is open, the amount of current through the motor is limited to allow the motor to cool. The motor has a fan for cooling. The drive system is operated by a direct current (DC)motor. Electric storage batteries are the source of power for the DC motor. The drive motor is a series wound motor and uses a high temperature insulation. The field and armature circuits are in series, which provides a single path for the current. Armature (5) is mounted with single row ball bearings at each end. The ball bearings are permanently lubricated with a high temperature lubricant. The drive motor is activated when the parking brake is released, the key and seat switch are closed, a direction is selected and the accelerator pedal is depressed. The electrical connections to the motor are made at corrosion resistant terminals on motor frame (7). On the outside of the motor frame is the brush cover (2) that can be removed for easy access to the brushes and the commutator. Field coils (6) are fastened to the inside of the motor frame. The drive motor powers the power transfer group through input gear (1). The four motor brushes are held in four brush holders (8). A spring holds each of the brushes against commutator (4) as the brushes wear. Power Train 19 Systems Operation Final Drive B15T-2, B18T-2, B20T-2(36V) 1 11 3 4 6 10 7 5 2 11 9 8 12 IHPS008S (1) Transmission housing. (2) Drain plug. (3) Breather. (4) Wheel shaft. (5) Helical gear. (6) Drive pinion. (7) Friction disc carrier. (8) Planetary gear. (9) Planetary carrier. (10) Internal gear. (11) Brake lever. (12) Friction and steel disc. When motor shaft turns, the helical pinion(6) connected on the motor shaft turns helical gear(5). Helical gear(5) is jointed to sun gear of planetary gear set and the sun gear turns three planetary gears(8). Three planetary gears turn planetary carrier which is inserted into inner hole of planetary gears(8). The planetary carrier is connected to wheel shaft(4) and wheel shaft turns rim mounted on wheel shaft flange. This transmission is a helical and planetary gear transmission unit with an integrated, hydraulically and mechanically actuated wet disk brake. This transmission consists of two assembly groups. 1. Helical gear transmission with connection for electric motor and helical gear step. 2. Basic transmission with planetary step, gear shaft and integrated brake. Power Train When hydraulic pressure is supplied to the cylinder of brake lever(11), the brake lever push parallel pin that is contacted on the end of brake lever(11). The wet disc brake is actuated by the force from parallel pin. The brake lever can be moved by cable mechanically as same as hydraulically for parking brake actuation. 20 Systems Operation B13T-2, B15T-2, B18T-2, B20T-2(48V) 6 11 7 8 1 12 2 3 10 E 4 5 5 10 13 15 9 E E E 14 (1) Pinion gear. (2) Helical gear. (3) Friction disc carrier. (4) Steel ball. (5) Lever plate. (6) Ring gear. (7) Planetary gear. (8) Drive shaft. (9) Planetary carrier. (10) Brake cylinder. (11) Transmission housing. (12) Air breather. (13) Piston rod. (14) Drain plug. (15) Friction and steel plate. When motor shaft turns, the helical pinion(1) connected on the motor shaft turns helical gear(2). Helical gear(2) is jointed to sun gear of planetary gear set and the sun gear turns three planetary gears(7). Three planetary gears turn planetary carrier which is inserted into inner hole of planetary gears(7). The planetary carrier is connected to drive shaft(8) and drive shaft turns rim mounted on drive shaft flange. This transmission is a helical and planetary gear transmission unit with an integrated, hydraulically and mechanically actuated wet disk brake. This transmission consists of two assembly groups. 1. Helical gear transmission with connection for electric motor and helical gear step. 2. Basic transmission with planetary step, gear shaft and integrated brake. Power Train When hydraulic pressure is supplied to the brake cylinder(10), piston rod(13) rotates lever plate(5). As the lever plate is contacted to steel ball (4), it is moved towards friction and steel plates(15) by rotation. Then wet disc brake is actuated by this force. The lever plate can be moved by cable mechanically as same as hydraulically for parking brake actuation. 21 Systems Operation Testing And Adjusting WARNING If an electrical failure or an overload of the motor is present, personnel must not breathe the toxic fumes which are a product of the burnt insulation. All power must be disconnected from the motor before any inspection is made to find the failure. The area around the motor must be well ventilated (air flow) and the motor is to be cooled before any repair work is done. Water must not be used on any electrical equipment because of the danger of electric shock. If a fire is present, disconnect the electrical power and use a carbon dioxide extinguisher to put the flame out. Troubleshooting Visual Checks Make a visual inspection of the truck to check for problems. Operate the truck in each direction. Make a note of the noises that are not normal and find their source. If the operation is not correct, make reference to the Check List During Operation for "Problems" and "Probable Causes". Do not operate the drive motors without a load, as too much speed may cause damage to the motor and injury to personnel. Checks During Operation Drive Motor Problem 1 : Drive Motor Will Not Operate. Before an analysis is made of any electric drive motor problem, always make reference to the Troubleshooting section of the MicroController System Operation module. probable Cause : 1. Switch not closed (battery connector, key switch, seat switch, direction switch or parking brake switch) : Close the switch. If it still does not operate test for power to the control panel and power flow through each switch with a voltmeter. But the service brake switch should be opened. WARNING The lift truck can move suddenly. Battery voltage and high amperage is present. Injury to personnel or damage to the lift truck is possible. Safely lift both drive wheels off the floor. Put wood blocks or jack stands of the correct capacity under the frame so the drive wheels are free to turn. During any test or operation check, keep away from the drive wheels. The head capacitor (HEAD CAP) will have to be discharged before any contact with the control panel is made. Disconnect the battery and discharge the HEAD CAP. Rings, watches and other metallic objects should be removed from hands and arms when troubleshooting the MicroController Control System. To prevent personal injury, never use air pressure that is more than 205 kPa (30 psi), and wear protective clothing and a face shield. 2. Bad connection. Fuse blown : Check battery connections. Check connections at battery connector. Check fuses, drive and logics. Replace fuse if blown. Check the Drive motor and control panel for possible reasons for a blown fuse. Some causes are : a. Operation under excessive transistor load, too high current limit (C/L). b. Operation under stall conditions. c. Possible short circuit in drive motor, see Probable Causes 5, 6 and 7. 3. Low battery voltage: Check battery terminal voltage. If too low, charge the battery. Check all the cells for one or more that have defects. Check the specific gravity of each cell. The maximum density difference from the highest to the lowest cell must not be more than .020 SG (specific gravity). NOTICE To prevent damage to electrical components, make sure the air line is equipped with a water filter when they are cleaned with air. 4. Control panel operation not correct : See the MicroController System Operation module. Power Train 22 Testing And Adjusting Problem 3 : Neither traction or hydraulic will last through a complete normal work period. 5. Brushes are worn: Inspect the drive motor commutator for burnt marks or scoring (scratches). Make corrections or make a repair of the armature commutator and replace the brushes as necessary. See Armature Commutator Inspection and Brush Inspection in Testing And Adjusting. Make reference to Problem: Sparks At The Commutator And/Or Rapid Brush Wear. Probable Cause : 1. Too small a battery equipped in the lift truck : Use a larger battery for the complete work cycle and normal work period. 2. Battery not being fully charged or equalized during the battery charging operation : Check the battery cells for an equalization charge(a charge to make the specific gravity the same in all cells). Check the battery charger for defects. 6. Check for open circuits in the field coils : Test coils according to procedures in Testing And Adjusting. If there are open circuits, make a replacement of the field assembly. 7. Check for a short circuit in the armature windings : Loose field winding pole ends, make the necessary repairs. Failed armature bar insulation. Repair or rebuild the insulation or make a replacement of the armature. 3. Battery change interval is too long or changed battery cooling time is too short. This decreases the capacity and the ability of the battery : Decrease the battery work duration before a change. Increase the battery cooling time after a charge before it is put to use. 8. Static return to off circuit (S.R.O.) actuated: If the static return to off is activated, the control will not start again until the accelerator is released and the directional control lever is returned to neutral. 4. Battery has one or more defective cells which results in less than the rated capacity and ability of the battery : Replace the battery. 5. Traction system draws (makes a consumption of) too much battery power because of traction system faults. Operation of the duty cycle (complete working cycle) condition is not correct : Check the brake adjustment according to the procedures in Testing And Adjusting in the Vehicle Systems module. Check the mechanical components such as wheel bearings, axles, etc., for corrections to eliminate the faults. Change to a tire with less friction. Problem 2 : Traction will not operate through a normal work period, but hydraulic operation is normal. Probable Cause : 1. Brakes have a defect, cause a resistance(lack of free movement). Heat increases, which causes the motor to stall : Check the brake adjustment according to the procedures in Testing And Adjusting in the Vehicle Systems module. 6. Hydraulic system draws too much battery power because of lifting and tilting arrangements, or hydraulic conditions are not correct for the duty cycle: Decrease hydraulic relief valve setting to the capacity that only will be used. Change to a smaller hydraulic pump. Check the mast for restriction during operation. 2. Too much heat in MicroController control panel because: a. Extra heavy traction loads. Decrease the duty cycle load. b. Faulty thermal switch. See the MicroController System Operation module. c. Too high current limit (C/L) setting. Lower the setting on the C/L adjustments. 7. Lift truck working more than the capacity of its design with no available power after one work shift : Have available an extra (exchange) battery. Decrease the speed and work load required to complete the work shift. These can cause transistors to become defective, control panel failure or drive fuse to go bad. Power Train 23 Testing And Adjusting Compare spring force with a new brush spring. Check the brush holder for oversize (larger size than for brush). Replace the brush spring if necessary. Problem 4 : Sparks at the commutator and/or rapid brush wear. Probable Cause : d. Loose brush leads or motor bus bar connections. Loose cable connections at motor terminals. Results are : 1. Worn brushes: Replace the brushes. See New Brush Installation And Brush Inspection in Testing And Adjusting. 2. Overheating (too much heat) of the traction motor : Check for an overload motor or a motor with defects. See Armature Commutator Inspection in Testing And Adjusting. Decrease the current limit (C/L) adjustmemts if set too high. See the MicroController System Operation module. Test the plugging rate, if set too short it will cause arcing and wear at the brushes. The duty cycle is too heavy, change the duty cycle. (1) High resistance and heating. 3. Defective drive motor : See Armature Commutator Inspection in Testing And Ajusting. f. Possibly heavy working condition that causes too much motor heat and rapid brush wear: Make a replacement of the brushes and make sure the brushes are seated. See New Brush Installation and Brush Inspection in Testing And Adjusting. Check the brush springs for the correct installation and for the correct spring usage. Too strong a spring rate will increase current draw and brush wear rate. Prevent operation in stall condition. Excessive (too much) duty cycle which increases motor temperatures and rapid brush wear. (2) Faster brush wear. Check brushes for tight connections. Replace the brushes if leads are loose in brush material. Check all cable and wire connections for tightness. e. Wrong grade of brushes installed that are not adaptable to the motor : Make sure all the brushes are of DAEWOO standards. Do not use other brands of brushes. a. Commutator bars burnt in two or more positions at 180° apart because: (1) Armature bars open. Replace the armature. (2) Motor was stalled against a heavy load while power discharged and caused the two bars, in contact with the brushes, to burn. 4. Overload of the drive motor such as: towing, constant ramp operation, chiseling (hydraulic actions that are not practical) and dragging (pull or push loads on the ground) : Operator training for better working practices. Add an auxiliary cooling to the drive motors. NOTICE Too heavy a load can stall the motor, and result in a failure to the drive motor. (3) Short circuit in the armature. See Armature Tests in Testing And Adjusting. 5. Current limit (C/L) set too high that causes too much current consumption through motors in the transistor range : Decrease the current limit (C/L) adjustment to the correct setting, see the MicroController System Operation module. (4) Armature not in balance, out of round, off center or with high commutator bars. This causes the brushes to bounce (move up and down). Make sure the diameter is the same all the way around and is in center line with the shaft. See Specifications. 6. Drive motor, armature or field windings have a defect that results in high current draw at low torque output: See Armature Tests and Field Coil and Terminal Tests in Testing And Adjusting. b. Dirty motor that has a metallic or carbon dust. This dust is a conductor which causes electrical shorts, increase current draw and decrease drive motor output : Remove any dirt with air pressure. 7. Restriction caused by components : Correct and make adjustments to wheel brakes and parking brakes that drag. Changes to tire with less friction. Check and correct wheel bearing torques. c. Brush movement causing arcing and brush wear: Check the brush springs for cracks, and overheat signs (blue). Power Train 24 Testing And Adjusting Problem 5 : Low resistance to ground [battery polarity either positive (+) or negative (–) or a medium voltage is in direct contact with truck frame (body) or drive motor body]. Problem 7 : Lift truck moves faster in one direction than the other direction with the same amount of accelerator pedal movement in Bypass mode (speed). Probable Cause : Probable Cause: 1. Dirty battery, electrolyte on top of cells and is in contact with the frame. Current flows through battery box, which places a voltage on the truck frame : Clean the battery with baking soda and water solution. 1. Motor brushes not located in the correct electrical position (brush neutral settings) : If the holes in the brush holder are not extended, make them longer so that brush holder can have a little rotation. When the holder is in the correct position, lift truck speed will be the same in both directions. 2. Battery or control panel wire connections in contact with truck frame : Make a continuity test and move the wire from contact. Remove wires in sequence until the fault is cleared. The fault will be in the wire last disconnected. 2. One directional contactor worn more than the other or loose connection on one contactor : Check contactor for wear and tighten any loose connections. Problem 8 : Lift truck will not get to top speed. 3. Dirty motor : Remove metallic or carbon dust with air pressure. Probable Cause : 1. Battery not fully charged or battery has bad cells : Charge the battery. Check for bad cells. Replace battery if necessary. 4. Wet motor : To dry the motor, heat it to 90°C (194°F). 2. A fault either in the drive motor, control panel or drive train : Check lift truck speed in both directions. If the MicroController control panel needs to be tuned up, make adjustments as shown in the respective MicroController System Operation module. If the drive motor is at fault, make the tests of the motor components in Testing And Adjusting. Problem 6 : Commutator surface has grooves or abnormal wear. Probable Cause : 1. Brushes are worn too low, brush wires caused arcing on the commutator : Replace the brushes. See Brush Inspection in Testing And Adjusting and the method to make the Brush Life Estimate in Testing And Adjusting. Problem 9 : Lift truck does not have enough power to position itself under a load. Lift truck does not have enough power on ramps or towing trailers. 2. Dirty motor ; and possibly salt water got inside : Disassemble motor, remove the debris with air pressure. If necessary, dry the motor with heat to 90°C (194°F). Probable Cause: 3. Grades of brushes mixed : Make sure all the brushes are of DAEWOO standards. Do not use other brands of brushes. Power Train 1. Current limit (C/L) set too low : Set current limit (C/L) to specification in the MicroController System Operation module. 2. Current limit (C/L) circuit has a defect : Test the MicroController control panel as stated in the respective service module. Repair or replace components as necessary. 3. Unpolished or improperly positioned forks : Install tapered and polished forks. Position forks correctly for load being lifted. 4. Lift truck equipped with tires that have poor traction : Install tires that have good traction per recommendation from DAEWOO Inc. 25 Testing And Adjusting 5. Lift truck work load is too heavy or the duty cycle too long : Decrease the work load and/or duty cycle. Problem 5 : Long brake pedal stroke. Problem 10 : Lift truck has slow acceleration. Probable Cause: 1. Excessive lining wear : Check the stroke of brake piston rod. Keep the stroke within 3~5 mm by adding shim. 1. Drive control overheated and the thermal switch opens : 2. Failure of brake master cylinder : Change the seals in the brake master cylinder. NOTE : The lift truck will still go into the bypass mode, but current limit will be cut back in the transistor mode if the thermal switch opens. Allow the MicroController control panel to cool so the thermal switch will close. Problem 6 : Decreased oil level in brake oil reservoir or leakage through brake piston rod. Probable cause : Probable cause : 1. Damage on seals of brake piston rod : Change the quad ring, back up ring and wear rings on piston rod. NOTE : The thermal switch will open if the temperature is 150 L 6°C (302 L 11°F) and close at 130 L 7°C (266 L 13°F). 2. Scratch on brake piston bore : Replace transmission housing cover with new one. Transmission Problem 7 : Noise during brake application. Problem 1 : Abnormal movement of drive shaft to axial direction. Probable cause : 1. Using wrong transmission oil specification : Check the transmission oil with specified one and keep the drain interval. Probable cause : 1. Lock nut loosening : Check if lock nut and socket head bolt for stopping lock nut are loosened. Tighten lock nut and socket head bolt with Loctite No.277. 2. Insufficient soaking hour of friction discs. After a few days, problem will disappear. Problem 8 : Poor brake performance. Problem 2 : Rattle noise during coasting and cornering. Probable cause : Probable cause : 1. Abnormal wear on tire tread : Change tires with new tires. Rattle noise could be improved by change tires left and right each other. 1. Damaged brake friction disc and steel plate by excessive heat : Check if parking cable is released. Change friction discs and steel plates. Keep the drain interval of transmission oil. Problem 3 : Gear noise during driving. Problem 9 : Leakage from drive shaft. Probable cause : Probable cause : 1. Damaged tooth or excessive wear of bearing : Check gears and bearings and change the damaged gear and bearing of excessive wear. Keep the oil drain interval and use specified oil. 1. Faulty oil seal of drive shaft : Check oil seal and drive shaft for damages in the sealing area. Problem 10 : Transmission overheats. Problem 4 : Leakage through air breather. Probable cause : Probable cause : 1. Transmission oil level is either too high or too low : Check oil level. 1. Excessive oil level : Check the oil level and keep the specified oil level. 2. Failure of air breather : Change air breather with new one. Power Train 2. Wheel bearings with an excessive prestress : Check rolling torque of drive shaft. 26 Testing And Adjusting Drive Motor Motor Brushes Brush Inspection 1. Measure the radial length of brush. 1 P0004332 Install Brushes (1) Brushes. NOTICE Installation of the wrong brushes can cause early motor failure. Always make sure the correct DAEWOO brushes are installed. P0004329 Brush Measurement 5. Install new brushes(1). Make sure the brushes move freely in the brush holders. Use a piece of plain bond paper to remove brush material if there is a restriction of brush movement. 2. If the brush length is less than 18 mm (.7 in) on the longest side, replace the brushes. New Brush Installation NOTE : Installation of new brushes is a two person operation. 2 1. Disconnect the batteries. 2. Lift the truck and put blocks under the chassis it so that the drive wheels are off the ground. 3. Discharge the head capacitor. P0004331 4. Remove the brush covers. Loosen two screws of the brush and BWI wires. Pull out the old brushes from the brush holder by lifting up the brush springs. Install Springs (2) Spring. 6. Place carefully the brush spring(2) on the top of brush and make sure they fasten into the brush holder box. 7. Pull up on the two wires of each brush until the contact end of the brush moves away from the commutator. Release the wires to see if the brush moves smoothly back into contact with the commutator. If it is too difficult to pull out, or it does not move smoothly in the brush holder box, remove the spring and brush. Make an inspection to find and correct the cause of the problem. 8. Connect the batteries to the battery connector. Power Train 27 Testing And Adjusting WARNING NOTICE Never use air pressure that is more than 205 kPa (30 psi). Make sure the line is equipped with a water filter. Wear eye protection when seating, polishing or cleaning the motor with air pressure. During the seating and polishing procedure, keep fingers away from components in rotation. For prevention of injury to fingers, do not use a commutator cleaner or brush seater stone that is shorter than 63.5 mm (2.50 in.). 12. After the brushes have the correct seat contact surface, operate the motor at slow speed. Use compressed (pressure) air to remove all dust and abrasive grit. Armature Tests Tools Needed 3 A Digital Multimeter Or Equivalent 1 Growler Tester 1 Test For Short Circuit P0004333 1 4 5 Brush Seating (3) ZLX –0036 Brush seater stone. 9. Put ZLX–0036 Brush Seater Stone (3) on the commutator and operate the motor at a slow speed. NOTICE Do not let stone(3) stay in contact with the commutator bar too long. This causes more wear than is necessary to the brushes and the commutator. P0004322 3 2 Short Circuit Test (1) Glowler. (2) Armature. (3) Hacksaw blade. (4) Green light. (5) Red light. 10. Move stone (3) across the commutator at the backe edge of the brushes for a short time. This will take the shiny finish off the commutator and seat the new brushes. 1. Turn the growler (1) on. 11. Turn the key switch to the OFF position and disconnect the batteries. Check the contact surface of each brush. At least 85% of the brush contact surface of each brush must show wear. If necessary, do Steps 8 through 11 again until the correct wear can be seen on the brush contact surface. 3. If the windings are shorted, the green light (4) will be on. The red light (5) will be on if the windings do not have a short. Power Train 2. Slowly turn the growler on the armature (2) while a hacksaw blade (3) is held over the windings. The odor of burned insulation from the drive motor while it is in operation is an indication of a short in the armature. 28 Testing And Adjusting Open Circuit Test Ground Test A P0004321 P0004320 Ground Test. Open Circuit Test (1) Armature. (A) Multimeter. A digital multimeter can also be used to test for grounds. Put the Function/Range Switch on the 2M resistance (A) scale. When the test probes are put on the commutator and the shaft, the meter must give an indication of over load (OL). This means that the resistance is more than 2 megohms. 1. Put the digital multimeter Function / Range Switch on the 200 ohm resistance (A) scale. 2. Put one test lead on one commutator bar. Put the other test lead on an adjacent (next to) bar and there must be less than one ohm resistance. This test can also be done with an instrument, such as a Kelvin Double Bridge, that can make a measurement of very low resistance. Do the test the same as above and make a comparison of the resistance measurements. NOTICE Never use air pressure that is more than 205 kPa (30 psi). Make sure the air line has a water filter. Two burned areas on opposite sides of the commutator are indications of an open armature winding. These burned areas can cause very rapid brush wear. If there is an indication of a ground in the above test, remove any dirt or debris form the armature with compressed (pressure) air. Do the test for grounds again. If there is still an indication of a ground, make a replacement of the armature. Power Train 1 29 Testing And Adjusting Commutator Inspection Surfaces of Commutators that need Replacement IHPS010P Grooves on the Commutator Surface IHPS008P Grooves on the commutators surface are caused by a cutting material in the brush or atmosphere. Marks on the Commutator Surface Marks on the commutator surface are an indication that metal has moved from the commutator surface to the carbon brushes. Marks will cause fast brush wear. IHPS011P Copper Drag on the Commutator Surface Copper drag is an extra amount of commutator material at the back edge of the commutator bars. IHPS009P Threads on the Commutator Surface Threads (grooves that look like threads) on the commutator surface, will also cause fast brush wear. Power Train 30 Testing And Adjusting Ground Test 1 P0004328 2 Ground Test (1) Field Terminal. (2) Motor housing. IHPS012P Pitch Bar–Marks on the Commutator Surface 1. Put the digital multimeter Function/Range Switch on the 20M resistance (A) scale. Pitch bar–marks cause low or burnt marks on the commutator surface. 2. Put one test lead to either outer field terminal (1) and the other test lead to the motor housing (2). There must be more than one megohm resistance. Field Coil and Terminal Tests Tools Needed Digital Multimeter Or Equivalent 3. If there is a measurement of less than one megohm, it can be caused by wet insulation on the field windings or excessive brush dust in housing. Heat the motor at 88°C (190°F) until the resistance goes above one megohm. If the resistance does not go above one megohm, the shell and field assembly must be replaced. A 1 Open Circuit Test P0004327 Open Circuit Test 1. Put the digital multimeter Function/Range Switch on the 200 ohm resistance (A) scale. 2. Put one test probe to each outer field terminal (S1,S2). 3. The resistance must be less than one ohm. If the resistance is too high, it is an indication of corrosion on the terminals or an open field coil. Power Train 31 Testing And Adjusting 1. Put the digital multimeter Function/Range Switch on the 20M resistance (A) scale. Armature Terminal Test Tools Needed A Digital Multimeter Or Equivalent 2. Put one test lead to an outer Armature terminal (1) and the other test lead to the motor housing (2). There must be more than one megohm resistance. 1 Test for Continuity 3. Do the test again with one test lead on the other outer brush terminal. 1 Brush Holder Test Tools Needed Digital Multimeter Or Equivalent A A 1 1 EX00005 Brush Test (1) Test lead. 1. Put the digital multimeter Function/Range Switch on the 200 ohm resistance (A) scale. 2 2. Put one test lead to an outer Armature terminal (1) and the other test lead to each brush lead that connects to that terminal. There must be less than one ohm resistance. P0004319 Brush Holder Test (1) Brush holder. (2) End bell. (A) Multimeter. 3. Do Step 2 again with the other outer Armature terminal (A1, A2) and brush leads. 1. The brush holders are mounted on the rocker at the commutator end of the motor. Make a visual inspection of the brush holders and the rocker. 4. Too much resistance is an indication of corrosion at the connection to the terminal. 2. Put digital multimeter Function/Range Switch (A) on the 200 ohm resistance (A) scale. Put one test lead to a brush holder (1) and the other test lead to the end bell (2). The meter must show overload (OL). Ground Test 1 3. Check each brush holder. If meter reading is low, the brush holder is grounded. Replace the rocker. 2 EX00006 Ground Test (1) Armature terminal. (2) Motor housing. Power Train 32 Testing And Adjusting Thermal Switch Tests Tools Needed Digital Multimeter Or Equivalent Brush Life Estimate 1. Before installation of new brushes, make an inspection of the armature commutator, see Armature Commutator Inspection in Testing and Adjusting. A 1 2. Do the steps and procedures for New Brush Installation in Testing and Adjusting. Open Circuits Test 3. Make the initial (first) inspection of brush wear between 250 smh and 500 smh. The reason for this initial inspection is to see if the brush wear rate is normal and not too fast. The measurement will help make an estimate of the length of brush life to be expected. NOTE : If there is an indication that brush wear is too fast, see Troubleshooting, Problem: Sparks at the commutator and/or rapid brush wear; for probable causes of this problem. P0004325 Open Circuit Test 4. Inspect all brushes in the motors. Measure and record each brush length (see Specification for each new brush length and minimum brush length). 1. Put the digital multimeter Function/Range Switch on the 200 ohm resistance (A) scale. 2. Put one test lead to each side of the thermal switch harness. 5. Estimate expected brush life (hours). Use the shortest measurement from Step 4 and the following Sample Procedure: 3. The resistance must be less than one ohm. Length of new brush...................35 mm (1.387 in.) Minimum length of brush..............18 mm (.708 in.) New brush length [35 mm (1.387 in.)] – Minimum brush length [18 mm(.708 in.)] = Total amount of usable brush wear [17 mm(.67 in.)]. Ground Test Length of shortest brush at 500 smh is 32.5 mm (1.279 in.). New brush length [35 mm (1.378 in.)] – Length of shortest brush at 500 smh [32.5 mm (1.279 in.)] = Amount of brush wear at 500 smh [2.5 mm (.10 in.)]. 1. Put the digital multimeter Function/Range Switch on the 20M resistance (A) scale. Amount of brush wear at 500 smh [2.5 mm (.10 in.)] ÷ Total amount of usable brush wear [17 mm (.67 in.)] = Portion of brush used at 500 smh (.1). Service Meter Hours (smh) at brush wear measurement (500 smh) ÷ Portion of brush used (.1) = Approximate total brush life of a new brush (5000 smh). 2. Put one test lead to either of the plug prongs. The other test lead must be grounded to the motor housing. There must be more than one megohm resistance. Approximate total brush life of a new brush (5000smh)–Amount of smh at brush life estimate (500 smh) = Remainder of usable brush life (4500 smh). P0004326 Ground Test Power Train 33 Testing And Adjusting 6. The smh estimate of brush life can be used if the machine is to work at the same rate (duty cycle), the battery is not discharged too much or the battery cells have not become damaged. If the machine is made to work harder, the battery is discharged too much, or the battery cells become damaged, the motor temperature will get hot very fast. This will cause rapid wear of the brush. 5. Place the motor carefully on the transmission and join the gearings of motor pinion and helical gear carefully. WARNING Do not knock with the drive pinion against the helical gear while installing the motor. This can cause knocking noise. 7. It is important to check brush length and brush condition at a specific time, such as during the preventive maintenance check. If an inspection shows that brush life will not extend to the next preventive maintenance check, install new brushes. NOTE : When joining the gearings, turn the motor shaft carefully until the drive pinion engages into the helical gear. Motor and Transmission 6. Turn motor so that bore pattern of transmission lines up with that of motor. B15T-2, B18T-2, B20T-2(36V) IHPS009S IHPS010S (1) Motor shaft. (2) Drive pinion. (3) Woodruff key. (4) Nut. (5) O–ring. (1), (2) Hexagon bolts. 1. Clean motor shaft (1) and taper bore of drive pinion (2) carefully with Loctite No. 706. 7. Screw motor and transmission together with three hexagon bolts (1) and (2). Tighten the bolts to a torque of 23 NIm (17 lbIft) NOTICE The taper connection must be free from grease and oil. Note faultless seat of the taper connection 2. Insert woodraff key (3) into motor shaft and push drive pinion on. 3. Screw a new lock nut (4). Tighten the nut to a torque of 55 NIm (41 lbIft). 4. Coat O–ring (5) slightly with transmission fluid and push it onto centering seat of motor. Power Train 34 Testing And Adjusting B13T-2, B15T-2, B18T-2, B20T-2(48V) Motor Transmission Unit and Vehicle Frame 1 B15T-2, B18T-2, B20T-2(36V) All dimensions in mm max. motor dia. 225mm max. motor dia. 210mm 7 hexagon bolts M14 3 2 R37 A .5 .92 min 5˚ 5˚L A=4 A Min. Sparing of frame for brake lever Installation position, differences must be approved IOPS003I (1) Socket head bolt. (2) Drive motor. (3) Transmission 1. Place the drive motor (2) carefully on the transmission (3) and join the gearings of motor spline and pinion gear carefully. Check the frame surface for damage and irregularities. The maximum admissible irregularity in the area of the transmission contour is 0.10 mm (.004 in). Screw drive unit with 7 hexagon bolts and shims to the vehicle frame. Tightening the bolts to a torque of 135 NIm (100 lbIft). NOTE : When joining the splines, turn the motor shaft carefully until the motor spline engages into the pinion gear. 2. Turn motor so that bore pattern of transmission lines up with that of motor. The fitting angle influences strongly the quantity of fluid which can be filled into the transmission as well as the maintenance procedure. There are 2 oil filling and draining plugs (A) in the housing. The fluid filling hole defines the fluid level (overflow). Remove the plug which is at lowest level for draining the fluid. 3. Screw motor and transmission together with three socket head bolts (1). Tighten the bolts to a torque of 55 NIm (41 lbIft). Power Train 35 Testing And Adjusting Brake B13T-2, B15T-2, B18T-2, B20T-2(48V) 10 7 1 Actuating stroke for the hand brake cable a. in the operating condition b. limit of wear 120˚ Actuating stroke for the hand brake cable a. inthe operating condition b. limit of wear dia.3 M10 X 1 B15T-2, B18T-2, B20T-2(36V) 54 a 5.7 12.2 b 2 1 3 2 3 All dimensions in mm IHPS005S (1) Bleeder valve. (2) Brake line (hydraulic line). (3) Brake cable. (a) In the operating condition. (b) Limit of wear. 14mm a(3~5mm) b(8mm) Connecting the hydraulic brake system Connect the bleeder valve (1) to the top threaded hole and the brake line (hydraulic line) (2) to the bottom threaded hole according to the assembly position. Tightening torque of bleeder valve (1) and brake line (2) is 50 NIm (37 lbIft). When placing the hydraulic lines, the bending radii should be kept as large as possible to keep the resistance against the restoring forces for lifting the brake as small as possible. 4 (1) Bleeder port. (2) Brake line (hydraulic line). (3) Brake cable. (4) Shim. (a) In the operating condition. (b) Limit of wear. Connecting the hydraulic brake system Connect the bleeder tube to the bleeder port (1) and the brake line (hydraulic line) (2) according to the assembly position. Tightening torque of bleeder port (1) and brake line (2) is 50 NIm (37 lbIft). Connecting the brake cable Screw the brake cable (3) into the third threaded hole to a torque of 50 NIm (37 lbIft). Connecting the brake cable Check and maintain the installation dimensions when the installation has been finished Screw the brake cable (3) to a torque of 50 NIm (37 lbIft). Check and maintain the installation dimensions when the installation has been finished. If the measured value is larger than installation dimension, insert shims (4) in the shown location to meet installation dimension. Power Train 36 Testing And Adjusting Replenishing With Transmission Fluid B15T-2, B18T-2, B20T-2(36V) B13T-2, B15T-2, B18T-2, B20T-2(48V) Approx. 0.5L 0.3 5L 1 2 3 2 1 EHPS018B (1) Filling plug. (2) Sealing ring. IOPS006I Use a funnel with a hose for easier filling. Maximum outside diameter of hose to be 13mm (.52 in). The correct fluid level and amount of fluid has been reached when the level can be seen at the opening. When filling the fluid in, make sure that no air bubbles are formed in the transmission. Turn the wheel shaft to remove them. (1) Air breather. (2) Sealing washer. (3) Oil level plug. Loosen air breather (1). Use a funnel with a hose for easier filling. Maximum outside diameter of hose to be 10mm (0.4 in). The correct fluid level and amount of fluid has been reached when the level can be seen at hole for oil level plug (3). When filling the fluid in, make sure that no air bubbles are formed in the transmission. Turn the wheel shaft to remove them. Screw the fluid filling plug (1) with the sealing (2). Tighten the plug to torque of 22 NIm (16 lbIft). Bleed the brake system after filling of brake fluid. Refer to Brake System Air Removal of Lift Trucks Vehicle System. Screw the air breather (1) with the sealing washer (2). Tighten the air breather to torque of 70 L 10 N•m (52 L 7 lbIft). Apply LOCTITE No.572 to thread of drain plug (3) and tighten to a torque of 70 L 10 N•m (52 L 7 lb•ft). Bleed the brake system after filling of brake fluid. Refer to Brake System Air Removal of Lift Trucks Vehicle System. Power Train 37 Testing And Adjusting Drive Axle 6 B15T-2, B18T-2, B20T-2(36V) 5 Disassemble Drive Axle Tools Needed A Gear puller (3”) 1 8 Start By : IHPD003P 7 a. Remove drive axle. 3 4. Disassemble the brake lever assembly (3) as follows : a. Remove cap (5) from the brake lever. b. Remove brake piston (6) from the brake lever. c. Check the condition of sealing ring (7). If they are worn or damaged, replace with new one. d. Remove spring (8). 1 2 10 9 IHPD001P 1. Remove two snap rings (1) and parallel pin (2) from brake lever. 2. Remove brake lever assembly (3) from the cover. IHPD004P NOTE : Before unscrewing the countersunk bolts (9) slight impacts on them are necessary to loosen the Loctite-connection. 4 5. Remove eight screws (9). Remove gear and housing cover assembly (10) from drive axle housing. 6. Check the condition of shaft seal and replace with new one if needed. IHPD002P 3. Remove pin (4) from the cover assembly. Power Train 38 Disassembly And Assembly 10 11 12 17 IHPD005P IHPD008P 7. Remove six bolts (11) and spring holder (12) from gear and housing cover assembly (10). 10. Carefully extrat the helical gear (17) together with the bearing from the cover seat by using 2 jackbolts. 14 18 13 15 IHPD006P IHPD009P 8. Remove three springs (13), internal disk carrier (14) and pressure disk (15). 11. Remove axial-friction bearing (18). NOTICE Avoid any damages of the bearing surface and notice the direction for reassembly. 16 IHPD007P 9. Remove snap-ring (16) located on the cover seat. Power Train 39 Disassembly And Assembly 19 20 IHPD010P 21 IHPD013P 15. By using a copper pin and a hammer drive out the wheel shaft of the housing together with the inner taper bearing ring and remove. 12. Remove four outer disks (19), three inner disks (20) and pressure disk (21) from internal gear. 22 25 IHPD011P IHPD014P 13. Carefully pull the three planet gears (22) with tool (A). Be sure to pull off the planet gears (22) complete with the bearing. 16. Remove the planetary carrier (25) together with the inner race of tapered roller bearing from the housing. NOTE : Check the condition of needle bearings and replace with new ones if needed. 27 24 23 26 IHPD015P IHPD012P 17. Remove ten bolts (26) from toothed disk. 18. Remove internal gear assembly (27). The internal gear (27) needs to be disassembled or assembled only if the teeth are damaged. For this reason, this operation will not be dealt with at greater length in the section describing the assembly. 14. Fix the wheel shaft to avoid its turning. Loosen the four bolts (23) and the disk (24) from the wheel shaft. Power Train 40 Disassembly And Assembly 29 34 36 35 30 37 27 28 IHPD016P IHPD019P 22. Remove NILOS-ring (34) and GAMMA-ring (35) from the housing. 19. Disassemble the internal gear assembly (27) as follows: a. Remove FEY-ring (28) from the internal gear. b. Remove snap-ring (29) and toothed disk (30) from the internal gear. 23. Remove cup bearing (36) and shims from the housing. 24. Remove Lip-seal (37) from the housing. 25. Check the conditions of ring and seal. Assemble Drive Axle Tools Needed Fitting Punch Peening Punch Dial Gauge 31 A B C 1 1 1 NOTE : Before the assembly, carry out the following operations : IHPD017P a. Thoroughly clean all parts and remove all residual Loctite. b. Check all the parts for wear and damage.Replace, if necessary. c. Finish the mating surface of sealing with an oil stone or a fine finishing file. d. Lubricate the cleaned antifriction bearings before installing. e. Be sure to replace all the sealing elements. f. Be sure to use mastic sealants (such as Loctite) only. 20. Remove cup bearing (31) from the housing. 32 33 WARNING IHPD018P Make sure corrosive detergents do not come in contact with the skin. Do not swallow them or inhale their vapors. Be sure to wear protective gloves and goggles. If any detergent has been accidentally swallowed, seek medical attention immediately. Scrupulously observe the manufacturer’s instructions. 21. Remove cone bearing (33) from the wheel shaft assembly (32). Power Train 41 Disassembly And Assembly 33 32 IHPD018P 1. Install cone bearing (33) onto the wheel shaft assembly (32). 29 30 IHPD001S 5. For preadjustment insert the disassembled set of shims (1) into the bearing seat again. By means of a copper pin drive the outer race(2) into the bearing seat of housing. Make sure outer race has even contact with shims. Repeat same procedure on opposite side of housing. 27 28 IHPD016P 2. Put the teethed disk (30) into the intenal gear and install snap ring (29) that hold teethed disk (30) on interal gear. NOTE : 1) Do not use damaged shims. 2) Do not install the radial shaft seal ring between the tapered roller bearings before bearing adjustment. 3. Install FEY-ring (28) onto the internal gear. 38 27 26 IHPD020P IHPD015P 6. place the preassembled wheel shaft (38) onto the outer race of bearing in the housing. Secure the wheel shaft against sliding and turning. 4. Put the internal gear assembly (27) into the housing and install bolts (26) that hold internal gear assembly (27) in the housing NOTE : Be sure to secure the bolts (26) with Loctite No.243 and torque them to 67 N•m (50 lb•ft). Power Train 42 Disassembly And Assembly 36 34 35 37 IHPD021P IHPD019P 7. The planetary carrier will be carefully contrived into the teethed wheel shaft bore. Drive the planetary carrier by means of a copper mandrel to seat. 11. Install new wheel shaft oil seal (37) into the housing. 12. Install cup bearing (36) and shims into the housing. NOTE : Make sure to apply LOCTITE 270 onto the internal teeth of the planetary carrier after pretensioning. 13. Install NILOS-ring (34) and GAMMA-ring (35) on the housing. 32 24 23 IHPD018P IHPD012P 8. Insert the disk (24) into the bore of the planetary carrier. Wheel shaft, planetary carrier and disk will be fitted together by screwing the four hexagonal bolts (23). Use the torque of 9.6 NIm (7.1 lbIft). 14. Lubricate the wheel shaft assembly (32) by applying Shell-Alvania R3 grease to the inner ring of taper roller bearing and the space between the rollers. NOTE : Tighten the hexagonal bolts evenly and crosswise! 9. Turn the wheel shaft repeatedly to permit taper rollers in the bearing inner races. The bearing pretention should be 0.025 to 0.075 mm(0.001 to 0.003 in). There must be no measurable bearing clearance. But it should be possible to turn the shaft by hand. The correct pretension is obtained by a friction moment of 4.5 to 6.5 NIIm (3.3 to 4.8 lbIIft). NOTE : If the friction moment is not within the specified range, the adjustment needs to modify. Therefore it is necessary to reduce or to increase the thickness of the shim set. 10. When the required adjustment is obtained, dismount the wheel shaft and the outer race of bearing again to assemble the sealing ring. Power Train 43 Disassembly And Assembly 24 23 25 IHPD014P IHPD012P 15. Lubricate the planet carrier (25) by applying sheel-Alvania R3 grease to the inner ring of taper roller bearing and the space between the rollers. 17. Put the planetary carrier (25) on the wheel shaft assembly (38). Screw wheel shaft and planetary carrier with the disk (24) by using the four bolts (23). Tighten the bolts evenly and crosswise. 38 22 IHPD020P IHPD023P 16. Join the preassembled wheel shaft assembly (38) to the outer ring of the taper roller bearing of the housing. Make sure that the wheel shaft assembly (38) can not slide away or rotate. 18. Position the planet gear (22) straight on the axle stub of the planet carrier, making sure the gear (22) is not tilted. Then use Tool (A) to press the gear (22) down until it sits on the abutment. NOTICE Be sure to employ Loctite No.270 when mounting the planet carrier (25) on the wheel shaft assembly (38). Loctite No.270 may be applied to the internal teeth of the planet carrier (25) only. NOTICE Pay attention to the correct fitting position of the planet gear (22). Make sure that the radius of inner ring rests on the axle stub abutment. 19. Apply the same procedure for two remaining planet gears (22). Power Train 44 Disassembly And Assembly Step1 •If the set need to be changed due to wear, use the old pressure disk (21) furthermore. •Insert the disks as follws : -pressure disk (21). -external disk (19), internal disk (20), ext. disk, int. disk, ext. disk, int. disk and at the end again an external disk. 22 Radius IHPD005S IHPD002S 20. Secure the three planet gears (22) against slipping by using Tool (B). For this purpose, widen the rim of the pocket hole until the inner bearing ring of the planet gears (22) can no longer be moved. The sinusoidal internal disks need to be aligned in a way that ensures opposite waviness. The alignment with the help of an internal disk carrier which is not used for installation, constitutes a fast and accurate method for this purpose. 19 14 20 IHPD010P 21 21. The assembly of the disk set needs the following two steps. IHPD003S Put the internal disk carrier (14) into the proper fitting position. Turn several times the internal disk carrier very carefully to permit the disks to the final position. Now carefully remove the internal disk carrier from the fitting position. In doing so, make sure that the position of the disks is unaltered. Power Train 45 Disassembly And Assembly <Table 1> Step2 Dimension Z Pressure disk thickness C 5.58 to 6.10 4.8 mm 6.10 to 6.70 5.3 mm 6.70 to 7.22 5.8 mm The required dimension C for example above is 4.80 mm 15 18 2 IHPD009P IHPD004S 22. Install the axial-friction bearing (18) into the housing cover. If more parts need to be changed e.g.the ring gear, then it is necessary to find the correct thickness of the pressure disk (21) by following steps. NOTE : Pay attention to the correct fitting position of the axial-friction bearing (18). This method is to be used for calculating the required thickness of the pressure disk (21) Dimension X = Distance between plain surface of the cover flange to the plain surface of the pressure disk (15). Dimension Y = Thickness of the complete disk set. Dimension W = calculated by following formula W=X+Y Dimension V = Distance between plain surface of housing and contact surface of pressure disk (21) in the ring gear Dimension Z = calculated by following formula Z=V-W 16 17 IHPD007P 23. Slide the helical gear (17) onto the bearing seat of cover and secure it with the snap-ring (16). Example : X=23.23mm measured at the cover surface Y=12.6mm measured thickness of disk set W=23.23+12.60=35.83mm V=41.93 mm measured at housing surface Z=41.93mm-35.83mm=6.10mm In table 1 the thickness of the washer will be shown in relation to the dimension Z Power Train 46 Disassembly And Assembly 14 10 9 15 13 IHPD006P IHPD004P 24. Fit the pressure disk (15) on the helical gear. 28. Put the cover (10), assembled as a complete unit, on an even surface and apply Loctite No.574 onto the sealing surface of the cover. 25. Fit the internal disc carrier (14) on the helical gear and insert three compression springs (13) into the holes of the internal disc carrier. NOTE : Due to the transmission contours, the sealing surface of the cover is quite irregular. The impression of the old sealing surface visible on the cover during the disassembly process can be very helpful in this respect. 11 29. Drive the cover (10) into the basic transmission unit. For this purpose, move the cover lightly and tap on it with a plastic hammer. 12 30. Use Loctite No. 243 to secure the countersunk bolts (9) employed to fasten the cover (10) and torque them to 9.6 NIm (85 lbIin). IHPD005P 6 26. Position the spring holder (12) on the internal disk carrier and align it with the gearing, making sure that the holder (12) does not interfere with the cover assembly operation. 5 27. Use Loctite No. 243 to secure the bolts (11) employed to fasten the internal disc carrier and torque them to 34 NIm (25 lbIft). 8 IHPD003P 7 31. Assemble the brake lever assembly (3) as follows : a. Put the spring (8) into the piston (6). b. Install the piston (6) with sealing ring (7) into the brake lever. c. Install the cap (5) onto the brake lever. Power Train 47 Disassembly And Assembly 4 IHPD002P 32. Install the pin (4) into the cover assembly. IHPD007S 4 1 Dimension for Assembly 0.4+0.6 (Dim.A) IHPD028P 3 d. After lever mounting check the dimension “A” and adjust if necessary. The dimension “A” needs to be between 0.4-1.0mm. Check the dimension by using a dial gauge. Therefore adjust the lever gauge to the specified measuring point on the head of the brake lever, and “0” indication gauge. Move the lever smoothly against the cover by hand. Read the dial gauge. The measured value is the dimension “A”. If the adjustment is not in accordance with the specified value, the thrust pin (4) needs to be changed or shortened. Therefore different pins are available. If the pin needs to be changed, the brake lever will be disassembled again. 2 IHPD006S 33. Install the brake lever assembly (3) as follows : a. Insert the brake lever assembly (3) into the cover mount. Pay attention to the correct fitting position. b. Drive in the straight pin (2) and the brake lever (3) simultaneously into the mount. c. Secure the straight pin with the two snap rings (1) to ensure that the straight pin cannot slip out of the mount. Power Train After the brake lever has been assembled, check the dimension again in the same steps as described above. 48 Disassembly And Assembly 1. Remove drain plug (1), oil level plug (2), air breather (3) and washer (4). B13T-2, B15T-2, B18T-2, B20T-2(48V) Disassemble Drive Axle Tools Needed A B T126 Nut lnstaller 1 Bearing Puller 1 6 5 Start By : a. Remove drive axle. IOPD004P 2. Remove snap ring (5) from housing cover (6). 1 IOPD001P IOPD005P 7 8 9 3. Remove four socket head bolts (7) and ten socket head bolts (8) from housing (9). 10 2 3 4 IOPD002P 10 IOPD006P 2 1 4 3 4. Using two M8 bolts (10), remove housing assembly from housing cover assembly. IOPD003P Power Train 49 Disassembly And Assembly 11 6 IOPD007P 5. Remove pinion gear assembly (11) from housing cover (6). 16 9 IOPD010P 7. Remove helical gear assembly (16) from housing (9). 17 12 15 18 19 13 IOPD008P 5 12 13 14 14 15 19 IOPD009P IOPD012P 20 17 18 8. Remove snap rings (17), (18) and sun gear (19) from helical gear (20). 6. Remove ball bearing (12), thrust bearing (14) and race ring (15) from pinion gear (13). Power Train 20 IOPD011P 50 Disassembly And Assembly 21 22 23 6 IOPD013P IOPD017P 23 22 26 26 23 21 IOPD014P IOPD018P 11. Remove three guide washers (23) and steel plate (26). 9. Remove three flat head bolts (21), end plat (22) and three guide washers (23) from housing cover (6). 24 25 26 27 6 6 IOPD015P IOPD019P 25 24 IOPD016P 26 IOPD020P 10. Remove three springs (24), five friction discs (25) and four steel plate (26) from housing cover (6). Power Train 29 28 27 12. Remove plug (27), return spring (28) and piston rod (29) from housing cover (6). 51 Disassembly And Assembly 41 40 30 31 IOPD021P 6 IOPD024P 15. Remove five steel balls (40) and ball bearing (41) from housing cover (6). 30 42 43 31 IOPD022P 13. Remove lever plate (30) and lever hook (31). IOPD025P 16. Remove six socket head bolts (42) from carrier assembly (43). 31 32 42 29 38 44 33 34 IOPD023P 35 36 37 39 14. Remove pin (32) and split pin (33) from lever hook (31). Remove wear rings (34), (39), backup rings (35), (38) and quad rings (36), (37) from piston rod (29). Power Train IOPD026P 17. Remove carrier cover (44) using three socket head bolts (42). 52 Disassembly And Assembly 49 44 45 IOPD027P 52 IOPD030P 50 18. Remove ball bearing (45) from carrier cover (44). 46 50 47 51 IOPD031P IOPD028P 20. Remove socket head bolt (49). 21. Remove nut (50) and shims (51) by using tool (A). And, remove carrier (52) from housing. 48 47 53 46 52 IOPD029P 19. Remove six race rings (46), three planet gears (47) and three needle roller bearings (48). IOPD032P 22. Remove taper roller bearing cone (53) from carrier (52) by using tool (B). Power Train 53 Disassembly And Assembly 55 52 53 61 60 54 IOPD059P IOPD035P 23. Remove pins (54) and spring pins (55) from carrier (52). 26. Remove twelve socket head bolts (60) from ring gear (61). 63 9 62 61 56 IOPD033P IOPD036P 24. Remove drive shaft assembly (56) from housing (9). 63 62 58 59 57 IOPD037P 61 27. Remove snap ring (62) and stopper plate (63) from ring gear (61). 25. If necessary, remove taper roller bearing cone (58) and eight wheel bolts (59) from drive shaft (57). Power Train 54 Disassembly And Assembly Assemble Drive Axle 9 Tools Needed A T127 Bearing Installer B T130 Needle Bearing Installer T126 Nut Installer IOPD038P 65 67 E F 1 T129 Gamma Seal Installer 68 D 1 T128 Oil Seal Installer 64 C 1 1 1 T131 Bolt Installer 1 NOTE : Before the assembly, carry out the following operations : 66 a. Thoroughly clean all parts and remove all residual Loctite. b. Check all the parts for wear and damage. Replace, if necessary. c. Finish the mating surface of sealing with an oil stone or a fine finishing file. d. Lubricate the cleaned antifriction bearings before installing. e. Be sure to replace all the sealing elements. f. Be sure to use mastic sealants (such as Loctite) only. 9 IOPD039P 28. Remove taper roller bearing cups (64), (65), gamma seal (66) and oil seal (67) from housing (9). WARNING 29. Remove needle roller bearing (68) from housing (9). Make sure corrosive detergents do not come in contact with the skin. Do not swallow them or inhale their vapors. Be sure to wear protective gloves and goggles. If any detergent has been accidentally swallowed, seek medical attention immediately. Scrupulously observe the manufacturer’s instructions. Power Train 55 Disassembly And Assembly 58 65 67 66 59 9 57 IOPD039P 1. Install taper roller bearing cone (58) by using tool (A). Apply Total MULTIS EP2 grease to the inner ring of taper roller bearing and the space between the rollers. 4. Apply Three Bond No.1102 on outer race of oil seal (67) and install oil seal into housing (9) by using tool (B). Apply grease on the rib of oil seal (67). 2. Install eight wheel bolts (59) into drive shaft (57). 5. Apply Three Bond No.1102 on inner race of gamma seal (66) and install gamma seal onto housing (9) by using tool (C). Apply grease on the rib of gamma seal (66). 54 55 6. Install taper roller bearing cup (65) into housing (9). 52 53 9 IOPD040P P0004209 3. Install pins (54) and spring pins (55) into carrier (52). Install taper roller bearing cone (53) onto carrier (52) by using tool (A). Apply Total MULTIS EP2 grease to the inner ring of taper roller bearing and the space between the rollers. IOPD038P 64 68 7. Install taper roller bearing cup (64) into housing (9). Install needle roller bearing (68) into housing (9) by using tool (D). Power Train 56 Disassembly And Assembly 9 50 54 56 IOPD041P 52 51 IOPD043S 8. Assemble drive shaft assembly (56) and housing (9). 10. To calculate the required thickness of shim pack (51), the following method is to be used. Dimension B = Distance between plain surface of carrier (52) and the plain surface of drive shaft (54). Dimension C = Hight of step in nut (50). IOPD042P 9 Dimension D = Required thickness of shim pack(51), calculated by following formula D=B-C-(0 ~ 0.05 mm) 52 9. Assemble carrier (52) into housing (9). Example: B = 2.58 mm measured at carrier and drive shaft C = 2.05 mm measured at nut D = 2.58 - 2.05 - (0 ~ 0.05) = 0.48 0 ~ 0.53 (mm) Then 0.5 mm thickness of shim pack can be applied. NOTE: Before determination of the shim pack thickness, to locate the taper roller bearing of drive shaft assembly in proper location, tighten the nut (50) to a torque of 80~110 NIm (59~81 lbIft) with rotating drive shaft assembly by hand. Power Train 57 Disassembly And Assembly 50 IOPD044P 50 52 52 IOPD044P 14. Remove nut (50) from carrier (52). 11. Install shim pack with the proper thickness which was determined in step 10. Tighten nut (50) to a torque 150~220 NIm (110~162 lbIft) by using tool (E). 60 12. Check if the slot in nut (50) for stopping socket head bolt is well aligned with tap in carrier (52). If not, the carrier should be rotated by one or two splines in step 17. 61 62 54 IOPD036P 15. Assemble stopper plate (61) and snap ring (60) into ring gear (62). IOPD045P 62 13. Measure rolling torque of drive shaft assembly (54). The specification of rolling torque is 4.5~6.5 NIm (3.3~4.8 lbIft). If the measured rolling torque value is out of the specification, increase or decrease the shim pack thickness and follow the procedure in steps 11 through 13. 58 9 IOPD033P 16. Install ring gear assembly (62) into housing (9). Apply LOCTITE No. 277 on threads of twelve socket head bolts (58) and tighten bolts to a torque 55 L 10 NIm (40.6~7.4 lbIft). Power Train 58 Disassembly And Assembly 49 44 45 IOPD030P 52 50 IOPD027P 20. Install ball bearing (45) into carrier cover (44). 17. Apply LOCTITE No. 277 on thread of nut (50) and tighten nut to a torque 150~220 NIm (110~162 lbIft) by using tool (E). 42 43 18. Apply LOCTITE No. 277 on thread of stopping socket head bolt (49) and tighten bolt to a torque 8 L 3 NIm (59 L 2.2 lbIft). 48 IOPD025P 47 21. Apply LOCTITE No. 277 on threads of six socket head bolts and tighten bolts to a torque of 30 L 7 NIm (22 L 5 lbIft) 46 IOPD029P 46 47 IOPD046P IOPD028P NOTE : Carrier cover (44) should be assembled so that marks on carrier and carrier cover are aligned. 19. Assemble six race rings (46), three needle roller bearings (48) and three planet gears (47). Power Train 59 Disassembly And Assembly 31 32 30 29 38 31 33 34 IOPD023P 35 36 37 39 IOPD022P 22. Assemble pin (32) and split pin (33) into lever hook (31). Split pin (33) should be bent enough not to be removed. 23. Assemble quad rings (36), (37), backup rings (35), (38) and wear rings (34), (39) into piston rod (29). 33 30 NOTE: Apply brake oil (Total AZOLLA ZS 10) on the surface of six rings in piston rod. Check the location of backup rings carefully. 6 31 IOPD021P 41 25. Install lever plate (30) and lever hook assembly (31) into housing cover (6). NOTE: The split pin (33) of lever hook assembly should be located on top side as shown. 40 IOPD024P 6 29 24. Install ball bearing (41) into housing cover (6). Install five steel balls (40). Apply Total MULTIS EP2 grease on the surface of steel balls. IOPD047P 26. Assemble piston rod assembly (29) to lever hook (31). Power Train 60 Disassembly And Assembly 25 24 IOPD020P 28 29 27 26 IOPD016P 24 25 26 27 IOPD019P IOPD015P 27. Apply total MULTIS EP2 grease onto outer of piston rod (29). 30. Install five firiction discs (25) and four steel plate (26) one by one as shown. Install three springs (24). 28. Install return spring (28) into housing cover and tighten plug (27) to a torque of 70 L 10 NIm (52 L 7 lbIft). 23 NOTE : Before installation of friction discs, soak those friction discs in transmission oil as much time as possible. If possible, over 12 hours are recommended. 26 23 IOPD017P IOPD048P 29. Install steel plate (26) and three washers (23) onto housing cover as shown. 31. Put three guide washers (23) carefully on three springs as shown. NOTE: Locate guide washers carefully on the positions of three taps in housing cover. Power Train 61 Disassembly And Assembly 19 21 22 IOPD049P IOPD012P 32. Put end plate (22) carefully on washers. Apply LOCTITE No.277 on threads of three flat head bolts (21) and tighten bolts to a torque of 8 L 3 NIm (5.9 L 2.2 lbIft) by using tool (F). 20 18 17 17 18 22 22 19 20 IOPD011P 66 34. Assemble sun gear (19), snap ring (18) and snap ring (17) into helical gear (20). Make the opening directions of two snap rings opposite. IOPD050I 33. Press end plate (22) and measure the distance (L) between the surface of end plate and the surface of housing cover (6). Specification for “L” is 1.03 ~1.63 mm (0.041~ 0.064 in). 20 6 IOPD051P 35. Align the teeth of the friction discs and assemble carefully helical gear assembly (20) into housing cover (6). Power Train 62 Disassembly And Assembly 13 5 IOPD052P IOPD004P 36. The housing cover areas must be cleaned and degreased. Apply Three Bond No.1215 to coat on one side as shown. 39. Install pinion gear assembly (13) into housing cover and assemble snap ring (5). 2 3 4 IOPD002P IOPD005P 7 9 8 40. Apply LOCTITE No. 572 on thread of oil level plug (2) and tighten plug to a torque of 70 L 10 NIm (52 L 7 lbIft). 37. Put housing assembly (9) on housing cover assembly. Apply LOCTITE No. 277 on threads of four socket head bolts (7) and ten socket head bolts (8). Tighten them to torque of 25 L 7 NIm (18 L 5 lbIft) for four bolts (7) and 30 L 7 NIm (22 L 5 lbIft) for ten bolts (8). 12 IOPD008P 41. Install washer (4) and air breather (3) and tighten air breather to a torque of 70 L 10 NIm (52 L 7 lbIft). 15 13 14 38. Assemble ball earing (12) onto pinion gear (13). Apply Total MULTIS EP2 grease to thrust bearing (14) and race ring (15) and assemble them onto pinion gear (13). Power Train 63 Disassembly And Assembly 1 IOPD001P 42. Apply LOCTITE No. 572 on thread of drain plug (1) and tighten plug to a torque of 70 L 10 NIm (52 L 7 lbIft). End By: a. Install drive Axle. Power Train 64 Disassembly And Assembly Special Service Tools B13T-2, B15T-2, B18T-2, B20T-2(48V) Ref. No Tool Name 1 Nut Installer Illustration Remark DAEWOO Tool No: T126 IOPD053I DAEWOO Tool 2 No: T127 Bearing Installer IOPD054I DAEWOO Tool 3 Oil seal Installer No: T128 IOPD055I DAEWOO Tool 4 Gamma Seal Installer No: T129 IOPD056I Power Train 65 Disassembly And Assembly Ref. No Tool Name 5 Needle Bearing Installer Illustration Remark DAEWOO Tool No: T130 IOPD057I 6 DAEWOO Tool Flat Head Bolt Installer No: T131 IOPD058I Power Train 66 Disassembly And Assembly SB4113E00 Sep. 2003 Specifications Systems Operation Testing & Adjusting Lift Trucks Vehicle Systems B15T-2, B18T-2, B20T-2(36V) EMOD4-00001~UP EMOD5-00001~UP EMOD6-00001~UP B13T-2, B15T-2, B18T-2, B20T-2(48V) EMOFB-00001~UP EMOFC-00001~UP EMOFD-00001~UP EMOD7-00001~UP Important Safety Information Most accidents involving product operation, maintenance and repair are caused by failure to observe basic safety rules or precautions. An accident can often be avoided by recognizing potentially hazardous situations before an accident occurs. A person must be alert to potential hazards. This person should also have the necessary training, skills and tools to perform these functions properly. Improper operation, Iubrication, maintenance or repair of this product can be dangerous and could result in injury or death. Do not operate or perform any Iubrication, maintenance or repair on this product, until you have read and understood the operation, Iubrication, maintenance and repair information. Safety precautions and warnings are provided in this manual and on the product. If these hazard warnings are not heeded, bodily injury or death could occur to you or other persons. The hazards are identified by the "Safety Alert Symbol" and followed by a "Signal Word" such as "WARNING" as shown below. WARNING The meaning of this safety alert symbol is as follows : Attention! Become Alert! Your Safety is Involved. The Message that appears under the warning, explaining the hazard, can be either written or pictorially presented. Operations that may cause product damage are identified by NOTICE labels on the product and in this publication. DAEWOO cannot anticipate every possible circumstance that might involve a potential hazard. The warnings in this publication and on the product are therefore not all inclusive. If a tool, procedure, work method or operating technique not specifically recommended by DAEWOO is used, you must satisfy yourself that it is safe for you and others. You should also ensure that the product will not be damaged or made unsafe by the operation, Iubrication, maintenance or repair procedures you choose. The information, specifications, and illustrations in this publication are on the basis of information available at the time it was written. The specifications, torques, pressures, measurements, adjustments, illustrations, and other items can change at any time. These changes can affect the service given to the product. Obtain the complete and most current information before starting any job. DAEWOO dealers have the most current information available. Vehicle Systems 1 Specifications Index Specifications Testing & Adjusting Dual Steer Axle And Wheel .....................................12 Brake System ..........................................................45 Brake System Air Removal.................................45 Parking Brake Control Group Adjustment ..........47 Parking Brake Test .............................................46 Pedal Adjustment................................................46 Hydraulic Pump Motor .............................................47 Armature Tests .............................................49(54) Brush Holder Test.........................................52(57) Brush Lift Estimate .......................................52(58) Commutator Inspection ................................50(55) Field Coil And Terminal Tests .......................51(57) Motor Brushes ..............................................47(53) Thermal Switch (Themostat)Tests ......................58 Hydraulic Control Vavel .............................................5 Hydraulic Pump .........................................................6 Hydraulic Pump Motor .............................................13 Lift Cylinders ..............................................................7 Standard ...............................................................7 Full Free Triple Lift And Full Free Lift Primary......7 Full Free Lift Secondary .......................................8 Full Free Triple Lift Secondary .............................8 Priority Valve............................................................10 Hydraulic System.....................................................41 Lift Cylinders Air Removal ..................................42 Relief Valve Pressure Check ..............................41 Sideshift Cylinder.......................................................6 Steer Axle And Wheel..............................................12 Steering Gear...........................................................11 Steering Wheel ........................................................10 Steering System ......................................................43 Steer Wheel Bearing Adjustment .......................43 Steering System Air Removal.............................43 Steering System Pressure Check ......................44 Tilt Cylinder ................................................................9 Systems Operation Troubleshooting .......................................................31 Brake System .....................................................36 Electric Motors ....................................................37 Hydraulic System And Mast ..............................31 Steering System .................................................35 Visual Checks .....................................................31 Brake System ..........................................................27 Master Cylinder...................................................27 Electric Motor...........................................................29 Hydraulic Pump Motor ........................................29 Hydraulic System.....................................................14 Control Valve ......................................................16 Steering System ......................................................23 Hydraulic Operation ............................................23 Steering Unit .......................................................24 Vehicle Systems 3 Index Specifications Hydraulic Control Valve 3 2 1 3 IHCS101S Control Valve Model Mast B13T-2 STD B15T-2 FFL B18T-2 Current Draw/Volt Main Relief Valve Auxiliary Relief Valve Amps/36(Ref.) Amps/48(Ref.) Pressure Pressure Min Max - - 360 380 Min 310 Max 330 FFLT B20T-2 L 350 kPa L 35 psi 15580 2260 17170 2490 19440 2820 21575 3130 L 350 kPa L 35 psi 14000 2025 (1) Torque for nuts that hold control valve sections together ......26 to 32 N•m (19 to 23 lb•ft) (2) Torque for nuts that hold control valve sections together ......24 to 29 N•m (18 to 21 lb•ft) (3) Torque for main and auxiliary relief valve ...................................44 to 49 N•m (32 to 36 lb•ft) Vehicle Systems 5 Specifications Hydraulic Pump Sideshift Cylinder 1 2 EHCS002B EHCS003B Rotation is counterclockwise when seen from drive end. (1) Torque for head ..............................270 L 35 N•m (200 L 25 lb•ft) Type of pump : Gear (2) Torque for piston nut ......................260 L 25 N•m (190 L 20 lb•ft) Displacement : 16 cc/rev Vehicle Systems 6 Specifications Lift Cylinders Full Free Triple Lift and Full Free Lift Primary Standard 1 1 (1) Put Pipe Sealant on the last three threads of bleed screw and tighten to a torque of .......................................6 L 1 N•m (53 L 9 lb•in) (1) Put Pipe Sealant on the last three threads of bearing. Put Pipe Sealant of the last three threads of bleed screw(not shown) and tighten to a torque of .............................................6 L 1 N•m (53 L 9 lb•in) NOTE : All seals to be lubricated with hydraulic oil. NOTE : All seals to be lubricated with hydraulic oil. Vehicle Systems 7 Specifications Full Free Lift Secondary Full Free Triple Lift Secondary 1 1 2 2 (1) Put Pipe Sealant on the last three threads of bearing. (1) Put Pipe Sealant on the last three thread of bearing. (2) Put Pipe Sealant on the last three threads of bleed screw and tighten to a torque of .......................................6 L 1 N•m (53 L 9 lb•in) (2) Put Pipe Sealant on the last three thread of bleed screw and tighten to a torque of .......................................6 L 1 N•m (53 L 9 lb•in) NOTE : All seals to be lubricated with hydraulic oil. NOTE : All seals to be lubricated with hydraulic oil. Vehicle Systems 8 Specifications Tilt Cylinder 1 2 3 4 Z X-closed, Y-open EHCS008B Tilt Angle Degrees Tilt Group Cyl. Closed – X Cyl. Open – Y Stroke – Z Forward Backward mm in mm in mm in A155007 5° 7° 382 15.0 463 18.2 81 3.2 A155008 5° 5° 396 15.6 463 18.2 67 2.6 A155009 5° 3° 409 16.1 463 18.2 54 2.1 (1) Adjust pivot eye to dimension(Y) with cylinder open(extended) (2) Torque for bolt .................................. 95 L 15 N•m (70 L 10 lb•ft) (3) With mast at tilt back position shim as required to permit no gap between eye(1) and spacer. Torque for head .... 270 L 35 N•m (200 L 25 lb•ft) (4) Torque for jam nut .............................. 260 L 25 N•m (190 L 20 lb•ft) Vehicle Systems 9 Specifications Steering Wheel Priority Valve 1 2 EHCS017 Flow ................................Load sensing closed center. EHCS016B (1) Torque for steering wheel nut .....................................80 L 6 N•m (60 L 4 lb•ft) (2) Torque for bolt..............................15 N•m (11 lb•ft) Vehicle Systems 10 Specifications Steering Gear 2 1 3 VIEW C-C TIGHTENING SEQUENCE FOR BOLTS VIEW B-B 4 C 5 B B C EHCS018B (1) Pin(1) in the body must be aligned with internal pump gear (gerotor) (2) and drive (3) as shown. (4) Tighten bolts in sequence shown. Tighten to a first torque of ............14.1 L 2.8 N•m (125 L 25 lb•in) Tighten to a final torque of ...........28.2 L 2.8 N•m (250 L 25 lb•in) (5) Torque for plug ......................11.3 N•m (100 lb•in) Plug to be flush (even) with or below mounting surface. Vehicle Systems 11 Specifications Steer Axle And Wheel Dual Steer Axle And Wheel 1 2 1 2 3 3 4 3 5 5 EHCS019B EHCS015B (1) Torque for bolts (three) ......................45 L 7 N•m (35 L 5 lb•ft) (1) Torque for bolts (three) ......................45 L 7 N•m (35 L 5 lb•ft) (2) Use as required to obtain end play of pinion shaft ...................................................0.01 to 0.035 mm (2) Use as required to obtain end play of pinion shaft ...................................................0.01 to 0.035 mm (3) Torque for bolts that hold support group to pinion shaft .....................270 L 25 N•m (200 L 20 lb•ft) (3) Torque for bolts that hold support group to pinion shaft .....................270 L 25 N•m (200 L 20 lb•ft) Steer Wheel Bearing Adjustment : Steer Wheel Bearing Adjustment : a. Tighten nut (5) slowly to 100 N•m (74 lb•ft) while the steer wheel is turned. a. Tighten nut (5) slowly to 133 N•m (98 lb•ft) while the steer wheel is turned. b. Loosen nut (5) completely and tighten again to ......................................40 L 3 N•m (30 L 2 lb•ft) b. Loosen nut (5) completely and tighten again to ..................................45 to 55 N•m (33 to 41 lb•ft) c. Bend a tap of lock (4) into a notch of the nut. c. Bend a tap of lock (4) into a notch of the nut. Vehicle Systems 12 Specifications Hydraulic Pump Motor (36V) 2 1 (48V) P2 P1 2 1 EHCS020B Hydraulic Pump Motor 1 Model Voltage 36V BxxT-2 48V New Brush Minimum 2 Minimum Thickness B Width B Length Brush Length * Commutator Diameter** 14 mm B 25.3mm B 38 mm 18 mm 78 mm (.55 in B 0.99 in B 1.49 in) (.70 in) (3.07 in) 12.5 mm B 32 mm B 35 mm 18 mm 78 mm (.49 in B 1.25 in B 1.37 in) (.70 in) (3.07 in) *As measured on longest side. ** All rough edges(burrs) must be removed after the commutator is machined. Maximum difference between commutator high and low point(out of round) ............0.03 mm (.001 in) TIR Maximum difference between bar to bar .............................................0.005 mm (.0002 in) TIR Machine chamfer on the commutator bars ........................................................0.40 mm (.016 in) Torque for the terminal bolts(not shown) the hold cable connections .............................14 N•m (10 lb•ft) Thermal switch Depth of the insulation below commutator bars. ............................................................1.5 mm (.05 in) Opening temperature ..........150 L 6°C (302 L 11°F) Width of the insulation below commutator bars ..........................................................0.8 mm (.031 in) Vehicle Systems Closing temperature ...........130 L 7°C (275 L 13°F) 13 Specifications Systems Operation Hydraulic System 1 1 2 3 4 6 5 8 9 7 10 11 12 13 14 15 16 IHCS102I Basic Hydraulic Schematic With Standard Lift (1) Lift cylinders. (2) Excess flow protector. (3) Sideshift cylinder(option). (4) Flow regulator. (5) Hydraulic control valve. (6) Tilt cylinders. (7) Relief valve (lift and tilt). (8) Relief valve (sideshift). (9) Hydraulic oil filter. (10) Hydraulic oil tank. (11) Priority valve. (12) Oil line. (13) Hydraulic strainer. (14) Hydraulic pump. (15) Oil line to steering unit. (16) Oil line. The return hydraulic oil from the cylinders flows through hydraulic control valve (5), line (12), into filter (9) and hydraulic tank (10). Relief valve (7) in the control valve body will make the flow control valve release extra pressure to the hydraulic tank when the pressure in the lift or tilt circuits goes higher than relief valve pressure shown in the control valve section of Specifications. Relief valve (8) does the same thing for the sideshift circuit when it goes higher than the auxiliary relief valve pressure shown in the control valve section of Specifications. The hydraulic system has hydraulic oil tank (10), which holds the oil for gear type hydraulic pump (14). Hydraulic pump (14) sends pressure oil to hydraulic and steering systems. Pump oil flows from pump (14) to priority valve (11) where the oil flow divides to the steering unit through line (15). Oil also flows to hydraulic control valve (5) and back to hydraulic tank (10). The control valve levers move the valve spools in control valve (5) to let the pump oil in the control valve go to lift cylinders (1) and/or (18), tilt cylinders (6) or sideshift cylinder (3). Vehicle Systems 14 Systems Operation 17 18 1 1 2 3 4 5 6 8 7 9 10 11 12 13 14 15 16 IHCS103I Basic Hydraulic Schematic With Full Free Lift Or Full Free Triple Lift (1) Lift cylinders. (2) Excess flow protector. (3) Sideshift cylinder(option). (4) Flow regulator. (5) Hydraulic control valve. (6) Tilt cylinders. (7) Relief valve (lift and tilt). (8) Relief valve (sideshift). (9) Hydraulic oil filter. (10) Hydraulic oil tank. (11) Priority valve. (12) Oil line. (13) Hydraulic strainer. (14) Hydraulic pump. (15) Oil line to steering unit. (16) Oil line. (17) Excess flow protector. (18) Lift cylinder(primary). The maximum speed when the lift cylinders are lowered is controlled by flow regulator (4). Excess flow protectors (2) and (17) will act as flow regulator if an oil line between them and flow regulator (4) is broken when the mast is raised or lowered. This prevents a sudden fall of the mast or carriage if an oil line is broken. REFERENCE : For the Hydraulic Systems Schematics. Vehicle Systems 15 Systems Operation Control Valve Lift Valve Neutral Position 2 3 4 5 6 7 1 10 8 9 ICCS009S Control Valve for Lift (Shown In NEUTRAL Position) (1) Spool. (2) Outlet To Head End Of Lift Cylinders. (3) Load Check Valve. (4) Passage. (5) Inlet Passage For Pump Oil. (6) Chamber. (7) Passage For Return Oil. (8) Passage. (9) Chamber. (10) Spring. Oil from pump enters the valve through a passage in the inlet section. From there it goes to both chamber (6) and chamber (9). Since spool (1) is in the NEUTRAL position, the only path the oil can take is from chamber (9) into the tilt valve. It would go out through passage (8). The mast can be stopped and held in any position when the lift control valve is in neutral. This is because the flow to and from the cylinders is stopped by spool (1). In the NEUTRAL position, oil can not flow from passage (4) to outlet (2) or back. Vehicle Systems 16 Systems Operation Lift Position 2 3 4 5 6 7 1 10 8 9 ICCS010S Control Valve for Lift (Shown In LIFT Position) (1) Spool. (2) Outlet To Head End Of Lift Cylinders. (3) Load Check Valve. (4) Passage. (5) Inlet Passage For Pump Oil. (6) Chamber. (7) Passage For Return Oil. (8) Passage. (9) Chamber. (10) Spring. When the control lever is moved to the LIFT position, lift spool (1) is moved into the valve. Movement of spool (1) opens a path for oil to flow from chamber (6) through load check valve (3) into passage (4). From passage (4) the oil goes to outlet (2) and then to the lift cylinders. Pressure oil to the head end of the lift cylinders moves the rod up and the mast will raise. Vehicle Systems 17 Systems Operation Lower Position 2 3 4 5 6 7 1 10 8 9 ICCS011S Control Valve For Lift (Shown In LOWER Postion) (1) Spool. (2) Outlet To H ead End Of Lift Cylinders. (3) Load Check Valve. (4) Passage. (5) Inlet Passage For Pump Oil. (6) Chamber. (7) Passage For Return Oil. (8) Passage. (9) Chamber. (10) Spring. When the control lever for lift is moved to the LOWER position, lift spool (1) moves until a path is opened between outlet (2) and passage for return oil (7). Vehicle Systems 18 Systems Operation Tilt Neutral Position 2 3 4 5 6 7 8 1 13 9 10 14 16 15 11 12 ICCS012S Tilt Spool In Neutral Position (1) Spool. (2) Outlet To Rod End Of Tilt Cylinders. (3) Load Check Valve. (4) Passage. (5) Inlet Passage For Pump Oil. (6) Chamber. (7) Outlet To Head End of Tilt Cylinders. (8) Passage For Return Oil. (9) Spring. (10) Spool. (11) Passage. (12) Chamber. (13) Spring. (14) Orifice. (15) Orifice. (16) Passage. Oil from lift valve goes to both chamber (6) and (12). Since spool (1) is in the NEUTRAL position, the only path the oil can take is from chamber (12) to tank through passage (11). The mast can be stopped and held in any position when the tilt control valve is in neutral. This is because the flow to and from the tilt cylinders is stopped by spool (1). In the NEUTRAL position, oil can not flow from passage (4) to outlet (2) or (7). Vehicle Systems 19 Systems Operation Tilt Forward Position 2 3 4 5 6 7 8 1 13 9 14 10 16 15 11 12 ICCS013S Tilt Spool In Forward Position (1) Spool. (2) Outlet to Rod End Of Tilt Cylinders. (3) Load Check Valve. (4) Passage. (5) Inlet Passage For Pump Oil. (6) Chamber. (7) Outlet To Head End Of Tilt Cylinders. (8) Passage For Return Oil. (9) Spring. (10) Spool. (11) Passage. (12) Chamber. (13) Spring. (14) Orifice. (15) Orifice. (16) Passage. When the control lever for tilt is moved to TILT FORWARD position, spool (1) is moved until a path is opened between passage (4) and outlet (7) and oil flow from chamber (12) to passage (11) is stopped. This causes the oil pressure to increase and open load check valve (3). The pressure oil from the pump can now flow from passage(4) to outlet (7). It then flows to the head end of the tilt cylinders and the mast tilts forward. Return oil from the rod end of the tilt cylinders flows into the valve through outlet (2) in to passage (8) and then to tank. Vehicle Systems As tilt spool (1) is moved to the TILT FORWARD position, two paths are opened for the flow of oil to the tilt cylinders. One is from passage (4) to outlet (7), which allows pressure oil to go to the head end of the tilt cylinders. The other path is for return oil from the rod end of the tilt cylinders. As spool (1) moves, orifice (15) moves into position to send pressure oil to the chamber behind spool (10). Spool (10) moves against the force of spring (9) and opens a path for return oil between passage (16) and orifice (14). This has the effect of slowing down the flow of oil from the rod end of the tilt cylinders and preventing cavitation in the head end. If pump flow (pressure) is lost, for any reason, spool (10) will return to the NEUTRAL position and the path for return oil is closed. 20 Systems Operation Tilt Back Position 2 3 4 5 6 7 8 1 13 9 10 14 16 15 11 12 ICCS014S Tilt Spool In Tilt Back Position (1) Spool. (2) Outlet To Rod End Of Tilt Cylinders. (3) Load Check Valve. (4) Passage. (5) Inlet Passage For Pump Oil. (6) Chamber. (7) Outlet To Head End Of Tilt Cylinders. (8) Passage For Return Oil. (9) Spring. (10) Spool. (11) Passage. (12) Chamber. (13) Spring. (14) Orifice. (15) Orifice. (16) Passage. When the control lever for tilt is moved to TILT BACK position, tilt spool (1) is moved until a path is opened between passage (4) and outlet (2), and oil flow from chamber (12) to passage (11) is stopped. This causes the oil pressure to increase and open load check valve (3). The pressure oil from the pump can now flow from passage (4) to outlet (2). It then flows to the rod end of the tilt cylinders and the mast tilts back. Return oil from the head end of the tilt cylinders flows into the valve through outlet (7) into passage (8) and then to tank. Vehicle Systems 21 Systems Operation Relief Valve If the control lever is held in LIFT or TILT position after the cylinder rod is fully extended or retracted, the flow of oil from outlet port to the cylinders is stopped. The oil under pressure must be released. The pressure oil flows through piston(11) of the main relief valve. The pressure oil opens pilot valve (14). This lets the oil flow go through spring chamber (13) to passage (7). The oil then returns to tank. When the pilot valve opened, it caused a decrease in the pressure in spring chamber (13) that let piston (11) move against the force of the spring in spring chamber (13). This stops the flow of oil around the pilot valve to passage (7) and moves piston (12) down until a path is open for pump flow to go to the tank through passage (7). This action will continue until the control lever is moved to NEUTRAL position. 13 14 7 12 11 IHCS104S Relief Valve (7) Passage for return oil. (11) Piston. (12) Dump valve. (13) Spring chamber. (14) Pilot valve. Vehicle Systems 22 Systems Operation Steering System Hydraulic Operation (Load Sensing Closed Center Steering System) 3 4 6 7 5 2 1 8 L T P R LS 9 13 10 11 12 IBCS036B Steering System Schematic (1) Steering Unit. (2) Hose (to hydraulic tank). (3) Priority Valve. (4) Hose (from hydraulic pump). (5) Hose (to control valve). (6) Hose. (7) Hose. (8) Steering Axle. (9) Check Valve (in steer gear). (10) Hose (from priority valve). (11) Hydraulic Pump. (12) Hydraulic Tank. (13) Hose (load sensing). pressure drops in these lines, the priority valve metering spool will shift to meet the flow demand. As the metering spool shifts, more oil flow is diverted to hose (10) than to hose (5). The priority valve metering spool will shift back and forth to meet the steering flow demand while maintaining the Load Sensing Pressure between load sense hose (13) and the priority valve internal sensing line. At times flow to hose (5) will be closed completely. The combination of flow restrictors in the lines and spring tension on the priority valve metering spool work together to maintain this balance. The steering system is a load sensing closed center type and uses hydraulic oil for its operation. Oil flow through the steering system is closed unless the steering wheel is turned. The flow through the steering gear is sensed by the priority valve, which then allows additional oil flow to the steering system. The priority valve also fills the requirements of the power brakes (if equipped) and then the mast. Hydraulic oil is pulled from hydraulic tank (12) through a strainer to hydraulic pump (11). The pump sends the oil through hose (4) to priority valve (3). Check valve (9) is in the steering unit (pump) to prevent oil flow back to priority valve (3), which could cause a sudden jerk of the steering wheel. When the steering gear is in NEUTRAL position, pressure in hose (10) and the priority valve internal sensing line rises. When this pressure rises more than load sensing signal hose (13) the priority valve metering spool shifts to stop oil flow to the steering unit. Oil flows hose (5) to the hydraulic control valve. When the unit (pump) is moved, oil starts to flow to steer axle (8). The pressure in line (10) and the priority valve internal sensing line will drop. As Vehicle Systems Relief valve in steering unit valve body will open if the steering pressure goes above 8000 kPa (1143 psi). 23 Systems Operation Oil Flow Steering Unit–Steering Gear 1 2 3 A 4 PUMP OIL METERED OIL RETURN OIL B 5 3 10 11 5 14 15 16 6 7 1 8 8 9 10 11 IBCS037B 13 9 2 17 12 Steering Unit A. Control valve section. B. Metering section. (1) Spool. (2) Sleeve. (3) Outlet to tank. (4) Check valve. (5) Inlet from pump. (6) Rotor. (7) Stator. (8) Centering springs. (9) Pin. (10) Left turn port. (11) Right turn port. (12) Body. (13) Drive. IBCS038B Steering Unit (Shown in RIGHT TURN Position) (1) Spool. (2) Sleeve. (3) Outlet to tank. (5) Inlet from pump. (8) Centering springs. (9) Pin. (10) Left turn port. (11) Right turn port. (13) Drive. (14) Passage. (15) Passage. (16) Gerotor. (17) Passage. The steering unit has two main sections ; control section (A) and pump or metering section (B). These two sections work together to send oil to the steering cylinder. When the steering wheel is turned for a right turn, pump oil flows into the STEERING UNIT through inlet (5) and passage (14). From passage (14) it goes into the gerotor through passage (17). With the steering wheel turning, gerotor (16) is turning and pumping oil. The Metered flow comes out through passage (15), where it is directed out to the steering cylinder through right turn port (11). When the steering wheel started to turn ; spool (1), pin (9) and drive (13) also started to turn. Sleeve (2) did not start to turn at the same time as the spool because the diameter of the holes in the sleeve are slightly larger than the diameter of pin (9). This allows spool (1) to turn inside of sleeve (2) enough to put the small holes in sleeve (2) in line with the grooves in spool (1). The alignment of the small holes in the sleeve with the grooves in the spool provides the path for oil flow to gerotor (16) and also to the steering cylinder. Centering springs (8) are compressed when the spool moves in relation to the sleeve. When the steering wheel is no longer turning, the springs will bring the spool and sleeve back to a NEUTRAL position. This means that the wheels will stay in the position they were in when the steering effort stopped. The steering wheel must be turned in the opposite direction to bring the wheels back to straight ahead, or to make a left turn. As the metered oil goes out to the cylinder through outlet (11) for a right turn, return oil from the cylinder is coming back into the STEERING UNIT through outlet (10). This oil is sent to the tank. Oil from the priority valve enters the steering unit through inlet (5) into the control section. When the steering wheel is turned, the control section sends the oil to and from the metering section, and also to and from the steering cylinder. The metering section is a small hydraulic pump. It meters the oil that goes to the steering cylinder, As the steering wheel is turned faster, there is an increase in the flow of oil to the steering cylinder. This increased flow causes the steering cylinder to move farther and faster. As the steering cylinder moves farther, more oil can flow from the metering section to the steering cylinder and a faster turn is made. Vehicle Systems 4 13 24 Systems Operation 3 PUMP OIL METERED OIL RETURN OIL 10 11 5 14 15 16 21 1 1 18 2 18 19 20 19 9 2 17 IBCS040B LEFT TURN Spool And Sleeve IBCS039B (1) Spool. (2) Sleeve. (18) Slots for spring. (19) Holes for pin. (20) Small holes for oil flow. (21) Grooves for oil flow. Steering Unit (Shown in a LEFT TURN Position) (1) Spool. (2) Sleeve. (3) Outlet to tank. (5) Inlet from pump. (9) Pin. (10) Left turn port. (11) Right turn port. (13) Drive. (14) Passage. (15) Passage. (16) Gerotor. (17) Passage. The rate of flow the gerotor sections is determined by how fast the steering wheel is turned. The faster the steering wheel turns, the greater the flow and the faster the vehicle will turn. When the steering wheel is turned to the left, spool (1), pin (9) and drive (13) turn with it. After spool (1) has turned a small amount pin (9) will cause sleeve (2) to move with the spool. They will rotate together but will be a few degrees apart. The flow of oil through the STEERING UNIT is in the opposite direction to that of a right turn. It comes in through inlet (5) and passage (14) and then goses into gerotor (16) through passage (15). From the gerotor, the oil leaves through passage (17), goes through the sleeve spool combination and then to left turn port (10). From the left turn port it goes to the steering cylinder. Vehicle Systems 25 Systems Operation TANK OIL (SUPPLY) METERED OIL RETURN OIL 7 3 10 11 4 9 6 15 16 17 13 EHCS036B EMERGENCY Pump Gears In The Metering Section (6) Rotor. (7) Stator. (9) Pin. (13) Drive. EHCS035B Steering Unit (Shown in Manually Operated Right Turn Position) (3) Outlet to tank. (4) Ball check. (10) Left turn port. (11) Right turn port. (15) Passage. (16) Gerotor. (17) Passage. When the steering wheel is turned, in either direction, pin (9) turns with the sleeve and spool and causes drive (13) to turn also. The drive cause rotation of rotor (6) inside of stator (7). This rotation of the rotor sends a controlled (metered) flow of oil back to the spool sleeve combination where it is then directed to either port (10) or (11) and then to the steering cylinder. If there is a pump failure or the engine stops and can not be started again, the STEERING UNIT can be manually operated. Turning the steering wheel will take oil from the tank and bring it in through outlet (3). It will then open check valve (4) and go to the gerotor (16) through passage (17). It will come out of (16) through passage (15) and go to the right turn port (11). This is the flow for a right turn. It would be reversed for a left turn. If the unit is taken apart for any reason, it must be put back together with the relationship between pin (9) and rotor (6) as shown. During normal operation, check valve (4) will be held closed by pressure oil from the pump. Vehicle Systems 26 Systems Operation Brake System Brake fluid from remote reservoir (1) to replenish master cylinder (2). Master Cylinder The master cylinder has a piston which push brake liquid into the brake lines. The reservoir, located on the cowl, is connected to inlet of master cylinder. The supply lines keep master cylinder (2) filled so no air enters the system. Reservoir (1) supplies brake liquid to the system. (36V) When the brake pedal is first pushed, the piston moves into the master cylinder and pushes brake liquid through outlet into the brake lines. When floating piston seats on seal, the liquid that is pushed by piston goes around cup seal, out through floating piston and outlet. This action continues until the liquid pressure in piston bore reaches the pressure that opens relief valve. The liquid, being pushed by piston, now returns to reservoir(1). Cup seal, seals and the liquid inside piston is pushed through piston and outlet. 1 2 The liquid pushed through outlet goes through the brake lines to the cylinder of brake lever (3). Check valve in the master cylinder keeps a small amount of pressure in the brake lines and wheel cylinders (3) when the pedal is released. This small amount of pressure helps the cylinder of brake lever piston cup seal seat, which keeps air out of the brake system. 3 IHCS111I 3 Master Cylinder And Cylinder of Brake Lever (1) Master cylinder reservoir. (2) Master cylinder. (3) Cylinder of brake lever. 4 EHCS038B Cylinder of Brake Lever When hydraulic pressure is supplied to the cylinder of brake lever (3), the brake lever push paralled pin that is contacted on the end of brake lever (3). The wet disc brake is actuated by the force from paralled pin. IHCS112P Remote Reservoir (4) Remote reservoir. Vehicle Systems 27 Systems Operation (48V) 1 1 IHCS112P (1) Master Cylinder Reservoir Brake fluid from remote reservoir (1) to replenish master cylinder (2). 2 The master cylinder has a piston which push brake liquid into the brake lines. The reservoir, located on the middle plate, is connected to inlet of master cylinder. The supply lines keep master cylinder (2) filled so no air enters the system. Reservoir (1) supplies brake liquid to the system. 3 When the brake pedal is first pushed, the piston moves into the master cylinder and pushes brake liquid through outlet into the brake lines. The liquid pushed through outlet goes through the brake lines to the brake cylinder (3). IOCS008I Master Cylinder And Cylinder of Brake Lever (1) Master Cylinder reservoir. (2) Master Cylinder. (3) Brake Cylinder. 3 5 4 IOCS009I (3) Brake Cylinder. (4) Piston Rod. (5) Lever Plate. When hydraulic pressure is supplied to the brake cylinder (3), piston rod (4) rotates lever plate (5). With rotation, lever plate is moved towards friction and steel plates. Then wet disc brake is actuated by this force from lever plate. Vehicle Systems 28 Systems Operation Electric Motors Hydraulic Pump Motor (36V) 2 3 1 6 5 7 4 8 (48V) 3 2 1 5 4 7 6 8 EHCS039B Electric Motor (1) Brush cover. (2) Thermal switch. (3) Motor frame. (4) Brush. (5) Commutator. (6) Armature. (7) Fleld coil. (8) Fan. commutator (5). Field coils (7) are fastened to the inside of the motor frame. The hydraulic system is operated by a direct current (DC) motor. Electric storage batteries are the source of power for the DC motor The motor brushes are held in the four brush holders by springs. The springs hold the brushes against commutator (5) and compensate for brush wear. The hydraulic pump motor is a series wound motor and uses high temperature insulation. Armature (6) is mounted with single row ball bearings at each end. The ball bearings are permanently lubricated with high temperature lubricant. The parts of armature (6) include the shaft, core, windings and commutator. The electrical connections to the motor are made of corrosion resistant terminals on motor frame (3). On the outside of the motor frame is cover (1) that can be removed for easy access to brushes (4) and Vehicle Systems 29 Systems Operation The motor is protected from over temperature by a thermostat switch (2). When the normally closed thermostat switch is open, the amount of current through the motor is limited to allow, the motor to cool. All motors are fan (8) cooled. The hydraulic pump motor is activated when the key and seat switches are closed and lift, tilt or auxiliary lever is moved. In lift operation, the speed of the motor is variable. The larger the distance the lever is moved, the faster the motor will rotate. The speed of the motor is fixed in tilt or auxiliary operation. On the Option MicroController Control, the speed of lift or tilt or auxiliary operation could be pre-settable. Vehicle Systems 30 Systems Operation Testing & Adjusting 3. Check all oil lines and connections for damage or leaks. Troubleshooting 4. Check all the lift chains and the mast and carriage welds for wear or damage. Troubleshooting can be difficult. A list of possible problems and corrections are on the pages that follow. Hydraulic System and Mast This list of problems and corrections will only give an indication of where a problem can be and what repairs are needed. Normally, more or other repair work is needed beyond the recommendations on the list. Remember that a problem is not necessarily caused only by one part, but by the relation of one part with other parts. This list can not give all possible problems and corrections. The serviceman must find the problem and its source, then make the necessary repairs. The pressure Gauge Kit or the Tetragauge Group can be used to make the pressure tests of the hydraulic system. Before any test is made, visually inspect the complete hydraulic system for leakage of oil and for parts that have damage. During a diagnosis of the hydraulic system, remember that correct oil flow and pressure are necessary for correct operation. The output of the pump(oil flow) increases with an increase in motor speed(rpm) and decreases when motor speed(rpm) is decreased. Oil pressure is caused by resistance to the flow of oil. Visual checks and measurements are the first step when troubleshooting a possible problem. Then do the Operation Checks and finally, do instrument tests with pressure gauges. Use the Pressure Gauge Kit, a stop watch, a magnet, a thermometer and a mm (inch) ruler for basic test measurements. WARNING 1. The pressure of the oil required to open the relief valve. Relief valve pressures that are too low will cause a decrease in the lift and the tilt characteristics of the lift truck. Pressures that are too high will cause a decrease in the life of hoses and components. To prevent personal injury when testing and adjusting the hydraulic system, move the machine to a smooth horizontal location and lower the mast and carriage to the ground. If the mast and carriage can not be on the ground, make sure they are blocked correctly to keep them from a fall that is not expected. Move away from machines and personnel that are at work. There must be only one operator. Keep all other personnel away from the machine or where the oerator can see the other personnel. Before any hydraulic pressure plug, line or component is removed, make sure all hydraulic pressures are released. 2. Drift rates in the cylinders. Cylinder drift is caused by a leakage past cylinder pistons, O-ring seals in the control valve, check valves that do not seat correctly or poor adjustment or fit in the control valve spools. 3. Cycle times in the lift and tilt circuits; Cycle times that are too long are the result of leakage, pump wear and/or pump speed(rpm). Performance Test Visual Checks The performance tests can be used to find leakage in the system. They can also be used to find a bad valve or pump. The speed of rod movement when the cylinders move can be used to check the condition of the cylinders and the pump. A visual inspection of the hydraulic system and its components is the first step when a diagnosis of a problem is made. Lower the carriage to the floor and follow these inspections; 1. Measure the oil level. Look for air bubbles in the oil tank. Lift, lower, tilt forward and tilt back the forks several times. 2. Remove the filter element and look for particles removed from the oil by the filter element. A magnet will separate ferrous particles from nonferrous particles (piston rings, O-ring seals, etc.). Vehicle Systems 1. Watch the cylinders as they are extended and retracted. Movement must be smooth and regular. 31 Testing & Adjusting 2. Listen for noise from the pump. Mast and Carriage 3. Listen for the sound of the relief valve. It must not open except when the cylinders are fully extended or retracted, when the forks are empty. Problem: The hydraulic system will not lift the load. Probale Hydraulic Cause : 1. There is an air leak, which lets air into the hydraulic system on the inlet side of the hydraulic pump. Hydraulic Oil Temperature (Too Hot) When the temperature of the hydraulic oil gets over 98.8°C (210°F), polyurethane seals in the system start to fail. High oil temperature causes seal failure to become more rapid. There are many reasons why the temperature of the oil will get this hot. 2. The relief valve opens at low oil pressure. 3. The hydraulic pump has too much wear. 4. The load is not correct (too heavy). 1. Hydraulic pump is badly worn. Probable Mechanical Cause: 2. Heavy hydraulic loads that cause the relief valve to open. 1. The mast is not in alignment with the other lifting components and does not move freely. 3. The setting on the relief valve is too low. 2. Not enough lubricant on the parts of the mast that move. 4. Too many restrictions in the system. 3. The carriage or mast rollers(bearings) are worn and do not move(seized). 5. Hydraulic oil level in the tank is too low. 6. High pressure oil leak in one or more circuits. Problem : Lift cylinder extends too slowly. 7. Very dirty oil. Probable Hydraulic Cause : 8. Air in the hydraulic oil. 1. Not enough oil supply to lift cylinder. NOTE : If the problem is because of air in the oil, it must be corrected before the system will operate at normal temperatures. There are two things that cause air in the oil(aeration). These are : 2. Defective lift cylinder seals. Probable Mechanical Cause : a. Return oil to the tank goes in above the level of the oil in the tank. 1. The mast is not in alignment with the other lifting components and does not move freely. b. Air leaks in the oil suction line between the pump and the tank. 2. Not enough lubricant on the parts of the mast that move. 3. The carriage or mast rollers (bearings) are worn and do not move (seized). Problem : Mast does not move smoothly Probable Hydraulic Cause : 1. Air in the hydraulic system. 2. Relief valve sticks or defective. Vehicle Systems 32 Testing & Adjusting Probable Mechanical Cause : 5. Air in the hydraulic system. 1. Not enough lubricant on the parts of the mast that move. Probable Mechanical Cause: 1. The mast is not in alignment with the other lifting components and does not move freely. 2. Load rollers(bearings) defective or not adjusted correctly. 2. Carriage chains need an adjustment. Problem : Mast will not lower completely or will not lower at all. 3. Not enough lubricant on the part of the mast that moves. Probable Mechanical Cause : 4. The carriage or mast rollers(bearings) are worn and do not move(seized). 1. Lift cylinder damaged or bent. Problem : The lift or tilt cylinders do not hold their position with the valve control levers in neutral position. 2. Load rollers(bearings) defective or not adjusted correctly. 3. Not enough lubricant on the parts of the mast that move. Probable Cause : 1. The valve spools do not hold their positions because the springs for the valve spools are weak or broken. Problem: The mast does not tilt correctly or moves too slowly. Probable Hydraulic Cause : 2. Control valve leakage caused by worn valve spools. 1. There is an air leak, which lets air into the hydraulic system on the inlet side of the hydraulic pump. 3. The check valve or flow control valves in the control valve are bad. 2. The relief valve opens at low oil pressure. 4. Leakage of the cylinder lines or piston seals. 3. The hydraulic pump has too much wear. 5. There is foreign material in the control valve. 4. The internal valve of the tilt spool is stuck. 5. Control valve tilt spool has a restriction. Hydraulic Pump Probable Mechanical Cause : Problem: Noise in the pump. 1. Damage or failure of the piston rods on the tilt cylinders. Probable : Cause : 1. The oil level is low. Problem : The carriage will not lower correctly. 2. The oil is thick(viscosity too high). Probable Hydraulic Cause: 3. The pump inlet line has a restriction in it. 1. There are restrictions in the lift line. 4. Worn parts in the pump. 2. The lift spool in the control valve has a restriction caused by foreign material and does not operate freely. 5. Oil is dirty. 6. Air leaks into the inlet line. 3. The lift cylinder flow control valve has a restriction. 4. Lift cylinders excess flow protectors have a restriction. Vehicle Systems 33 Testing & Adjusting 7. The bolts of the pump do not have the correct torque. Problem: The oil temperature is too high. Probable Cause : 1. The oil level is low. Hydraulic control valve 2. There is a restriction in an oil passage. Problem:The control spools do not move freely. 3. The relief valve setting is too low. Probable Cause: 4. The oil is too thin. 1. The temperature of the oil is too high. 5. There is air leakage in the system. 2. There is foreign material in the fluid. 6. The pump has too much wear. 3. The fitting connections in the valve body are too tight. 7. The system operates at too high a pressure. 4. The fastening bolts of the valve assembly do not have the correct torque and have twisted the body. a. Relief valve setting too high. b. Attachment components cause a restriction during movement. c. Restrictions in flow control valve, check valve and in oil lines. 5. Linkage of the lift and tilt levers does not operate smoothly. Problem : Leakage at the pump shaft seal. 6. Bent lift or tilt spools. Probable Cause : 7. Damage to the return springs of the spools. 1. The shaft seal is worn. 8. The hydraulic oil is not at normal temperature for operation. 2. The inner parts of the pump body are worn. Problem : Control valve spools have leakage around the seals. 3. Operation with too low oil level in tank causes suction on the seal. Probable Cause : 4. Seal cut on shoulder of pump or keyway during installation. 1. There is foreign material under the seal. 5. Seal lips are dry and hardened from heat. 2. The valve spools are worn. Problem : There is failure of the pump to deliver fluid. 3. The seal plates are loose. 4. The seals have damage or are badly worn. Probable Cause : Problem : The load lowers when the lift spool is moved from the NEUTRAL position to the RAISE position. 1. Low level of the oil in the tank. 2. There is a restriction in the pump inlet line. Probable Cause : 3. There is air leakage in the pump inlet line. 1. There is foreign material in the check valve area. a. Loose bolts. b. Defects in suction line. 2. The check valve poppet and seat show wear. 4. The viscosity of the oil is wrong. 3. Sudden loss of pump oil pressure. 5. The pump has too much wear. 4. Damage to the relief valve which causes low oil pressure. 6. Failure of the pump shaft. Vehicle Systems 34 Testing & Adjusting Problem : Foreign material behind the wiper rings causing scratches on the cylinder rod. Problem : Spools do not return to neutral. Probable Cause: Probable Cause : 1. The springs are broken. 1. The wiper rings show wear and do not remove dirt and foreign material. 2. The spool is bent. 3. The system or valve has foreign particles in it. 4. The control linkage is not in alignment. Steering System 5. The fastening bolts of the valve have too much torque. Problem : Too much force needed to turn steering wheel. Problem : No motion or slow, then a too sudden action of the hydraulic system. Probable Cause : 1. Priority valve (if equipped) releases pressure oil at a low setting Probable Cause : 2. Pump oil pressure is low, worn pump. 1. The relief valve is not correctly set, or will not move in base and/or is worn. 3. Steering gear covers are too tight. 2. There is air in the system. 4. Steering column not aligned with steering gear. 3. Dirt or foreign particles between relief valve control poppet and its seat. 5. Priority valve spool is held in one position. 4. Valve body has a crack inside. 6. Steering gear without lubrication. 5. Spool not moved to a full stroke. 7. Low fluid level in the hydraulic supply tank. Lift and Tilt Cylinders Problem : Steering wheel does not return to center position correctly. Problem : Leakage around the cylinder rod. Probable Cause : Probable Cause : 1. Steering gear covers are too tight. 1. Cylinder head(bearing) seals are worn. 2. Steering column is not in correct alignment. 2. Cylinder rod is worn, scratched or bent. 3. Valve spool in the steering gear has a restriction. Problem There is leakage of oil inside the cylinder or loss of lift or tilt power. 4. Priority valve check valve permits lift and tilt hydraulic oil to affect hydraulic circuit. Probable Cause : Problem : Oil leakage at the pump. 1. The piston seals are worn and let oil go through. Probable Cause : 2. Cylinder has damage. 1. Loose hose connections. Problem: The tilt cylinder rods show wear. 2. Bad shaft seal. Probalble Cause : 1. The cylinder are not in correct alignment. 2. Oil is dirty. Vehicle Systems 35 Testing & Adjusting Problem: Low oil pressure. Problem : The temperature of the oil is too hot. Probable Cause : Probable Cause : 1. Low oil level. 1. The viscosity of the oil is wrong. 2. Priority valve (if equipped) relief valve spring weak. 2. Air is mixed with the oil. 3. Relief valve(priority valve) will not move from the open position. 3. The relief valve is set too high(priority valve). 4. There is a restriction in the return line circuit. 4. Oil leakage inside or outside of the system. 5. Bad pump. Brake System Problem : Pump makes noise when turning the steering wheel and does not move smoothly. Wet Disc Brake Probable Cause : Problem : Pedal resistance is not solid(spongy). 1. Air in the steering hydraulic circuit. Probable Cause : 2. The pump has to much wear. 1. Leakage or low fluid level. 3. Loose connection of the oil line on the inlet side of the pump. 2. Air in the brake hydraulic system. 3. Master cylinder is loose. 4. The viscosity of the oil is wrong. Problem : Extra (excessive) pedal pressure needed for braking action. 5. The oil level in the hydraulic tank is low. Probable Cause : Problem : Lift truck does not turn when steering wheel is slowly turned. 1. Mechanical resistance on the brake pedal. Probable Cause : 2. Restriction in the brake line. 1. The oil level of the tank is low. 3. Bad master cylinder. 2. There is air in the steering system. 4. Discs look like glass(glazed) or are worn. 3. The pump operation is not correct. Problem : Pedal gradually goes to the floor. 4. Dirt in the steering system. Probable Cause : 5. Steering gear operation is not correct. 1. Leakage or low fluid level. 6. Restriction in the steer axle linkage. 2. Bad master cylinder. Vehicle Systems 36 Testing & Adjusting Problem : Extra(excessive) pedal travel. Parking Brakes Probable Cause : Problem : Brakes will not hold. 1. Pedal adjustment is not correct. Probable Cause : 2. Leakage or low fluid level. 1. Parking brake assembly out of adjustment. 3. Air in the brake hydraulic system. 2. Parking brake control cable out of adjustment. 4. Bad master cylinder. 3. Worn brake discs. 5. Discs are worn. Problem : Brakes will not apply. Electric Motors Probable Cause : Before an analysis is made of any electric motor problem, always make reference to the troubleshooting section of MicroController Control System module. 1. Leakage or low fluid level. 2. Air in the brake hydraulic system. 3. Linkage is not in correct adjustment or is bent. WARNING 4. Discs look like glass (glazed) or worn. If an electrical failure or an overload of the motor is present, personnel must not breathe the toxic fumes which are a product of the burnt insulation. All power must be disconnected from the motor before any inspection is made to find the failure. The area around the motor must be well ventilated(air flow) and the motor is to be cooled before any repair work is done. Water must not be used on any electrical equipment because of the danger of electrical shock. If a fire is present, disconnect the electrical power and use a carbon dioxide extinguisher to put the flame out. 5. Oil or brake fluid is on the lining. 6. Bad master cylinder. Problem : Not braking evenly or rough feeling during braking (chatter). Probable Cause : 1. Discs look like glass (glazed) or worn. 2. Oil or brake fluid is on the lining. Do not operate the drive motor without a load as too much speed may cause damage to the motor and injury to personnel. 3. Bad contact between the steel discs and friction discs. 4. Brake discs uneven (out of flat). 5. Loose pressure plate bearing. NOTICE Never use air pressure that is more than 30 psi(205 kPa) and make sure the air line is equipped with a water filter. 6. Bad disc and friction disc assembly. Vehicle Systems 37 Testing & Adjusting 5. Check for short or open circuit in the armature or between armature and field. Loose field winding pole pieces. Check poles for damaged insulation, repair or replace damaged insulators. Failed armature bar insulation or armature bar connector open. Repair or rebuild the insulation, replace the armature. Problem 1 : Hydraulic pump motor will not operate. Probable Cause : 1. Bad connections or fuses. Check battery connections. Check the key fuse and power steering fuse. Check the hydraulic pump motor for possible reasons for a bad fuse. Some causes are: a) Operation with too high hydraulic pressures. b) Operation with too much current draw. c) Possible short circuit in motor. NOTE : If armature open circuits cause commutator bar pitting or burnt areas, armature will need replacement. Heat from the arcing causes the hardened copper commutator bars to be annealed (soft). Just machining (turned to a lesser diameter) of the commutator will not correct the problem from occurring again. The armature must be replaced. 2. Key switch, seat switch or line contactor not closed. Close the seat and key switch. Use a multimeter(VOM) to check power flow thru the seat switch, key switch, line contactor coil and line contactor. The key switch, seat switch and line contacor must be closed for the power steering function to operate. The key switch, seat switch, control valve switch and the line contactor must be closed for the hydraulic pump motor to operate. Opens in the armature bar connections must be found and soldered(repaired). 6. Lift and drive system operation not correct. See troubleshooting section of the Micro Controller Control System module. Problem 2 : Battery will not last a complete normal work period. Probable cause : 3. Not enough voltage. High resistance in battery cells or cables. Charge the battery or replace the battery. Check all the cells for one or more that has defects. Check the specific gravity of each cell. The maximum density difference from the highest to lowest cell must not be more than .020 SG (specific gravity). Check cable terminals for tight fit at battery terminal and control panel connectors. Check for broken inner wires in cables. 1. Too small a battery installed in the lift truck. Study and question the use of the lift truck in its complete working conditions, select and purchase appropriate capacity of battery regarding work hours. 2. Battery not being fully charged or equalized during the battery charging operation. Check the battery cells for an equalization charge (a charge to make the specific gravity the same in all cells). Check the battery charger for defects. 4. Brushes are worn. Disconnect the battery and discharge the commutating capacitor(HEAD CAP). Inspect the pump motor commutator for burnt marks or scoring (scratches). Make corrections or repair the armature commutator, replace the brushes as necessary. See Armature Commutator Inspection and Brush Inspection in Testing And Adjusting. Make reference to Problem : Pump Motor Overheat (Too Much Heat). Check for open circuits in the field coil. Test coils according to procedures in Testing And Adjusting. If there are open circuits, replace the coils. Vehicle Systems 3. Battery Discharge Indicator (BDI) lift interrupter circuit which protects the battery, shuts off the hydraulic motor circuit too soon. See Battery Discharge Indicator Operation Adjustment and Troubleshooting in the MicroController Control System module. 4. Battery charge interval is too long or charged battery cooling time is too short. This causes excessive (too much) cell temperatures which decreases the capacity of the battery to supply the rated amp hours. Decrease the battery work duration before a change. Increase the battery cooling time after a charge before it is put to use. 38 Testing & Adjusting If the motor has EE covers and the duty cycle is heavy and within the lift truck capacity, remove the covers if permitted. 5. Battery has one or more defective cells which can result in less than the rated capacity and ability of the battery. Test and locate the defective cells. Replace the defective cell (s). Battery cells are connected in series, one bad cell causes a high resistance in series with the other cells. This slows down the speed of the motor as the cell resistance increases. This can occur with the other cell almost fully charged. 4. Commutator bars burnt in two or more positions at 180° apart because : Armature bars open, replace armature, Short circuit in the armature, see Armature Tests. Armature not in balance which causes brush bounce, see Specifications. Motor was stalled against a heavy load and caused the two bars in contact with the brushes to burn, see Armature Commutator Inspection. 6. Hydraulic system draws too much battery power because of lifting and tilting arrangements or hydraulic controls are not correct for the duty cycle. Decrease hydraulic relief valve setting to the capacity needed for the application. Change to a smaller hydraulic pump (if available). Check the mast for restriction during operation. Remove quick disconnects and install fittings with lesser resistance to oil flow. Check for defective hydraulic control valve, the pilot operated relief valve. Remove any restrictions in the hydraulic circuit. Make an inspection of the movable hydraulic attachments for restrictions. Check for components that slide, bearing wear, hinges binding and the correct amount of lubrication on necessary components. 5. Dirty motor that has metallic or carbon dust. This dust is a conductor which causes electrical shorts, increase current draw and decrease pump motor output. Remove any dirt with air pressure. 6. Brushes too tight in brush holder. Brush springs not strong enough to force one or more brushes in contact with commutator. a. At installation, pull upon brush leads to make sure they return to contact with commutator correctly. See Brush Installation in Testing And Adjusting. b. If brushes are too tight remove the brush material with sandpaper until brush movement in brush box is free. 7. Loose movement of the brushes. Check the brush springs for cracks and overheating signs (bluing). Compare spring force with a new brush spring. Check the brush holder for oversize (too large for brush size). Replace the brush spring if necessary. Problem 3 : Sparks at the commutator and/or rapid brush wear. Probable Cause : 1. Worn brushes. 8. Loose brush leads or motor bus bar connections. Check the brushes for tight connections. Replace if leads are loose in brush material. Check all cables and wire connections for tightness. Replace the brushes and make sure the brushes are seated. See New Brush installation and Brush Inspection in Testing And Adjusting. 2. Loose cable connections at the motors terminals cause a high resistance in the circuit. The resistance increases amperage draw(consumption), as a result brushes deteriorate(destroy), there is arcing on the commutator, insulation on wires burns and causes a short circuit to lift truck frame. Tighten the nuts or bolts that hold the cable connections on the motor terminals. 9. Wrong grade of brushes installed that are not adaptable to the motor. Make sure all the brushes are of DAEWOO standards. Do not use other brand brushes. 10. Replacement brushes are not seated, the current goes through a small contact area with the commutator. As a result the brush temperature increases. Possibly if the contact area is poor the brushes will be destroyed in a few service meter hours. Always seat new brushes when installed, see New Brush Installation, in Testing And Adjusting. 3. Overheating(too much heat) of the pump motor. Check for an overload or a motor with defects. See Armature Commutator Inspection in Testing And Adjusting. The duty cycle is too heavy, use the hydraulics only to the limited capacity of the lift truck. Vehicle Systems 39 Testing & Adjusting 4. Wet pump motor. Dry the motor with heat to 190 ¢µ(90 °…). 11. Pump motor armature or field windings have a defect that results in high current draw at low torque output. See Armature Tests and Field Coil and Terminal Tests in Testing And Adjusting. Problem 5 : Commutator surface is grooved or extra wear. Probable Cause : 12. Possible heavy working conditions that cause too much motor heat and rapid brush wear. Commutator skin is very black which gives an indication of high temperatures. Make a replacement of the brushes and make sure the brushes are seated. See New Brush Installation and Brush Inspection in Testing And Adjusting. Install extra heavy duty brushes when available. Check the brush springs for the correct installation and for the correct spring usage. Too strong a spring force will increase amperage draw and brush wear rate. Prevent operation in an overload condition caused by excessive duty cycle which increases motor temperature and gives rapid brush wear. 1. Brushes are worn too low, brush wires caused arcing on commutator. Inspect the commutator for damage. If the arcing caused light pitting on commutator, install new brushes and seat the brushes with the Brush Seater Stone which will also clean the commutator surface. Make another inspection, if there is still pitting, commutator surface must be machined only to the minimum diameter as shown is in Specifications. 2. Dirty motor, and possibly salt water got inside. Disassemble motor, remove the debris with air pressure. If necessary, dry the motor with heat to 190°C (90°F). 13. Restriction caused by system components. Operate the hydraulic and steering system with an ammeter and a pressure gauge installed. If amperage draw and oil pressure are too high, see Testing And Adjusting and Specifications for the acceptable amperage draws and oil pressure, the system must be inspected for both mechanical and hydraulic restrictions. 3. Grade of brushes mixed. Make sure all of the brushes are DAEWOO standards. Do not use other brands of brushes. 4. Overload on brushes. Check the brush springs for the correct installation and make sure the lift truck is operating at a rated capacity. Problem 4 : Low resistance to ground [ battery potential either positive (+) or negative (-) or a medium voltage is in direct contact with truck frame (body) or drive motor body]. Problem: Lift truck has slow hydraulic speeds. Probable Cause : 1. Hydraulic pump motor overheated and pump motor thermal switch opens. Allow the motor to cool so the thermal swithch will close. See Specifications for thermal switch opening and closing temperatures. Probable Cause : 1. Dirty battery, electrolyte on top of cells and is in contact with the frame. Current flows through battery box which places a voltage on the truck frame. Clean off the battery with baking soda and water solution. 2. Pump motor control circuit overheated and thermal switch opens. Allow the control panel to cool so the Controller thermal switch will close. The thermal switch Opens at 85 L 4°C (185 L 7°F) and close at 73 L 4°C (163 L 7°F) for this model. 2. Battery or control panel wire connections in contact to truck frame. Make a continuity test to move the wire from contact. Remove wires in sequence until the fault is cleared. The fault will be in the wire last disconnected. 3. Dirty motor. Remove the metallic or carbon dust with air pressure. Vehicle Systems 40 Testing & Adjusting Hydraulic System 2 Relief Valve Pressure Check Use the Pressure Gauge Group to check the relief valve pressure. WARNING Hydraulic oil, under pressure can remain in the hydraulic system after the engine and pump have been stopped. Personal injury can be caused if this pressure is not released before any work is done on the hydraulic system. To prevent possible injury, lower the carriage to the ground, key switchoff and move control levers to make sure all hydraulic pressure is released before any fitting, plug, hose or component is loosened, tightened, removed or adjusted. Always move the lift truck to a clean and level location away from the travel of other machines. Be sure that other personnel are not near the machine when engine is running and tests or adjustments are made. 3 4 5 IHCS105S Relief Valve Adjustment (2) Control valve. (3) Screw. (4) Jam nut. (5) Acorn nut. 1. With the key switch off, remove plug(1) from priority valve (6) and install a pressure gauge. 2. Turn the key switch ON and tilt the mast back to the end of its travel. 3. With the motor at fast rpm, hold the tilt control lever in the TILT BACK position and watch the gauge. This indication of the gauge is the pressure of the oil that opens the relief valve. For the correct pressure setting, see the topic Control Valve in SPECIFICATIONS. 4. If an adjustment to the relief valve setting is necessary, do the steps that follow: a. Turn the key switch OFF. b. Remove acorn nut (5) and loosen jam nut(4). c. Turn Screw (3) either clockwise for an increase or counterclockwise for a decrease. d. Hold screw (3) and tighten jam nut (4). Install acorn nut (5). 6 1 IHCS113P Control Valve Pressure Check (1) Plug (6) Priority Valve. Vehicle Systems 5. Check the relief valve pressure setting again. 41 Testing & Adjusting Lift Cylinders Air Removal After the lift cylinder has been disassembled and then assembled again, it may be necessary to remove the air (bleed) from the cylinder. 24 1. With no load, lift and lower the mast and carriage through one complete cycle. 2. With the forks on the floor, check the oil level in the hydraulic tank. Add oil (if necessary)to bring the oil level to the full mark. EHCS009C Lift Cylinder Air Removal (FFTL - Secondary Cylinders) (24) Bleed Screw. 3. With no load, left and lower the mast and carriage again through four complete cycles. 5. Open bleed screws (23 and 24) no more than one turn. The weight of the carriage will force air and hydraulic oil out of the cylinders through the bleed screws. Close the bleed screws before all the pressure is out of the cylinders. This will prevent air from entering back through the bleed screws. WARNING The oil will have high pressure present. To prevent personal injury, do not remove the bleed screws completely . Keep hands and feet away from any parts of the truck that move, because the forks will lower when the bleed screw is loose. 6. Repeat Steps 4 and 5 until there is no air bubbles at the bleed screws. 7. After all the air is removed, tighten the bleed screws. 8. Fill the hydraulic tank to the full mark. 4. Lift the forks high enough to put a load on all stages of the lift cylinders. (The illustrations shown are of a full free triple lift mast.). 9. Lift and lower the mast and carriage again through one complete cycle. If the mast does not operate smoothly, repeat Step 3 through 9. 23 EHCS008C Lift Cylinder Air Removal (FFTL - Primary Cylinder) (23) Bleed Screw. Vehicle Systems 42 Testing & Adjusting Steering System Steering System Air Removal Steer Wheel Bearing Adjustment 1. Fill the hydraulic tank nearly full. Be ready to add oil when the pump motor is started. Do not let the oil level go below the outlet to the pump. 2 NOTICE To prevent damage to the steering pump, keep the oil level in the hydraulic tank above the outlet to the pump. 1 2. Close the seat switch and turn the key switch on. Add oil immediately to the tank as needed. EHCS033C 3. Lift a capacity load to take the weight off of the steer axle. Turn the steering wheel as rapidly as possible to remove the air in the steer axle and lines. Bearing Adjustment (1) Nut. (2) Lock washer. Single wheel 4. Add oil immediately when the valve spool of the steering gear is activated to replace oil that flows through the circuit. 1. Tighten nut (1) slowly to 100 N•m (74 lb•ft) while the wheel is rotated in both directions to put the bearings into position. 2. Loosen nut (1) completely. Tighten nut (1) again to 40 L 3 N•m (30 L 2 lb•ft). NOTICE Do not hold the steer wheel against its stops for an extended period of time. This will cause the oil to get hot and damage the components. 3. Bend lock (2) over nut (1) to hold the nut in positon. Dual wheel 5. Turn the steer wheel until it has reached the stop in one direction, then quickly turn the steering wheel in the opposite direction to the opposite stop. 1. Tighten nut (1) slowly to 133 N•m (98 lb•ft) while the wheel is rotated in both directions to put the bearing into position. 6. This procedure must go on approximately 15 to 20 times, to remove the air from the system. Add oil as required. 2. Loosen nut (1) completely. Tighten nut (1) again to 45 ~ 55 (33 ~ 41 lb•ft). 3. Bend lock (2) over nut (1) to hold the nut in position. NOTE : The oil in the lines to the steer axle stops at the piston assemblies of the rack. The oil in the steer axle does not flow in a circuit. As the piston moves backward and forward, the oil moves backward and forward in the lines. Air in these lines, and in the steer axle may move slowly into the steering gear and then to the tank. EHCS034C Bearing Adjustment Vehicle Systems 43 Testing and Adjusting 3. Turn the key switch to the ON position and activate the hydraulic controls until the oil is at a temperature for normal operation. WARNING To prevent personal injury, do not operate vehicle until air is removed. The steering will not operate correctly until the air is removed. 4. Turn the steer wheels to the left or right against the stops and make a note of the indication on the pressure gauge. 5. The indication on the pressure gauge must be the priority valve relief setting. The priority relief setting should be from 8000 to 8500 kPa(1161 to 1234 psi). If the indication is correct and a problem exists, then there is possibly a mechanical failure in the steering system. 7. When the oil in the tank is clear(not cloudy), the system is free of air. 8. Fill the tank to the recommended level. Steering System Pressure Check 6. If the indication is not correct, then there is steering hydraulic failure in the components. Do these procedures to find the failure as follws. a. With the motor running and read the indication on pressure gauge. b. If the indication is approximately the pressure shown in Step 5, then the steering gear has a hydraulic failure. 1 c. If the indication is too low or too high, then the priority valve on its components must be replaced. IHCS114P 7. If the steering gear and the priority valve are working properly, the steering cylinder is defective and must be repaired. Hydraulic Steering Gear (1) "P" port of steering unit. 8. Correct the problem and check steering relief valve pressure again. If the steering system does not work correctly, check the hydraulic tank for the correct oil level and the hoses and connections for leakage. If all these items are correct, use the pressure gauge to check the steering hydraulic system and its relief pressure setting. WARNING Hydraulic pressure can cause personal injury. Before any steering system hydraulic lines or components are disconnected, make sure all hydraulic pressure is released in the steering system. Move the steer wheels to the left and right and then to the straight forward direction. 1. Turn the motor off. Disconnect off. 2. Connect the 28000 kPa (4000 psi) gauge to the port(1) after removing plug. Vehicle Systems 44 Testing and Adjusting Brake System 2 Brake System Air Removal When the brake pedal resistance is spongy(not solid) it is usually an indication that there is air in the brake hydraulic system. The cause may be low fluid or oil level, leakage in the system, a broken brake line or a brake line that is not connected. IHCS116P To remove air from the brake system. do the procedure that follows : Bleed Screw Location (2) Bleed screw. 2. Put pressure on the brake pedal and open bleed screw (2) to let air out of the system. Close bleed screw (2), while pressure is still on the brake pedal, then let the pedal return to the original position. 1 3. Do step 2 again as many times as necessary until the brake fluid is free of air. 4. (If equipped) : Use the procedure in Steps 2 and 3 again, except this time use the other bleed screw (not shown). IHCS115P Reservoir Location (1) Reservoir. 5. Fill the reservoir again, with the correct fluid, to the level explained in Step 1. 1. Fill reservoir (1) with the correct fluid to 12.7 mm (.50 in) from the filler cap. See the Operation And Maintenance Manual for the correct brake fluid. Vehicle Systems 45 Testing and Adjusting Pedal Adjustment Parking Brake Test The brake pedal must have enough free play to let the master cylinder piston return to the release positon and open the relief outlet. 1. Drive the lift truck with a rated load up a 15% incline. Hydraulic pressure in the brake lines goes back through the relief opening and releases the brakes. If there is no pedal free play, the pressure can not go back through the relief opening, and the brakes will tighten and not release. WARNING To prevent personal injury, the operator must be ready to use the service brake if the parking brake is not adjusted correctly and the lift truck starts to move. If there is too much free play, the brake pedal will be low even with the correct brake adjustment. 2. Half way up the incline, stop the lift truck with the service brakes. Apply the parking brake. The master cylinder push rod must be adjusted so the brake pedal has 3.0 to 8.0 mm(.118 L .315 in) of free play from the pedals stop to the push rod contact point with the master cylinder piston. 3. If the parking brake has the correct adjustment, the lift truck will be held in this position. If the pedal free play adjustment is not correct, do the procedure that follows : 4. If the parking brake does not hold, do the steps in Parking Brake Adjustment. 2 1 3 IHCS117P Location of Master Cylinder (1) Boot. (2) Rod. (3) Nut. NOTE : On some trucks the rubber boot may have to be moved to expose the adjustment nuts. 1. Loosen nut (3). 2. Adjust rod (2) until there is the correct amount of free play. 3. Hold rod (2) and tighten nut (3). Vehicle Systems 46 Testing and Adjusting Parking Brake Control Group Adjustment Hydraulic Pump Motor (36V) (36V) Motor Brushes Brush Inspection 1. Measure the radial length of the brush. 2 1 ILCS021P Brush Measurement EHCS048B 2. Brush measurement : (48V) B a. If the brush length is less than 18 mm (.7 in) on the radial side, replace the brushes. A B New Brush Installation A NOTE : Installation of new brushes is a two person operation. 1. Disconnect the batteries. 1 VIEW A-A 2. Discharge the head capacitor. 3. Remove the brush covers. Loosen the screw of the brush. Pull out the old brushes from the brush holder while lifting up the brush spring. Each two brushes are involved in each sides. Totally 8 brushes. VIEW B-B EHCS048B Parking Brake Control Group (1) Switch assembly. (2) Cam. 1. Put the parking brake in the OFF position. 2. Adjust the switch assembly (1) whichis depressed by cam (2) when parking brake put in the ON position. Vehicle Systems 47 Testing and Adjusting WARNING Wear eye protection when seating, polishing or cleaning the motor with air pressure. During the seating and polishing procedure, keep fingers away from components in rotation. For prevention of injury to fingers, do not use a commutator cleaner or brush seater stone that is shorter than 63.5 mm (2.50 in). ILCS022P Install Brushes (1) Brushes. NOTICE Installation of the wrong brushes can cause early motor failure. Always make sure the correct DAEWOO brushes are installed. 4. Install new brushes(1). Make sure the brushes move freely in the brush holders. Use a piece of plain bond paper to remove brush material if there is a restriction of brush movement. ILCS024P Brush Seating (3) Brush seater stone. 8. Put ZLX-0036 Brush Seater Stone (3) on the commutator and operate the motor at a slow speed. NOTICE Do not let stone (3) stay in contact with the commutator bar too long time. This causes more wear than is necessary to the brushes and the commutator. ILCS023P 9. Move stone (3) across the commutator at the back edge of the brushes for a short time. This will take the shiny finish off the commutator and seat the new brushes. Install Springs (2) Spring. 5. Place carefully the brush spring (2) on the top of brush and make sure they fasten into the brush holder box. 10. Turn the key switch to the OFF position and disconnect the batteries. Check the contact surface of each brush. At least 85% of the brush contact surface of each brush must show wear. If necessary, do Steps 7 through 10 again until the correct wear can be seen on the brush contact surface. 6. Pull up the wire of each brush until the contact end of the brush moves away from the commutator. Release the wire to see if the brush moves smoothly back into contact with the commutator. If it is too difficult to pull out, or it does not move smoothly in the brush holder box, remove the spring and brush. Make an inspection to find and correct the cause of the problem. 7. Connect the batteries to the battery connector. Vehicle Systems 48 Testing and Adjusting Ground Test NOTICE Never use air pressure that is more than 205 kPa (30 psi). Make sure the line is equipped with a water filter. 11. After the brushes have the correct seat contact surface, operate the motor at slow speed. Use compressed (pressure) air to remove all dust and abrasive grit. ILCS026P Armature Tests Ground Test Tools Needed Digital Multimeter Or Equivalent 1 Growler Tester 1 Digital multimeter can be used to test for grounds. Put the Function / Range Switch on the 2M resistance (Ω) scale. When the test leads are put on the commutator and the shaft, the meter must give an resistance is more than 2 megohms. Short Circuit Test NOTICE Never use air pressure that is more than 205 kPa (30 psi). Make sure the air line has a water filter. If there is an indication of a ground in the above test, remove any dirt or debris from the armature with compressed (pressure) air. Do the ground test again, If there is still an indication of a ground, replace the armature. ILCS025P Open Circuit test Short Circuit Test (1) Glowler. (2) Armature. (3) Hacksaw Blade. (4) Green Light. (5) Red Light. The odor of burned insulation from the pump motor while it is in operation is an indication of a short in the armature. 1. Turn the growler (1) on. 2. Slowly turn the growler on the armature (2) while a hacksaw blade (3) is held over the windings. ILCS027P 3. If the windings are shorted, the green light (4) will be on. The red light (5) will be on if the windings do not have a short. Vehicle Systems Open Circuit Test 1. Put the digital multimeter Function/Range Switch on the 200 ohm resistance (Ω) scale. 49 Testing and Adjusting 2. Put one test lead on one commutator bar, Put the other test lead on an adjacent (next to) bar and there must be less than one ohm resistance. This test can also be done with an instrument, such as a Kelvin Double Bridge, that can make a measurement of very low resistance. Do the test the same as above and make a comparison of the resistance measurements. Two burned areas on opposite sides of the commutator are indications of an open armature winding. These burned areas can cause very rapid brush wear. EHCS050P Commutator Inspection Threads on the Commutator Surface Surfaces of Commutators that need Replacement Threads (grooves that look like threads) on the commutator surface, will also cause fast brush wear. EHCS049P Marks on the Commutator Surface EHCS051P Marks on the commutator surface are an indication that metal has moved from the commutator surface to the carbon brushes. Marks will cause fast brush wear. Vehicle Systems Grooves on the Commutator Surface Grooves on the commutators surface are caused by a cutting material in the brush or atmosphere. 50 Testing and Adjusting Field Coil And Terminal Tests Tools Needed Digital Multimeter Or Equivalent 1 Open Circuit Test EHCS052P Copper Drag on the Commutator Surface Copper drag is an extra amount of commutator material at the back edge of the commutator bars. ILCS028P Open Circuit Test 1. Put the digital multimeter Function / Range Switch on the 200 ohm resistance (Ω) scale. 2. Put one test lead to each outer field terminal (P1, P2). 3. The resistance must be less than one ohm. If the resistance is too high, it is an indication of corrosion on the terminals or an open field coil. EHCS053P Pitch Bar-Marks on the Commutator Surface. Pitch bar-marks cause low or burnt marks on the commutator surface. ILCS029P Brush Test (1) Field terminal. (2) Brush leads. (A) Multimeter. 4. Put one test lead to one of outer field terminals (1). Put the other test lead to each of brush leads (2) that connect to the brush holders. There must be continuity to two of the leads with a resistance of less than 1 ohm. 5. Put one test lead to the other outer field terminal. There must be continuity from this field terminal to the other two brush holder leads. Vehicle Systems 51 Testing and Adjusting Ground Test 1. The brush holders are mounted on the rocker at the commutator end of the motor. Make a visual inspection of the brush holders and the rocker. 2. Put digital multimeter Function / Range Swich on the 200 ohm resistance (Ω) scale. Put one test lead to brush holder (1) and the other test lead to the end bell (2). The meter must show overload(OL). 3. Check each brush holder. If meter reading is low, the brush holder is grounded. Replace the rocker. ILCS030P Ground Test (1) Field terminal. (2) Motor housing. Brush Life Estimate 1. Put the digital multimeter Function / Range Switch on the 20M resistance (Ω) scale. 1. Before installation of new brushes, inspect the armature commutator. See Armature commutator Inspection in Testing and Adjusting. 2. Put one test lead to either outer field terminal (1) and the other test lead to motor housing (2). There must be more than one megohm resistance. 2. Do the steps and procedures for New Brush Installation in Testing and Adjusting. 3. Make the initial (first) inspection of brush wear between 250 smh and 500 smh. The reason for this initial inspection is to see if the brush wear rate is normal and not too fast. The measurement will help make an estimate of the length of brush life to be expected. 3. If there is measurement of less than one megohm, it can be caused by wet insulation on the field windings or excessive brush dust in housing. Heat the motor at 88˚C (190˚F)until the resistance goes above one megohm. If the resistance does not go above one megohm, the shell and field assembly must be replaced. NOTE : If there is an indication that brush wear is too fast, see Troubleshooting, Problem: Sparks at the commutator and/or rapid brush wear. Brush Holder Test 4. Inspect all brushes in the motors. Measure and record each brush length. Tools Needed Digital Multimeter Or Equivalent 5. Estimate expected brush life (hours). 1 6. The smh estimate of brush life can be used if the machine is to work at the same rate(duty cycle), the battery is not discharged too much or the battery cells have not become damaged. If the machine is made to work harder, the battery is discharged too much, or the battery cells become damaged, the motor temperature will get hot very fast. This will cause rapid wear of the brushes. 7. It is important to check brush length and brush condition at a specific time, such as during the preventive maintenance check. If an inspection shows that brush life will not extend to the next preventive maintenance check, install new brushes. ILCS031P Brush Holder Test (1) Brush Holder. (2) End Bell. Vehicle Systems 52 Testing and Adjusting (48V) Motor Brushes Brush Inspection 1 1. Measure the radial length of the brush. EHCS040C Install Brushes (1) Brushes. NOTICE Installation of the wrong brushes can cause early motor failure. Always make sure the correct DAEWOO brushes are installed. EHCS039C Brush Measurement 2. Brush measurement : 4. Install new brushes(1). Make sure the brushes move freely in the brush holders. Use a piece of plain bond paper to remove brush material if there is a restriction of brush movement. a. If the brush length is less than 18 mm (.7 in) on the radial side, replace the brushes. New Brush Installation NOTE : Installation of new brushes is a two person operation. 2 1. Disconnect the batteries and remove them from the lift truck. Put the batteries close enough to the truck that the battery connector can be plugged in. 2. Discharge the head capacitor. EHCS041C 3. Remove the brush covers. Loosen the two screws of the brush and BWI Wires. Pull out the old brushes from the brush holder while lifting up the brush spring. Install Springs (2) Spring. 5. Place carefully the brush spring (2) on the top of brush and make sure they fasten into the brush holder box. 6. Pull up on the two wires of each brush until the contact end of the brush moves away from the commutator. Release the wires to see if the brush moves smoothly back into contact with the commutator. If it is too difficult to pull out, or it does not move smoothly in the brush holder box, remove the spring and brush. Make an inspection to find and correct the cause of the problem. Vehicle Systems 53 Testing and Adjusting 7. Connect the batteries to the battery connector. NOTICE Never use air pressure that is more than 205 kPa (30 psi). Make sure the line is equipped with a water filter. WARNING Wear eye protection when seating, polishing or cleaning the motor with air pressure. During the seating and polishing procedure, keep fingers away from components in rotation. For prevention of injury to fingers, do not use a commutator cleaner or brush seater stone that is shorter than 63.5 mm (2.50 in). 11. After the brushes have the correct seat contact surface, operate the motor at slow speed. Use compressed (pressure) air to remove all dust and abrasive grit. Armature Tests Tools Needed Digital Multimeter Or Equivalent 1 Growler Tester 1 3 Short Circuit Test 1 4 5 EHCS042C Brush Seating (3) Brush seater stone. 8. Put ZLX-0036 Brush Seater Stone (3) on the commutator and operate the motor at a slow speed. 3 EHCS043C Short Circuit Test (1) Glowler. (2) Armature. (3) Hacksaw blade. (4) Green light. (5) Red light. NOTICE Do not let stone (3) stay in contact with the commutator bar too long time. This causes more wear than is necessary to the brushes and the commutator. The odor of burned insulation from the pump motor while it is in operation is an indication of a short in the armature. 9. Move stone (3) across the commutator at the back edge of the brushes for a short time. This will take the shiny finish off the commutator and seat the new brushes. 1. Turn the growler (1) on. 2. Slowly turn the growler on the armature (2) while a hacksaw blade (3) is held over the windings. 10. Turn the key switch to the OFF position and disconnect the batteries. Check the contact surface of each brush. At least 85% of the brush contact surface of each brush must show wear. If necessary, do Steps 8 through 11 again until the correct wear can be seen on the brush contact surface. Vehicle Systems 2 3. If the windings are shorted, the green light (4) will be on. The red light (5) will be on if the windings do not have a short. 54 Testing and Adjusting Ground Test 1. Put the digital multimeter Function/Range Switch on the 200 ohm resistance (Ω) scale. 2. Put one test lead on one commutator bar, Put the other test lead on an adjacent (next to) bar and there must be less than one ohm resistance. A This test can also be done with an instrument, such as a Kelvin Double Bridge, that can make a measurement of very low resistance. Do the test the same as above and make a comparison of the resistance measurements. Two burned areas on opposite sides of the commutator are indications of an open armature winding. These burned areas can cause very rapid brush wear. EHCS044C Ground Test (A) Multimeter. Commutator Inspection Surfaces of Commutators that need Replacement Digital multimeter (A) can be used to test for grounds. Put the Function / Range Switch on the 2M resistance (Ω) scale. When the test leads are put on the commutator and the shaft, the meter must give an resistance is more than 2 megohms. NOTICE Never use air pressure that is more than 205 kPa (30psi). Make sure the air line has a water filter. If there is an indication of a ground in the above test, remove any dirt or debris from the armature with compressed (pressure) air. EHCS049B Do the ground test again, If there is still an indication of a ground, replace the armature. Marks on the Commutator Surface Marks on the commutator surface are an indication that metal has moved from the commutator surface to the carbon brushes. Marks will cause fast brush wear. Open Circuit test 1 EHCS045C Open Circuit Test (1) Armature. Vehicle Systems 55 Testing and Adjusting EHCS050B EHCS052B Threads on the Commutator Surface Copper Drag on the Commutator Surface Threads (grooves that look like threads) on the commutator surface, will also cause fast brush wear. Copper drag is an extra amount of commutator material at the back edge of the commutator bars. EHCS053B EHCS051B Pitch Bar-Marks on the Commutator Surface. Grooves on the Commutator Surface Pitch bar-marks cause low or burnt marks on the commutator surface. Grooves on the commutators surface are caused by a cutting material in the brush or atmosphere. Vehicle Systems 56 Testing and Adjusting Ground Test Field Coil And Terminal Tests Tools Needed Digital Multimeter Or Equivalent 1 2 1 Open Circuit Test EHCS048C Ground Test (1) Field terminal. (2) Motor housing. 1. Put the digital multimeter Function / Range Switch on the 20M resistance (Ω) scale. EHCS046C Open Circuit Test 2. Put one test lead to either outer field terminal (1) and the other test lead to motor housing (2). There must be more than one megohm resistance. 1. Put the digital multimeter Function / Range Switch on the 200 ohm resistance (Ω) scale. 3. If there is measurement of less than one megohm, it can be caused by wet insulation on the field windings or excessive brush dust in housing. Heat the motor at 88 °C(190 °F)until the resistance goes above one megohm. If the resistance does not go above one megohm, the shell and field assembly must be replaced. 2. Put one test lead to each outer field terminal (P1, P2). 3. The resistance must be less than one ohm. If the resistance is too high, it is an indication of corrosion on the terminals or an open field coil. 1 2 Brush Holder Test Tools Needed A Digital Multimeter Or Equivalent 1 1 A EHCS047C Brush Test (1) Field terminal. (2) Brush leads. (A) Multimeter. 4. Put one test lead to one of outer field terminals (1). Put the other test lead to each of brush leads (2) that connect to the brush holders. There must be continuity to two of the leads with a resistance of less than 1 ohm. 2 EHCS049C Brush Holder Test (1) Brush holder. (2) End bell. (A) Multimeter. 5. Put one test lead to the other outer field terminal. There must be continuity from this field terminal to the other two brush holder leads. Vehicle Systems 57 Testing and Adjusting Ground Test 1. The brush holders are mounted in the cover at the commutator end of the motor. Make a visual inspection of the brush holders and the cover. 2. Put digital multimeter (A) Function / Range Swich on the 200 ohm resistance (Ω) scale. Put one test lead to brush holder (1) and the other test lead to the end bell (2). The meter must show overload(OL). 3. Check each brush holder. If meter reading is low, the brush holder is grounded. Replace the cover. EHCS051C Thermal Switch(Thermostat) Tests Ground Test Tools Needed Digital Multimeter Or Equivalent 1. Put the digital multimeter Function / Range Switch on the 20M resistance (Ω) scale. 1 2. Put one test lead to either of the plug prongs. The other test lead must be grounded to the motor housing. There must be more than one megohm resistance. Open Circuit Test Brush Life Estimate 1. Before installation of new brushes, inspect the armature commutator. See Armature commutator Inspection in Testing and Adjusting. 2. Do the steps and procedures for New Brush Installation in Testing and Adjusting. EHCS050C Open Circuit Test 3. Make the initial (first) inspection of brush wear between 250 smh and 500 smh. The reason for this initial inspection is to see if the brush wear rate is normal and not too fast. The measurement will help make an estimate of the length of brush life to be expected. 1. Put the digital multimeter Function / Range Switch on the 200 ohm resistance (Ω) scale. 2. Put one test lead to each side of the thermal switch harness. NOTE : If there is an indication that brush wear is too fast, see Troubleshooting, Problem: Sparks at the commutator and/or rapid brush wear. 3. The resistance must be less than one ohm. 4. Inspect all brushes in the motors. Measure and record each brush length. See Hydraulic Pump or Steering Pump Motor in Specifications for new and minimum brush length. Vehicle Systems 58 Testing and Adjusting 5. Estimate expected brush life (hours). Use the shortest measurement from Step 4 and the following Sample Procedure : Length of new brush ................ 35mm (1.387 in) Minimum length of brush ............18mm (.708 in) New brush length [35mm (1.387 in)] - Minimum Brush length [18mm (.708 in)] = Total amount of Usable brush wear [17mm (.67in)] Length of shortest brush at 500 smh is 32.5 mm(1.279 in) New brush length [35mm (1.378 in)] - Length of shortest brush at 500 smh [32.5mm (1.279) in)]=Amount of brush wear at 500 smh [2.5 mm(.10in)]. Amount of brush wear at 500 smh [2.5mm(.10 in)] Total amount of usable brush wear [17mm (.67 in)]=Portion of brush used at 500 smh (.1). Service Meter Hours (smh) at brush wear measurement (500 smh) - Portion of brush used (.1)=Approximate total brush life of a new brush (5000 smh). Approximate total brush life of a new brush (5000smh) - Amount of smh at brush life estimate (500smh)=Remainder of usable brush life(4500 smh). 6. The smh estimate of brush life can be used if the machine is to work at the same rate(duty cycle), the battery is not discharged too much or the battery cells have not become damaged. If the machine is made to work harder, the battery is discharged too much, or the battery cells become damaged, the motor temperature will get hot very fast. This will cause rapid wear of the brushes. 7. It is important to check brush length and brush condition at a specific time, such as during the preventive maintenance check. If an inspection shows that brush life will not extend to the next preventive maintenance check, install new brushes. Vehicle Systems 59 Testing and Adjusting SB4114E00 Sep. 2003 Disassembly & Assembly Lift Trucks Vehicle Systems B15T-2, B18T-2, B20T-2(36V) EMOD4-00001~UP EMOD5-00001~UP EMOD6-00001~UP B13T-2, B15T-2, B18T-2, B20T-2(48V) EMOFB-00001~UP EMOFC-00001~UP EMOFD-00001~UP EMOD7-00001~UP Important Safety Information Most accidents involving product operation, maintenance and repair are caused by failure to observe basic safety rules or precautions. An accident can often be avoided by recognizing potentially hazardous situations before an accident occurs. A person must be alert to potential hazards. This person should also have the necessary training, skills and tools to perform these functions properly. Improper operation, Iubrication, maintenance or repair of this product can be dangerous and could result in injury or death. Do not operate or perform any Iubrication, maintenance or repair on this product, until you have read and understood the operation, Iubrication, maintenance and repair information. Safety precautions and warnings are provided in this manual and on the product. If these hazard warnings are not heeded, bodily injury or death could occur to you or other persons. The hazards are identified by the "Safety Alert Symbol" and followed by a "Signal Word" such as "WARNING" as shown below. WARNING The meaning of this safety alert symbol is as follows : Attention! Become Alert! Your Safety is Involved. The Message that appears under the warning, explaining the hazard, can be either written or pictorially presented. Operations that may cause product damage are identified by NOTICE labels on the product and in this publication. DAEWOO cannot anticipate every possible circumstance that might involve a potential hazard. The warnings in this publication and on the product are therefore not all inclusive. If a tool, procedure, work method or operating technique not specifically recommended by DAEWOO is used, you must satisfy yourself that it is safe for you and others. You should also ensure that the product will not be damaged or made unsafe by the operation, Iubrication, maintenance or repair procedures you choose. The information, specifications, and illustrations in this publication are on the basis of information available at the time it was written. The specifications, torques, pressures, measurements, adjustments, illustrations, and other items can change at any time. These changes can affect the service given to the product. Obtain the complete and most current information before starting any job. DAEWOO dealers have the most current information available. Vehicle Systems 1 Disassembly And Assembly Index Accelerator Control Switch.......................................17 Brake Master Cylinder..............................................41 Control Panel ...........................................................52 Counterweight ..........................................................62 Drive Motor & Drive Axle..........................................54 Hood(with seat) Assembly..........................................5 Hydraulic Control Panel ...........................................51 Hydraulic Control Valve..............................................7 Hydraulic Pump........................................................14 Hydraulic Pump Motor..............................................13 Overhead Guard ....................................................... 6 Primary Lift Cylinder.................................................23 Priority Valve ............................................................40 Secondary Lift Cylinder ............................................18 Spindle – Steer Axle.................................................48 Steer Axle.................................................................43 Steer Sensor Group .................................................30 Steering Column ......................................................32 Steering Gear...........................................................35 Steering Wheel.........................................................31 Tilt Cylinder ..............................................................26 WARNING Disconnect batteries before performance of any service work. Vehicle Systems 3 Index Hood(with seat) Assembly Remove & Install Hood(with seat) Assembly 3 1 EHCD003C 4. Remove two bolts (3) and washers. EHCD001C 1. Raise the hood. Support the hood with a hoist. 4 2. Disconnect harness connector (1) for seat brake. EHCD004C 2 5. Use the hoist to remove hood and seat assembly (4). 6. Install the hood and seat assembly in the reverse order of removal. EHCD002C WARNING The hood and seat assembly can fall when nut (2) is removed from the support cylinder rod. To avoid personal injury, support the seat and hood assembly before removing nut (2). 3. Remove nut (2) from the support cylinder. Remove the cylinder rod from the bracket. Vehicle Systems 5 Disassembly And Assembly Overhead Guard 4 Remove & Install Overhead Guard 3 IHCD101P 3. Remove caps (3), nuts, bolts (4) and washers from the front leg (each side). 1 EHCD005C 5 1. Disconnect harness connector (1) from inside of the cowl. 2 IHCD102P 4. Remove bolts and washer (5) from the rear leg (each side). 5. Remove overhead guard (2). EHCD006C 6. Install overhead guard (2) in the reverse order of removal. 2. Support overhead guard (2) with lifting straps and a hoist as shown. Vehicle Systems 6 Disassembly And Assembly Hydraulic Control Valve 3 Remove & Install Hydraulic Control Valves WARNING Hydraulic oil under pressure can remain in the hydraulic system after the pump motor have been stopped. Personal injury can result if the pressure is not released before any work is done to the hydraulic system. To prevent possible personal injury, turn the key switch off and move the control levers to make sure the hydraulic pressure is released before any fitting, plug, hose or component is loosened, tightened, removed or adjusted. Always move the lift truck to a clean and level location away from the travel of other machines. IHCD104P 3. Support control valve (1). Remove three bolts (3), nuts and control valve (1). 4. Install the control valve (1) in the reverse order of removal. 5. Fill the hydraulic tank to the correct level with fluid. Refer to the Operation And Maintenance Manual for further information. End By : a. Install the hydraulic control valve switch group. Start By : a. Remove hydraulic control valve switch group. 1. Drain the hydraulic tank. 3 1 IHCD103P 2 NOTE : For purposes of reassembly, put identification marks on all lines, tubes and hoses before any disconnections are made. 2. Disconnect lines (2) from control valve (1). NOTE : Plug and cap all openings to avoid contamination and debris from entering the system after removing any tubes or lines. Vehicle Systems 7 Disassembly And Assembly Disassemble Hydraulic Control Valve Start By : 6 a. Remove hydraulic control valve. IHCD107P 5. Remove lift section assembly (6) from the valve body. 1 2 7 10 IHCD105P 8 6 NOTE : For purpose of assembly, put identification marks on all valve sections. 1. Remove three nuts (1) to separate the valve sections. 9 2. Remove inlet section assembly (2) from the valve body. IHCD108P 6. Remove plug (7) and O-ring (8) from the lift section assembly (6). 4 5 3 2 7. Remove O-ring (9), poppet (10) and spring (11) from lift section assembly (6). IHCD106P 13 12 3. Remove O-ring (3) from inlet section assembly (2). 4. Remove relief valve (4) and O-ring (5). IHCD109P 8. Remove two screws (12) and cap (13) from lift section assembly. Vehicle Systems 8 Disassembly And Assembly 17 16 18 26 IHCD110P IHCD112P 13. Remove tilt section assembly (26) from the valve body. 9. Remove two screws (16) and seal plate (17). 10. Remove lift spool (18). 28 26 24 19 23 29 20 25 IHCD111P 22 IHCD113P 21 27 14. Remove O-ring (27), poppet (28) and spring (29) from tilt section assembly (26). 11. Remove the wiper seals (19) and O-rings (20) from the spool. Check the condition of O-rings and wiper seals and replace with new ones if needed. NOTE : Remove the spool end (21) from the spool. The centering spring (22) has a slight preload and will extend to its free length when the spool end is removed. 30 31 12. Remove the spring seats (23 and 24), centering spring (22) and seal plate (25). IHCD114P 15. Remove two screws (30) and cap (31) from tilt section assembly. Vehicle Systems 9 Disassembly And Assembly 15 14 44 45 33 32 43 34 IHCD115P IHCD118P 16. Remove two screws (32), seal plate (33) and tilt spool (34). 20. Remove side shift section assembly (43) and fourth section (44) from the valve body. 17. Remove valve (14) and O-ring (15). NOTE : Do step 7 through 12 to disassemble valve spools of side shift and fourth section assembly. 21. Remove section assembly (45). 35 46 47 45 37 36 38 IHCD116P 18. Remove the wiper seals (35) and O-rings (36). Check the condition of wiper seals and O-rings and replace with new ones if needed. IHCD119P 22. Remove relief valve (46) and O-ring (47) from the section assembly (45). NOTE : Remove the spool end (37) from the spool. The centering spring (38) has a slight preload and will extend to its free length when the spool end is removed. 39 38 40 37 42 41 IHCD117P 19. Remove spring seats (39 and 40), spring (38 and 42) and piston (41). Vehicle Systems 10 Disassembly And Assembly Assemble Hydraulic Control Valve 24 19 23 NOTICE Do not use caustic (corrosive) materials to clean any parts in this valve group. Caustic materials will cause corrosion and damage to parts. 20 25 IHCD111P 1. Make sure all valve parts are clean and free of dirt. 4 5 21 22 4. Install the spring seats (23 and 24), centering spring (22) and seal plate (25) on the lift spool. 3 5. Compress the spring with spool end (21) and tighten spool end. Torque the spool end to 8 ~ 11 N•m (70 ~ 97 lb•in). 2 6. Install the wiper seals (19) and O-ring (20) to the spool (18). IHCD106P 2. Install O-ring (3) to inlet section assembly (2). 16 17 18 3. Install relief valve (4) with O-ring (5) to inlet section assembly (2). The torque for the relief valve is 44 ~ 49 N•m (32 ~ 36 lb•ft). IHCD110P 7. Install the spool (18), seal plate (17) and the screws (16). Vehicle Systems 11 Disassembly And Assembly 46 45 47 13 12 IHCD109P IHCD119P 13. Install O-ring (47) and relief valve (46) to the section assembly (45). 8. Install cap (13) and two screws (12). 7 8 10 6 1 9 2 IHCD108P IHCD105P 9. Install O-ring (9), poppet (10) and spring (11) to lift section assembly (6). 14. Assemble all the sections on the studs. 15. Install the nuts (1) that hold the valve sections together. Tighten the single top nut to torque of 26 ~ 32 N•m (19 ~ 23 lb•ft) and two bottom nuts to torque of 24 ~ 29 N•m (18 ~ 21 lb•ft). 10. Install O-ring (8) and plug (7) to the lift section assembly. 39 38 40 37 End By : a. Install hydraulic control valve. 42 41 IHCD117P 11. Install piston (41), spring (42), spring seats (39 and 40) and spring (38) on the tilt spool assembly. 12. Compress the spring with spool end (37). Torque the spool end to 8 ~ 11 N•m (70 ~ 97 lb•in). NOTE : Do step 6, 7, 8 and 9 to assemble the tilt spool to the tilt section assembly. NOTE : Do same steps to assemble the side shift section and fourth section assembly. Vehicle Systems 12 Disassembly And Assembly Hydraulic Pump Motor 4 Remove & Install Hydraulic Pump Motor 5 6 Start By : a. Raise the hood. 7 b. Disconnect the battery. EHCD047C NOTE : For purpose of assembly, put identification marks on the wires and cables for proper installation. 3. Loosen clamp (6) and remove hose (7). 8 5 1 EHCD045C ILCD018P 1. Remove side panel (1) from lift truck. 4. Loosen two bolts (8) and pull the motor (5) outward. 4 3 2 10 5 9 EHCD046C EHCD048C 2. Disconnect two cables (2), harness connector (3) and BWI Cable (4) from hydraulic pump motor (5). 5. Remove elbow (9) from the hydraulic pump (10). NOTE : Plug and cap all openings to avoid contamination and debris from entering the system after removing any tubes or lines. Vehicle Systems 13 Disassembly And Assembly Hydraulic Pump Disassemble Hydraulic Pump Start By : a. Remove hydraulic pump. 2 ILCD021P 6. Remove two bolts (11), washers, hydraulic motor and pump assembly. 1 3 5 EHCD050C NOTE : Identify and mark all sections of the hydraulic pump for purposes of reassembly. 1. Remove four bolts (1) and washers (2) to remove pump cover (3). ILCD020P 7. Support pump motor (5) with straps and move out motor and pump assembly. 4 8. Remove two bolts, washers, hydraulic pump from hydraulic motor. For the reassembly purpose, the torque for bolt is 55 L 10 N•m (40 L 7 lb•ft). EHCD051C 9. Install the hydraulic pump motor and hydraulic pump in reverse order of removal. 2. Remove O-ring seal (4) from the pump body. End By : a. Connect the battery. 5 b. Close the hood. 7 6 EHCD052C 3. Remove seal (5), back up-ring (6) and bushes (7) from the pump gears. Vehicle Systems 14 Disassembly And Assembly Assemble Hydraulic Pump 13 8 14 EHCD053C 4. Remove two gears (8) from the pump body. Separate the pump sections. EHCD055C NOTE : When installing seal (13), make sure the lip of the seal is positioned toward the inside of the pump housing. 1. Install seal (13) in the pump body. 12 10 12 9 EHCD054C 5. Remove O-ring (9), seal (10), back up-ring (11) and bush (12) from the pump body. Replace seals, back up-ring, O-ring with new ones if needed. 10 9 EHCD054C 2. Install bush (12), back-up ring (11), seal (10) and O-ring (9) in the pump body. 13 14 EHCD055C 6. Remove seal (13) from the flange (14). Vehicle Systems 15 Disassembly And Assembly 2 8 1 3 EHCD053C EHCD050C 7. Install the bolts (1), washers (2) and pump cover (3) onto the pump body. Tighten the bolts for cover (3) to a torque of 39 to 40 N•m (28 to 30 lb•ft). 3. Install two gears (8) in the pump body. End By : 5 a. Install the hydraulic pump. 1 6 EHCD052C 4. Install back-up ring (6) and seal (5) in the bushes (7). 5. Install bushes (7) in the pump body. 4 EHCD051C 6. Install seal (4) on the pump body. Vehicle Systems 16 Disassembly And Assembly Accelerator Control Switch Remove And Install Accelerator Control Switch 4 5 IOCD014P 1 4. Remove four bolts (4), washers and accelerator assembly (5). 5. Install the accelerator assembly in the reverse order of removal. IOCD011P 1. Remove the floormat (1). 2 IOCD012P 2. Remove rear floor plate (2). 3 IOCD013P 3. Remove front floor plate (3). Vehicle Systems 17 Disassembly And Assembly Standard Lift Cylinder 3 Disassemble Standard Lift Cylinder Start By : a. Remove standard lift cylinders. EHCD101C 3. Remove rod (3) from the cylinder body. 1 4 EHCD099C 1. Put standard lift cylinder (1) in position as shown. EHCD102C 4. Remove retaining ring (4) from the cylinder rod. 2 5 EHCD100C 2. Remove rod-cover assembly (2) with tool. 6 EHCD103C 5. Remove screw bleeders (5) and steel ball (6) from the rod-cover. Vehicle Systems 18 Disassembly And Assembly Assemble Standard Lift Cylinder 7 12 8 9 10 EHCD104C 6. Remove O-ring seal (7) and back up ring (8) from the rod-cover. EHCD105C 1. Install slide ring (12), back up ring (11) U-packing (10) and wiper seal (9) on the inside of the rodcover 12 9 10 7 EHCD105C 8 7. Remove wiper seal (9), U-packing (10), back up ring (11) and slide ring (12) from the rod-cover. EHCD104C 2. Install back up ring (8) and O-ring seal (7) onto the rod-cover. 5 6 EHCD103C 3. Install the steel ball (6) and screw-bleeder (5) onto the rod cover. Vehicle Systems 19 Disassembly And Assembly Secondary Lift Cylinder 3 Disassemble Secondary Lift Cylinder Start By : a. Remove secondary lift cylinders. EHCD101C 4. Install rod (3) with a retaining ring into the cylinder body. 1 2 EHCD099C 1. Put secondary lift cylinder (1) in position as shown. EHCD100C 2 5. Install rod-cover assembly (2) on the cylinder rod and tighten using tool. End By : a. Install standard lift cylinder.* * Refer to the topic "Assemble Mast" in this module. EHCD100C 2. Remove rod-cover assembly (2) with tool. Vehicle Systems 20 Disassembly And Assembly 3 10 EHCD101C EHCD104C 6. Remove O-ring seal (10) and back up ring (11) from the rod-cover. 3. Remove rod (3) from the cylinder body. 5 4 15 12 13 14 6 7 EHCD105C IOCD015I 7. Remove wiper seal (12), U-packing (13), back up ring (14) and slide ring (15) from the rod-cover. 4. Remove wear rings (5), snap ring (7) and cushion ring (6) from piston (4). 8 9 EHCD103C 5. Remove screw bleeders (8) and steel ball (9) from the rod-cover. Vehicle Systems 21 Disassembly And Assembly Assemble Secondary Lift Cylinder 5 4 15 12 13 6 14 7 IOCD015I EHCD105C 4. Install cushion ring (6), snap ring (7) and wear rings (5) onto the piston (4). 1. Install slide ring (15), back up ring (14) U-packing (13) and wiper seal (12) on the inside of the rodcover 3 10 EHCD101C 5. Install rod (3) with a retaining ring into the cylinder body. EHCD104C 2. Install back up ring (11) and O-ring seal (10) onto the rod-cover. 2 8 EHCD100C 9 6. Install rod-cover assembly (2) on the cylinder rod and tighten using tool. EHCD103C End By : 3. Install the steel ball (9) and screw-bleeder (8) onto the rod cover. a. Install secondary lift cylinder.* * Refer to the topic "Assemble Mast" in this module. Vehicle Systems 22 Disassembly And Assembly NOTE : The following steps are for the installation of the primary lift cylinder. Primary Lift Cylinder Remove And Install Primary Lift Cylinder 2 Start By : 1 a. remove carriage. WARNING Be sure all the pressure in the hydraulic system has been released before any lines or hoses are disconnected. EHCD106C 5. Put primary lift cylinder (5) in position on the mast. 6. Connect hydraulic hose. 7. Install U-bracket (2) and bolts (1). 2 1 End By : a. Install carriage. Disassemble Primary Lift Cylinder EHCD106C Start By : 1. Fasten nylon straps and a hoist to the primary lift cylinder. a. Remove primary lift cylinder. 2. Remove bolts (1) and U-bracket (2). 1 2 5 4 EHCD108C 1. Remove head assembly (1). EHCD107C 2. Remove rod (2) from the cylinder body. 3. Pull the cylinder out enough to disconnect hydraulic hose (4). Remove primary lift cylinder (5). Vehicle Systems 23 Disassembly And Assembly Assemble Primary Lift Cylinder 3 6 7 8 EHCD109C 9 3. Remove rings (3) from the cylinder rod. EHCD111C 4 1. Install back-up ring (7) and U-packing (8) in the head assembly. Install the seal with the lip toward the inside. 5 2. Install wiper seal (6). Install the seal with the lip toward the outside. 3. Install slide rings (9) in the head assembly. EHCD110C 4 4. Remove O-ring seal (4) and back-up ring (5) from the head assembly. 5 6 7 EHCD110C 8 NOTE : Install the back-up ring with the curved side contacting the O-ring seal. 9 4. Install the back-up ring (5) and O-ring seal (4) on the head assembly. EHCD111C 5. Remove wiper seal (6), back-up ring (7), U-packing (8) and slide rings (9) from the head assembly. Vehicle Systems 24 Disassembly And Assembly 3 EHCD109C 5. Install split rings (3) on the cylinder. 1 2 EHCD108C 6. Install cylinder rod (2) in the cylinder body. 7. Install head assembly (1) on the cylinder body. Tighten the head assembly. End By : a. Install primary lift cylinder. Vehicle Systems 25 Disassembly And Assembly Tilt Cylinder Remove & Install Tilt Cylinder NOTE : The procedure for removing and installing the tilt cylinders is the same for both cylinders. 4 WARNING 7 IOCD016P If both tilt cylinders are removed at the same time the mast can fall. To avoid possible personal injury, make sure the mast is securely held in place or supported by a hoist before removing the tilt cylinders. 6 5 WARNING To prevent personal injury, move the control levers backward and forward to release any pressure in hydraulic system. Slowly loosen the cap of the hydraulic tank to release any pressure in the tank. Be cautious of hot hydraulic oil when any lines are disconnected in the hydraulic system. 2. Disconnect hoses (5) and (6). Remove retainer bolt (7) and pin (4). NOTE : Plug and cap all openings to avoid contamination and debris from entering the system after removing any hoses or lines. IOCD011P 1 10 2 IOCD012P 9 8 EHCD212C 3 3. Remove retainer bolt (9) from pin (8). Remove pin (8). 4. Remove tilt cylinder (10). 1. Remove floor mat (1) and floor plates (2), (3). 5. Install the tilt cylinder in the reverse order of removal. 6. Adjust tilt cylinders as follows: a. Loosen nut (11). b. Slide spacer down so rod can be turned into or out of pivot eye to obtain the correct length. c. Tighten nut (11) and the nut to a torque of 95 L 15 N•m (70 L 10 lb•ft). d. With mast at tilt back position, install shims as required to permit no gap between pivot eye and spacer. Shim so mast does not twist at full tilt back. Vehicle Systems 26 Disassembly And Assembly Disassemble & Assemble Tilt Cylinders 7 Start By : a. Remove tilt cyliner. EHCD115C 1 6. Remove spacer (6) with a O-ring seal and shims from the cylinder rod (7) if they are installed. 7. Loosen the nut and bolt on the rod eye. Remove cylinder rod (7). 2 EHCD113C 1. Remove cover-rod (1) from the cylinder body. 10 9 NOTICE Use extra care not to damage the highly finished surface of the cylinder rod and the bore of the cylinder body during disassembly and assembly of the tilt cylinder. EHCD116C 2. Remove rod assembly (2) from the cylinder body. 8. Remove slipper seal (9) and O-ring seal (10) from the piston. 4 5 3 NOTICE Check the condition of all seals. If any parts are worn or damaged use new parts for replacement. EHCD114C 3. Remove nut (3) from the cylinder rod. 4. Remove piston and seal assembly (4) from the cylinder rod. 5. Remove cover-rod assembly (5). Vehicle Systems 27 Disassembly And Assembly NOTE : Use the following steps to assemble the tilt cylinder. 12 15 13 EHCD117C 14 9. Remove O-ring seal (11) and back up-ring (12) from the cover-rod. EHCD118C NOTE : U-packing (15) should be installed with the lip of the seal toward the outside of the cover-rod. 15 12. Install wiper seal (13) in the cover-rod. Position the lip of the seal toward the outside of the coverrod as shown. 13 13. Install back-up ring (14). 14. Install U-packing (15) in the cylinder head. 14 EHCD118C 10. Remove wiper seal (13), back-up ring (14) and Upacking (15) from the cover-rod. 12 16 EHCD117C 15. Install O-ring seal (11) and back up-ring (12) on the cover-rod. EHCD119C 11. Inspect the bushing (16) in the cover-rod. If the bushing has a large amount of wear, Replace the bushing and cover-rod as a unit. The parts can not be ordered separately. Vehicle Systems 28 Disassembly And Assembly 5 4 10 3 9 EHCD116C EHCD114C 19. Position the cylinder rod eye in a vise as shown. 16. Install slipper seal (9) and O-ring seal (10) on the piston. 20. Install cover-rod assembly (5) on the cylinder rod. 21. Install piston assembly (4) onto the cylinder rod. The torque for the nut (3) is 260 L 25 N•m (190 L 20 lb•ft). 7 1 EHCD115C 17. Install cylinder rod (7) and shims. Tighten the nut and bolt on the rod eye to a torque of 95 L 15 N•m (70 L 10 lb•ft). EHCD113C 18. Install the spacer (6) with O-ring seal onto the cylinder rod if needed. 2 22. Install the rod assembly (2) in the cylinder body. 23. Tighten cover-rod (1). The torque for cover-rod (1) is 270 L 35 N•m (200 L 25 lb•ft). End By : a. Install tilt cylinder. Vehicle Systems 29 Disassembly And Assembly Disassemble Steer Sensor Group Steer Sensor Group Start By : Remove And Install Steer Sensor Group a. Remove steer sensor group Start By : 2 a. Remove counter weight. 1 EHCD122C 1 1. Remove two screws (1), washers and cover (2). EHCD120C 1. Disconnect harness connector (1). 3 EHCD123C 3 2 4 2. Remove two screws (3), washers, micro switch (4) and spacer from the plate. EHCD121C 3. Do step 2 disassemble micro switches. 2. Remove two bolts (2) and washers. 3. Remove steer sensor group (3) from steer axle assembly. 4. Install the steer sensor group in the reverse order of removal. End By : a. Install the counter weight. Vehicle Systems 30 Disassembly And Assembly Assemble Steer Sensor Group Steering Wheel Remove And Install Steering Wheel 3 1 3 2 4 EHCD123C 1. Install spacer, micro switch (4), washers and two screws (3) to plate. EHCD002B 2. Do step 1 assemble micro switches. 1. Remove cap (1) from the steering wheel. 2. Remove nut (3) and cup (2) from the steering wheel. 2 3. Use a suitable puller to remove the steering wheel. NOTE : The following steps are for installation of the steering wheel. 1 4. Put the steering wheel in position on the shaft. Install cup (2) and nut (3). Tighten the nut to a torque 80 L 7 N•m (60 L 5 lb•ft). EHCD122C 5. Install cap (1) on the steering wheel. 3. Install cover (2), washers and two screws (1) to plate. NOTE : The range of operating for micro switches are as follows: L/S L/S4 L/S3 L/S2 L/S1 75°~90° 1 1 1 0 45°~75° 0 1 1 0 25°~45° 0 0 1 0 0°~25° 0 0 0 0 25°~ 45° 0 0 0 1 45°~75° 0 0 1 1 75°~90° 1 0 1 1 ANGLE End By : a. Install the steer sensor group. Vehicle Systems 31 Disassembly And Assembly 3. Disconnect four harness connectors (5) and remove instrument panel. Steering Column Remove Steering Column 6 Start By : a. Remove steering wheel. EHCD127C 4. Remove horn switch (6) from the steering column. 1 2 IOCD020P 8 7 1. Remove four screws (1), washers and front cover (2) from the support assembly. 9 10 4 EHCD128C 5. Remove two bolts (7), washers and bracket with a directional switch (8) from the support assembly. 3 6. Disconnect four hoses (9) from the steering gear. NOTE : Put identification marks on all hoses for profer installation. Plug and cap all openings to avoid contamination and debris from entering the system after removing any hoses or lines. IOCD021P 2. Remove two screws (3) and top cover (4). 12 EHCD129C 5 IOCD022P 7. Remove four bolts (11) and separate steering gear (10) from steering column (12). Remove steering column (12) from the support assembly. NOTE : Put identification marks on all hoses and wires for proper installation purpose. Vehicle Systems 32 Disassembly And Assembly NOTICE Steering gear (10) and column (12) can separate after bolts (11) have all been removed, causing gear (10) to fall. To avoid damaging components, support the steering gear while removing bolts (11). 25 22 19 16 EHCD132C 15 13. Remove two springs (22) from the support assembly (25). EHCD130C 17 18 25 24 8. Support the support assembly (25). 9. Remove bolt (15), washers and knob (16) from the rack assembly (17). 23 25 EHCD133C 10. Remove spring (18) from the rack assembly (17). 14. Remove nuts (23), washers and bolts (24). Remove the bushings if a replacement is necessary. Remove support assembly (25) from the cowl. 11. Remove two bolts, washers, nuts (19) and rack assembly (17) from the support assembly (25). Install Steering Column 24 22 EHCD131C 12. Remove key switch (21) from the support assembly. 23 25 EHCD133C 1. Install the bushings if they were removed. Put the support assembly (25) in position on the cowl. Install bolts (24), washers and nuts (23). Vehicle Systems 33 Disassembly And Assembly 13 12 25 22 EHCD132C EHCD129C 6. Put steering gear (14) and steering column (13) in position. Install four bolts (12) and washers. 2. Install two springs (22) on the support assembly. 19 15 16 10 EHCD130C 17 18 8 25 EHCD128C 3. Put rack assembly (17) in position on the support assembly. Install two bolts, washers and nuts (19). 7. Connect hose (11) to the steering gear. Put directional switch (10) in position on the support assembly. Install the two bolts (8) and washers. 4. Put knob (16) in position on the tilt bracket. Move the console group until the knob is seated in the hole of the support assembly. Install the spring and bolt that holds the knob in position. 8. Tighten the four bolts (12) to a torque of 15 N•m (11 lb•ft). 7 EHCD127C 22 EHCD131C 9. Install horn switch (7) on the steering column. 5. Install key switch (21) to support assembly. Vehicle Systems 34 Disassembly And Assembly Steering Gear Disassemble & Assemble Steering Gear(Pump) Start By : a. Remove steering gear (pump). 5 Refer to the “Remove Steering Column” in this module for further information. IOCD022P 10. Connect four harness connectors (5). Connect wire harness to the key switch. 4 1 3 EHCD134C Typical Example IOCD021P 1. Remove the elbows (1) from pump body (2). 5 11. Put cover (4) in position on the support assembly. Install the two screws (3). 4 3 2 2 EHCD135C 1 2. Remove seven bolts (5) from gerotor housing (3) and cap (4). IOCD020P 12. Put cover(2) in position on the support assembly. Install the washers and screws (1). NOTICE Make a note of the position of special bolt with a pin. It is locatedmat a mark in line with check valve. End By : a. Install steering wheel Vehicle Systems 3. Separate housing (3) and cap (4) from pump body (2). 35 Disassembly And Assembly 6 10 9 7 8 EHCD136C 3 17 23 4 EHCD139C 4. Remove the components from housing (3) as follows: a. Remove plate (6) from housing (3) and cap (4). b. Remove shaft (7) from gerotor (9). c. Remove gerotor (9) from housing (3). d. Separate cap (4) from housing (3). e. Remove O-rings seal (8) from housing (3). f. Remove O-ring seal (10) from cap (4). 19 20 17 23 18 9. Remove the components from sleeve (16) as follows : a. Remove pin (18) from spool (17) and sleeve (16). b. Remove spool (17) from sleeve (16). c. Remove two bearing races (19), (20) and bearing (21) from spool (17). d. Remove six springs (23) and ring (22) from spool (17). 12 14 22 21 EHCD140C EHCD137C 16 13 5. Remove suction valve balls (12) and pins (11). 25 6. Remove screw (13) and check valve ball (14). 26 2 24 EHCD141C 16 EHCD138C 10. Remove O-ring seal (24) and king-ring (25) from body (2). 15 11. Check the condition of dust seal ring(26). Replace seals with new if worn or damaged. 7. Remove O-ring seal (15) from pump body (2). 8. Remove sleeve (16) from pump body (2). Vehicle Systems 36 Disassembly And Assembly 28 37 36 27 EHCD142C EHCD143C 15. Install washer (37) and plug (36) into the pump body. 12. Remove plugs (27) and washer (28) from pump body (2). 2 32 2 32 35 35 31 31 34 34 EHCD003B EHCD003B 13. Remove plug (31) and spring (32) from the pump body (2). 16. Install housing (35) and poppet (34) into the pump body. 14. Remove poppet (34) and relief valve housing (35) from the pump body. 17. Install spring (32) and plug (31) into pump body (2). Tighten plug (31) to a torque 11.3 N•m (100 lb•in). 37 28 36 27 EHCD143C EHCD142C 15. Remove plug (36) and washer (37) from the pump body. 18. Install washer (28) and plug (27) into pump body (2) Tighten plugs to a torque 30 N•m (22 lb•ft). NOTE : The following steps are for assembling the steering pump. Vehicle Systems 37 Disassembly And Assembly 22. Install pin (18), ring (22), two bearing races (19), (20) and bearing (21) in their original positions on spool (17). 25 26 2 24 EHCD141C 16 19. Install dust seal ring (26). Install O-ring seal (24) with king-ring (25) into pump body (2). EHCD138C 19 22 21 17 15 23. Install sleeve (16) into pump body (2). 24. Install O-ring seal (15) into pump body (2). EHCD140C 20 23 18 12 NOTICE For purposes of installation, note that springs (23) are installed in two stacks of three. Make sure the curves of the two stacks are in contact and positioned in the center of spool (17). The notched side of springs (23) must be positioned toward sleeve (16). EHCD137C 13 14 25. Install check valve ball (14) and screw (13).Tighten the screw (13). 26. Install suction valve balls (12) and pins (11) in their original positions into the pump body. 17 16 23 EHCD139C 20. Install springs (23) into spool (17). 21. Install spool (17) into sleeve (16). Vehicle Systems 38 Disassembly And Assembly EHCD004B 6 EHCD004B 10 9 7 NOTICE To assure proper operation of the pump, make sure bolts (5) are clean and dry before installing. Tighten bolts (5) in the sequence shown in the illustration. 5 EHCD136C 8 3 4 4 3 27. Install plate (6) onto pump body (2). 2 NOTICE Make sure the notch of shaft (7) properly seats on pin (18) when installed into body (2) and spool (17). EHCD135C 31. Install bolts (5) into cap (4). Tighten bolts (5) asfollows: a. Tighten bolts (5) in correct sequence to a first torque of 14.1 L 2.8 N•m (125 L 25 lb•in). b. Tighten bolts (5) in correct sequence to a second torque of 28.2 L 2.8 N•m (250 L 25 lb•in). 28. Install shaft (7) into body (2) and spool (17). NOTICE Gerotor (9) must be aligned with shaft (7) and pin (18) as shown in the illustration. 29. Install O-ring seal (8) and housing (3). End By : 30. Install O-ring seal (10) and cap (4). a. Install steering pump. Vehicle Systems 39 Disassembly And Assembly 5. Fill the hydraulic tank with fluid to the correct level. Fefer to the Operation and Maintenance Manual for further information. Priority Valve Remove & Install Priority Valve End By : Start By : a. Install the floorplate. a. Remove floorplate. WARNING Disassemble & Assemble Priority Valve Hydraulic oil under pressure can remain in the hydraulic system after the pump motor have been stopped. Personal injury can result if the pressure is not released before any work is done to the hydraulic system. To prevent possible personal injury, turn the key switch off and move the control levers to make sure the hydraulic pressure is released before any fitting, plug, hose or component is loosened, tightened, removed or adjusted. Always move the lift truck to a clean and level location away from the travel of other machines. Start By : a. Remove priority valve NOTE : Mark the positions of all components for purposes of reassembly. 1 2 1. Drain the hydraulic tank. 3 EHCD145C 3 4 1. Remove the spool assembly from valve body as follows : a. Remove plug (1). Check the condition of the bush (2). Replace with new bush if worn or damaged. b. Remove spool (3). c. Remove spring (4). 2 1 EHCD144C NOTE : For purposes of reassembly, put identification marks on all lines, tubes and hoses before any disconnections are made. 2. Disconnect four hydraulic lines (1) from priority valve (2). Plug and cap all openings to prevent contamination and debris from entering the system. 3. Support valve (2). Remove the two bolts (3) and priority valve and mount assembly (2). 4. Install priority valve (2) in the reverse order of removal. Vehicle Systems 40 Disassembly And Assembly Brake Master Cylinder 5 Remove And Install Brake Master Cylinder EHCD146C 3. Remove check valve (5) from the valve body. 1 NOTE : Check the condition of all components. Replace any worn or damaged components with new parts. Make sure all components are clean before reassembling. IHCD120P 4. Assemble the priority valve in the reverse order of disassembly. End By : a. Install the priority valve. 2 3 IHCD121P 1. Remove floor mat (1) and floor plates (2), (3). Vehicle Systems 41 Disassembly And Assembly Disassemble & Assemble Brake Master Cylinder 5 Start By : a. Remove master cylinder. 4 IHCD125P 2 1 2. Disconnect hose (4) and tube (5) from the master cylinder. 8 7 6 1. Remove head(1) and boot(2). 2. Remove snap ring(3) from master cylinder. 7 15 IHCD125P 4 9 13 3 5 3. Remove the cotter pin and pin (6) from the clevis and brake pedal assembly. 4. Remove two bolts (7) and master cylinder (8) from the bracket. 6 8 12 14 5. Install the brake master cylinder in the reverse order of removal. 11 10 3. Remove large spring(4) and small spring(5). 6. Fill the brake reservoir and master cylinder with brake fluid. See the Operation And Maintenance Manual. 4. Remove retaining ring(6) from small piston(12). 5. Remove spring seat(7), primary cup1(8) and small spacer(9) from small piston(12). 7. Bleed the brake system, and if necessary, adjust the pedal free level. See Brake System Air Removal And Pedal Adjustment in Testing And Adjusting. 6. Remove secondary cup(10) from large piston(13). 7. Remove spring pin(11). 8. Remove small piston(12) from large piston(13). 9. Remove primary cup2(14) and large spacer(15) from large piston(13). 10. Assemble the master cylinder in the reverse order of disassembly. End By : a. Install master cylinder. Vehicle Systems 42 Disassembly And Assembly Steer Axle Remove & Install Steer Axle Start By : 2 a. Remove overhead guard. b. Remove counterweight. c. Remove steer sensor group. 3 EHCD158C WARNING 3. Disconnect hose-steer (2) and (3) from the housing-steer axle. Be sure the pressure in the hydraulic system is released before any lines or hoses have been disconnected. 5 4 1. Raise the rear of the lift truck and support with wooden block. NOTE : For purposes of reassembly, put identification marks on hoses and lines before any disconnections are made. Plug and cap all openings to prevent contamination and debris from entering the system. EHCD159C 4. Support the axle beam with a floor jack. 5. Remove six bolts (4) and washers. For the reassembly purpose, the torque for bolt (4) is 270 L 25 N•m (200 L 18 lb•ft). Apply the Loctite NO. 262 on the bolt thread. 6. Remove axle beam assembly (5) from the housing assembly. EHCD157C 1 2. Disconnect overflow hose (1) from the housingsteer axle. Vehicle Systems 43 Disassembly And Assembly Disassemble & Assemble Housing Group-SteerAxle Start By : 6 a. Remove housing group-steeraxle 1. Drain hydraulic oil. 2 EHCD160C 7 2 1 7. Remove three bolts (6) and washers (7) then, remove axle-housing assembly (8) from the frame. For the reassembly purpose, the torque for bolt (6) is 460 L 60 N•m (340 L 45 lb•ft). Apply the Loctite NO. 262 on the bolt thread. 8. Install the steer axle assembly in the reverse order of removal. EHCD161C 2. Remove three bolts (1) and top plate (2). End By : a. Install counterweight. b. Install overhead guard. 3 c. Install steer sensor group. EHCD162C 3. Remove shim pack (3) from the pinion gear. Vehicle Systems 44 Disassembly And Assembly 4 10 EHCD163C EHCD166C 4. From the top of the pinion gear assembly, tap the pinion gear assembly (4) and remove pinion gear assembly (4) from the housing. 7. Remove piston and rack gear assembly (10) from the housing. 4 13 5 12 14 EHCD167C EHCD164C 8. Disassemble piston and rack gear assembly as follows : a. Remove wear ring (11) from the piston. b. Remove bolt (12) and washer. c. Remove piston (13) from the rack gear. d. Remove win seal (14) and O-ring from the piston. 5. Remove cone bearing (5) from the pinion gear assembly (4). 7 NOTE : Check the condition of ring and seals and replace with new ones if needed. 8 9 16 15 EHCD165C 6. Remove four bolts (8), washers and cap (9) with O-ring from the housing (7). Check the condition of O-ring and replace with new one if needed. EHCD168C 9. Remove Lip seal (15), cone bearing (16) and cup bearing from the housing. Replace with a new seal if needed. Vehicle Systems 45 Disassembly And Assembly 18 15 16 17 EHCD169C EHCD168C 10. Remove Lip seal (17) from the housing. Replace with a new seal if needed. 14. Install cup bearing in the housing. Install cone bearing (16) in the housing. 11. Remove cup bearing (18) from the housing. 15. Install Lip-seal (15) in the housing. NOTE : Use the following steps to install the housing group-steer axle. 13 18 17 12 14 EHCD167C 16. Install and assemble the piston and rack gear assembly as follows : EHCD169C 12. Install the cup bearing (18) in the housing. a. Install O-ring, win seal (14) to the piston (13). 13. Install Lip seal (17) in the housing. NOTE : Apply light coat of Loctite NO.592 sealant to outer of seal case. NOTE : Lubricate sealing lip lightly with the lubricant being sealed. b. Install the piston (13), bolt (12) and washer to the rack gear. The torque for the bolt (12) is 55 L 10 N•m (40 L 7 lb•ft). NOTE : Prepack rack gear with NLGI NO. 2 (GREASE) lubricant. c. Install wear-ring (11) on the piston. Install the piston and rack gear assembly in the housing. Vehicle Systems 46 Disassembly And Assembly 7 3 8 9 EHCD165C EHCD162C 17. Install the cap (9), washers and four bolts (8) to housing (7). The torque for the bolt (8) is 55 L 10 N•m (40 L 7 lb•ft). 21. Adjust the shim (3) on the pinion gear assembly as follows : a. Install top plate and bolts on the housing Torgue for the bolt is 55 L 10 N•m (40 L 7 lb•ft). b. Remove bolts and top plate again. c. Measure the distance (Y) from the surface of housing to the top of pinion gear. Record this measurement. d. Measure the distance (X) from the surface of housing to the top of cone bearing Record this measurement. e. Calculate the required shim thickness. 4 5 Required Shim=X–Y Following is the content of the shim pack. EHCD164C SHIM NO THICKNESS 18. Install cone bearing (5) to pinion gear assembly (4). 1 0.05 2 0.13 3 0.80 f. Combine the above shims to obtain end play of 0.01 to 0.035. EHCD006B 19. Put the pinion gear assembly (4) in position as follows : a. Put the rack gear assembly in center of housing. b. Put the pinion assembly in ‘top’ position as shown. Vehicle Systems 47 Disassembly And Assembly Spindle-Steer Axle 2 1 Remove And Install Spindle-Steer Axle 2 EHCD161C 1 22. Install the top plate (2) and bolt (1). The torque for the bolt (1) is 45 L 7 N•m (33 L 5 lb•ft). End By : a. Install the housing group-steer axle. EHCD170C 1. Loosen six nuts (1) and put wooden block under the lift truck, and lower it onto the wooden block as shown. 2. Remove six nuts (1) and tire (2). 3 EHCD171C 3. Remove cover (3) from the beam-axle. 4. Eliminate grease from the beam-axle. Vehicle Systems 48 Disassembly And Assembly 5 4 9 EHCD172P 6 EHCD175C 9. Remove cup bearing (9) from the beam-axle. 5. Bend the locking tab of washer (5) back. NOTE : Put identification on cup bearings to use at assembly. 6. Remove the nut (6) lock washer (5) and washer (4) from the spindle. 10. Remove dust-seal (10) from the beam-axle. Replace with a new seal if needed. 7 10 EHCD173C EHCD176C 7. From the front of beam-axle, tap the spindle and remove cone bearing (7) from the spindle. 11. Remove cone bearing (11) from the beam-axle. 12. Remove cup bearing from the beam-axle. NOTE : Use the following steps to install and assemble the spindle-steer axle assembly. 8 EHCD174C 8. Remove spindle assembly (8) from the beam-axle. Vehicle Systems 49 Disassembly And Assembly NOTICE Prepack wheel, actuator bearing and hub with NLGI NO. 2(GREASE) lubricant. 8 EHCD174C 10 17. Install the spindle assembly (8) into the beam axle. EHCD176C 13. Install cup bearing into the beam-axle. 7 14. Install cone bearing (11) into the beam-axle. 15. Install dust-seal (10) into the beam-axle. NOTE : Lubricate sealing lip lightly with the lubricant being sealed. EHCD173C 18. Install cone bearing (7) onto the spindle assembly (8). 19. Install washer, lock washer (5) and nut (4) on the spindle assembly. NOTE 1 : Single Wheel While rotating the wheel or hub to seat bearings, tighten locknut (6) to 100 N•m (74 lb•ft) then loosen nut (6) completely. Retighten to 40 L 3 N•m (30 L 2 lb•ft). 9 EHCD175C NOTE 2 : Dual Wheel While rotating the wheel or hub to seat bearing, tighten lock nut (6) to 133 N•m (98 lb•ft) the loosen nut (6) completely. Retighten to 45 to 55 N•m (33 to 41 lb•ft). 16. Install cup bearing (9) into the beam-axle 20. Bend the lock washer (5) to groove of nut (6) and tighten the nut (6). Vehicle Systems 50 Disassembly And Assembly NOTE : Before installing cover (3) apply grease (NLGI NO. 2) to fitting until it comes out at cover end, fill cap with grease and install in place. Hydraulic Control Panel Remove & Install Hydraulic Control Panel (36V Only) WARNING 3 Battery voltage and high amperage are present. Injury to personnel is possible. Disconnect the battery. 1. Raise the hood. EHCD171C 21. Install the cover (3) into the beam-axle. 2 2 1 1 IHCD124P 2. Remove two bolts (1), washers and side panel assembly (2) from the lift truck. EHCD170C 22. Install the steer tire (2) and nuts (1). Torque for the nut (1) is 140 N•m (103 lb•ft). 23. Remove the wooden block. 4 3 EHCD178C NOTE : For purposes of reassembly, put identification marks on all cables and wiring harness before any disconnections are made. 3. Disconnect six cable assemblies (3). 4. Disconnect harness connector (4) from the hydraulic control panel assembly. Vehicle Systems 51 Disassembly And Assembly Control Panel Remove And Install Control Panel 6 5 WARNING Battery voltage and high amperage are present. Injury to personnel is possible. The head capacitor (HEAD CAP) must be discharged before any contact with the control panel is made. Disconnect the battery and discharge HEAD CAP. EHCD179C 5. Loosen two bolts from the bottom of hydraulic control panel assembly (6). 6. Remove two bolts (5), washers and hydraulic control panel assembly (6). 7. Install the hydraulic control panel assembly (6). in the reverse order of removal. 1 2 EHCD180C 1. Raise the hood. Remove bolt (1), washers and side panel-top (2) from the frame. 4 IHCD124P 3 2. Remove two bolts (3), washers and side panel assembly (4). Vehicle Systems 52 Disassembly And Assembly 5 9 EHCD182C EHCD184C 3. Open the logic cover and disconnect four connectors (5) from the logics. 6. Disconnect ten cable assemblies (9) from the contactor at the bottom of the control panel. NOTE : Mark all cables and wires for correct installation. 7 6 8 10 EHCD183C 4. Disconnect two connectors (6). EHCD185C 5. Disconnect four nuts (7), washers and logics (8) from control panel. 7. Loosen two bolts at the bottom of the control panel. 8. Remove three bolts (10) and washers from the control panel. 9. Remove control panel assembly (11) from the lift truck. 11. Install the control panel in the reverse order of removal. Vehicle Systems 53 Disassembly And Assembly Drive Motor & Drive Axle 4 Remove & Install Drive Motor And Drive Axle 3 (36V) Start By : a. Remove mast. EHCD187C b. Remove floorplate 3. Disconnect wiring harness (3) and connector (4) from the drive motor. NOTE : The procedure for removing and installing the drive motor and drive axle is the same for both sides. 4. Disconnect four cables from the drive motor. NOTE : Put identification marks on all cables and wiring harness for installation purposes. 2 8 7 6 1 EHCD186C 1. Loosen five nuts (1) and put a jack or wooden block under the lift truck. EHCD188C 5. Loosen nuts (6) from parking cable and remove parking cable (7) from the drive axle. 2. Remove five nuts (1) and drive tire (2). 6. Remove two brake tubes (8) from the drive axle. 9 EHCD189C 7. Remove screw and band (9) from the drive motor. Vehicle Systems 54 Testing and Adjusting 13 14 10 12 EHCD190C EHCD191C 8. Support the drive motor and drive axle assembly (10). 12. Put the drive motor (13) on the drive axle (14) and install the bolt (12). The torque for the bolt (12) is 23 N•m (17 lb•ft). 9. Remove seven bolts (11) and drive motor and drive axle assembly (10) from the frame. NOTE : Apply Loctite NO. 262 sealant on bolt (10) thread. 10. Lower the drive motor and drive axle assembly (10) on the wooden block. WARNING 13 Do not knock with the drive pinion against the helical gear while installing the motor. This can cause knocking noise. 14 12 NOTICE When joining the gears, turn the motor shaft carefully until the drive pinion engages into the gearing of the helical gear. EHCD191C 11. Remove three bolts (12). Remove drive motor (13) from the drive axle (14). NOTE : The following steps are for installation of the drive motor and drive axle assembly. 10 NOTE : Before mounting, clean the mating surfaces on the drive axle and electric motor carefully (such as Loctite NO. 706) and check for damage. EHCD190C 13. Check the frame surface for damage and irregularities. The maximum admissible irregularity in the area of the drive axle contour is 0.10mm. 14. Put the drive motor and drive axle assembly (10) on the frame and install the bolt (11). The torque for the bolt (11) is 135 N•m (100 lb•ft). Apply Loctite NO. 262 on bolt thread. Vehicle Systems 55 Testing and Adjusting 9 2 1 EHCD189C EHCD186C 15. Install the band (9) and screw on the drive motor. 18. Clean mating surface on wheel shaft and wheel thoroughly (such as Loctite NO. 706) and check for damage. 8 7 6 19. The bore pattern in the rim should be in line with the bolts of the wheel shaft, then push the wheel on. 20. Install the drive tire (2). The torque for the nut (1) is 140 N•m (103 lb•ft). EHCD188C 16. Install the brake tubes (8) and parking cable (7) on the drive axle. The torque for the fitting is 50 N•m (37 lb•ft). Tighten the nut (6). 16 15 4 EHCD007B 21. If replenishing with transmission fluid, remove plug (15) with sealing ring (16) from the drive axle. 3 22. Fill the drive axle with ATF transmission fluid. Fluid capacity approximate 0.35 liters(0.37 USgt). The accurate amount of fluid is defined by the opening for the fluid filling plug. EHCD187C 17. Connect the wiring harness (3), connector (4) and four cables on the drive motor. WARNING ATF transmission fluid may only be filled in with the gear unit in the assembly position. Overfilling may impair the tightness and affect the operating temperature of the transmission. Vehicle Systems 56 Testing and Adjusting NOTE : Use a funnel with a hose for easier filling. Maximum outside diameter of hose to be 13mm. The correct level and amount of fluid has been reached when the level can be seen at the opening. When filling with fluid, make sure that no air bubbles are formed in the transmission. Turn the wheel shaft to remove them. 23. Install the plug (15) in with the sealing ring. The torque for the plug (15) is 22 N•m (16 lb•ft). 24. Check the fluid level again after a short running time. 25. The brake system must be bleeded after replenishing with brake fluid. a. Apply pressure by operating the brake pedal. b. Open bleeder valve approximate half a turn with a spanner and press simultaneously the brake pedal to bleed the system. WARNING Do not release the brake pedal before you have closed bleeder valve. c. Repeat this procedure until the brake fluid escapes without bubbles. Check the brake fluid container for sufficient fluid and refill if necessary. d. When brake fluid escapes without bubbles tighten bleeder valve. End By : a. Install mast. Vehicle Systems 57 Testing and Adjusting (48V) 6 5 NOTE : The procedure for removing and installing the drive motor and drive axle is the same for both sides. 7 2 IOCD029P 5. Loosen nuts (5) from parking cable and remove parking cable (6) from the drive axle. 1 6. Remove brake bleeder tube (7) from the drive axle. IOCD027P 1. Loosen 8 nuts (1) and put a jack or wooden block under the lift truck. 2. Remove five nuts (1) and drive tire (2). 4 8 IOCD030P 3 7. Remove brake inlet tube (8) from the drive axle. 9 IOCD028P 3. Disconnect wiring harness (3) and connector (4) from the drive motor. 4. Disconnect four cables from the drive motor. NOTE : Put identification marks on all cables and wiring harness for installation purposes. EHCD189C 8. Remove screw and band (9) from the drive motor. Vehicle Systems 58 Testing and Adjusting 13 12 10 IOCD031P IOCD032P 9. Support the drive motor and drive axle assembly (10). 10. Remove six bolts (11) and drive motor and drive axle assembly (10) from the frame. 11. Lower the drive motor and drive axle assembly (10). 14 13 IOCD033P 12 13 13. Put the drive motor (13) on the drive axle (14) and install the bolt (12). The torque for the bolt (12) is 55 N•m (41 lb•ft). NOTE : Apply Loctite NO. 262 sealant on bolt (12) thread. IOCD032P 10 IOCD031P 14 IOCD033P 13 14. Check the frame surface for damage. 15. Put the drive motor and drive axle assembly (10) on the frame and install the bolt (11). The torque for the bolt (11) is 200 N•m (147 lb•ft). Apply Loctite NO. 262 on bolt thread. 12. Remove three bolts (12). Remove drive motor (13) from the drive axle (14). NOTE : The following steps are for installation of the drive motor and drive axle assembly. NOTE : Before mounting, clean the mating surfaces on the drive axle and electric motor carefully (such as Loctite NO. 706) and check for damage. Vehicle Systems 59 Testing and Adjusting 9 4 3 EHCD189C IOCD028P 16. Install the band (9) and screw on the drive motor. 18. Connect the wiring harness (3), connector (4) and four cables on the drive motor. 2 1 8 IOCD030P IOCD027P 6 5 7 19. Clean mating surface on wheel shaft and wheel thoroughly (such as Loctite NO. 706) and check for damage. 20. The bore pattern in the rim should be in line with the bolts of the wheel shaft, then push the wheel on. 21. Install the drive tire (2). The torque for the nut (1) is 140 N•m (103 lb•ft). IOCD029P 17. Install the brake tubes (8), (7) and parking cable (6) on the drive axle. The torque for the fitting is 50 N•m (37 lb•ft). Tighten the nut (5). Vehicle Systems 60 Testing and Adjusting NOTE : Use a funnel with a hose for easier filling. Maximum outside diameter of hose to be 10mm. The correct level and amount of fluid has been reached when the level can be seen at hole for oil level plug (15). When filling with fluid, make sure that no air bubbles are formed in the transmission. Turn the wheel shaft to remove them. 16 24. Install the plug (15) in with applying LOCTITE NO.572. The torque for the plug (15) is 70 ± 10 N•m (52 ± 7 lb•ft). 15 25. Screw the air breather (16) with the sealing washer. Tighten the air breather to a torque of 70 ± 10 N•m (52 ± 7 lb•ft) with applying LOCTITE NO.277. IOCD034I 26. Check the fluid level again after a short running time. 22. If replenishing with transmission fluid, remove plug (15), and air breather (16) from the drive axle. 27. The brake system must be bleeded after replenishing with brake fluid. 23. Fill the drive axle with transmission fluid. Fluid capacity approximate 0.5 liters. The accurate amount of fluid is defined by the opening for the fluid level plug. a. Apply pressure by operating the brake pedal. b. Open bleeder valve approximate half a turn with a spanner and press simultaneously the brake pedal to bleed the system. WARNING Transmission fluid may only be filled in with the gear unit in the assembly position. Overfilling may impair the tightness and affect the operating temperature of the transmission. WARNING Do not release the brake pedal before you have closed bleeder valve. c. Repeat this procedure until the brake fluid escapes without bubbles. Check the brake fluid container for sufficient fluid and refill if necessary. d. When brake fluid escapes without bubbles tighten bleeder valve. Vehicle Systems 61 Testing and Adjusting Counterwieght Remove And Install Counterweight 2 Start By: a. Remove overhead guard. 1 b. Remove hood. IHCD126P 4. Put the counterweight in position on the lift truck and install two bolts (1) and washers. The torque for the bolt (1) is 460 L 16 N•m (340 L 45 lb•ft). Apply the Loctite NO.262 on the bolt thread. 2 End By : a. Install overhead guard. 1 b. Install hood. IHCD126P 1. Install two forged eyebolts at the top of the counterweight. Attach a hoist. 2. Remove two bolts (1) and washers from the counterweight (2). 3. Remove counterweight (2). The approximate weight of the counterweight is as follows: B13T-2(36V,48V)......................... B15T-2(36V)................................ B15T-2, B18T-2, B20T-2(48V) .... B20T-2(36V)................................ 550 630 630 840 kg kg kg kg (1213 (1389 (1389 (1852 lb) lb) lb) lb) NOTE : The following steps are for installation of the counterweight. Vehicle Systems 62 Testing and Adjusting SB4115E00 Sep. 2003 Schematic Lift Trucks Hydraulic Systems B13T-2, B15T-2, B18T-2, B20T-2 MODEL : B13T-2, B15T-2, B18T-2, B20T-2 13 S/A 10 9 3 8 6 4 7 Item 2 5 1 11 12 Components 1 Hydraulic Pump 2 Priority Valve 3 Steering Unit 4 Pressure Switch 5 Flow Regulator 6 Flow Protector-Primary 7 Flow Protector-Secondary, Standard 8 Lift Cylinder-Primary 9 Lift Cylinder-Secondary, Standard 10 Tilt Cylinder 11 Hydraulic Filter 12 Suction Strainer 13 Control Valve SB4116E00 Sep. 2003 Schematic Lift Trucks Electric Systems B15T-2, B18T-2, B20T-2(36V) EMOD4-00001~UP EMOD5-00001~UP EMOD6-00001~UP B13T-2, B15T-2, B18T-2, B20T-2(48V) EMOFB-00001~UP EMOFC-00001~UP EMOFD-00001~UP EMOD7-00001~UP SB2143E02 Sep. 2003 Disassembly & Assembly Testing & Adjusting Lift Trucks Mast Systems G15S-2, G18S-2, G20SC-2 GC15S-2, GC18S-2, GC20SC-2 D15S-2, D18S-2, D20SC-2 B16X, B18X, B20X B13T-2, B15T-2, B18T-2, B15S, B18S B20T-2 Important Safety Information Most accidents involving product operation, maintenance and repair are caused by failure to observe basic safety rules or precautions. An accident can often be avoided by recognizing potentially hazardous situations before an accident occurs. A person must be alert to potential hazards. This person should also have the necessary training, skills and tools to perform these functions properly. Read and understand all safety precautions and warnings before operating or performing lubrication, maintenance and repair on this product. Basic safety precautions are listed in the “Safety” section of the Service or Technical Manual. Additional safety precautions are listed in the “Safety” section of the owner/operation/maintenance publication. Specific safety warnings for all these publications are provided in the description of operations where hazards exist. WARNING labels have also been put on the product to provide instructions and to identify specific hazards. If these hazard warnings are not heeded, bodily injury or death could occur to you or other persons. Warnings in this publication and on the product labels are identified by the following symbol. WARNING IImproper operation, lubrication, maintenance or repair of this product can be dangerous and could result in injury or death. Do not operate or perform any lubrication, maintenance or repair on this product, until you have read and understood the operation, lubrication, maintenance and repair information. Operations that may cause product damage are identified by NOTICE labels on the product and in this publication. DAEWOO cannot anticipate every possible circumstance that might involve a potential hazard. The warnings in this publication and on the product are therefore not all inclusive. If a tool, procedure, work method or operating technique not specifically recommended by DAEWOO is used, you must satisfy yourself that it is safe for you and others. You should also ensure that the product will not be damaged or made unsafe by the operation, lubrication, maintenance or repair procedures you choose. The information, specifications, and illustrations in this publication are on the basis of information available at the time it was written. The specifications, torques, pressures, measurements, adjustments, illustrations, and other items can change at any time. These changes can affect the service given to the product. Obtain the complete and most current information before starting any job. DAEWOO dealers have the most current information available. 1 Index Disassembly & Assembly Forks.........................................................................5 Backrest....................................................................5 Carriage....................................................................6 Mast..........................................................................9 Testing & Adjusting Carriage Adjustment...............................................22 Chain Adjustments .................................................23 Chain Wear Test.....................................................23 Carriage and Mast Height Adjustment ........................24 Forks Parallel Check ..............................................24 Tilt Cylinder Alignment............................................25 Drift Test .................................................................25 Tilt Cylinder Adjustment..........................................26 Lift & Tilt Mounting Group Adjustment....................27 Mast mounting Group Adjustment..........................28 Lift Trucks Mast System 3 Index Backrest Disassembly & Assembly Remove & Install Backrest Forks Remove & Install Forks 1 1 3 2 IBCD501P 2 1. Fasten a hoist to the backrest. Remove bolts(2) that fasten the backrest to the carriage. IDCD001P 2. Remove backrest (1). Backrest weighs 32 kg (71 lb). 3. Install backrest(1) in the reverse order of removal. IDCD002P 1. Remove stopper bolt and washer (3). 2. Lift fork pin (1). 3. Use a suitable C-clamp, strap and hoist to support the fork as shown. 4. Slide the fork to slot (2) in the middle of the carriage. 5. Remove the fork. The weight of the fork is 35 kg (77 lb). 6. Repeat steps 1 through 4 for the remaining fork. 7. Install the forks in the reverse order of removal. 8. Put the forks in position. Lower both fork pins(1) to lock the forks in position. 9. Install stopper bolt and washer (3). Lift Trucks Mast System 5 Disassembly & Assembly Carriage Remove & Install Carriage Start By: a. Remove forks. b. Remove backrest. IBCD504P 7 6 4. Remove two nuts (6). Remove carriage stop bolt (7). 2 1 9 4 3 IBCD502P 1. Remove two bolts (1) and hose guard (2) from the cross head (3). 2. Remove cross head (3) from the cylinder rod (4). 8 IBCD510P 5. Raise the inner mast to pull out carriage as shown. 5 6. Remove carriage from bottom of inner mast (9). Carriage weighs 64kg (141 lb). IBCD503P 3. Remove hoses (5). NOTE: Use the following steps to install the carriage. 7. Raise the inner mast (9) to put in the carriage (8) onto the mast, and lower the inner mast to cover carriage bearing fully. Lift Trucks Mast System 6 Disassembly & Assembly End By: a. Install backrest. b. Install forks. Disassemble Carriage 7 IBCD504P Start By: 6 a. Remove carriage. 8. Install stop bolt (7). Shim stop bolt as required to obtain a 4 to 6 mm (.157 to .242 in) lap with top carriage stop on the inner upright. 1 9. Put the chains in position over cross head. Install nuts(6) onto the chain anchors to a torque of 300 L 30 NIIm (220 L 22 lbIIft). IBCD571P 2 1. Remove the roll pins and pins(2) to disconnect chains(1). 5 IBCD503P 3 10. Install hoses (5). 2 IBCD572P 1 2. Remove lower roller bearings(3) and the shims from the carriage. 4 3 IBCD502P 11. Install cross head (3) to cylinder rod (4). 12. Install hose guard (2) and bolts (1) to a torque of 8 L 2 NIIm (6 L 1.5 lbIIft). Lift Trucks Mast System 7 Disassembly & Assembly 1. Select bearings from the chart to obtain minimum clearance (C) between bearings and channel leg for full channel length. Use same bearing at all four locations. 7 4 8 CARRIAGE BEARING CHART 9 5 6 IBCD573P Part No. Bearing Size Bearing O.D.* D580006 Undersize 98.5 mm (3.878 in) D580007 Standard 99.0 mm (3.898 in) D580008 Oversize 99.5 mm (3.917 in) * Permissible tolerance of L 0.08 mm (.003in) 3. Remove screw(5) and washer(4). Remove two top roller bearings(6) and the shims. Refer to carriage Adjustment in Testing & Adjusting. 4. Remove bolt (7), washer, pin-adjust (8) and sideroller bearing (9) from the carriage. Assemble Carriage NOTE : The standard, Full Free Lift and Full Free Triple Lift carriage load bearings are all adjusted the same way. The Full Free Triple Lift carriage is shown in the following illustrations. To make the carriage clearance adjustments, carriage must be removed from the mast. IBCD543P Use the procedure that follows to adjust carriage load bearings. A A B A 2. Find narrowest point by ruler on the inner mast in the area where the bearings make contact. 1 4 5(STD) 3 A C D C B B C 5 (FF, FFT) 6 VIEW A-A C C 7 10 9 8 IBCD574P 2 A VIEW C-C IBCD581I VIEW B-B 3. Install enough shims (1) that have been divided into two equal groups behind bearings (2). At installation, there is to be contact [zero clearance (A)] between the bearings and the narrowest point of inner mast. Carriage Adjustment (3) Upper bearings. (4) Shims. (5) Bolt. (6) Screw. (7) Side-roller bearings. (8) Lower bearings. (9) Pin-adjust. (10) Bolt. (A) Zero clearance. (B) 4.0 to 6.0 mm. (.157 to .242 in) clearance. (C) Minimum clearance. (D) 4.5 L 0.5 mm Lift Trucks Mast System 4. Do step 2 through 3 for other sets of bearings. 8 Disassembly & Assembly Mast 4 Remove & Install Mast Start By: a. Remove forks. Move the truck to the place where pit is set up. 3 IDCD016P 5. Tighten screw (3) that holds the top and middle bearings (4) to the carriage to a torque of 34 L 7 NIm (25 L 5 lbIft). 1 2 6 IBCD511P 1. Support mast assembly(2) with a hoist and strap (1) as shown. IBCD571P 5 6. Position chains (6) on the carriage. Install pins (5) and the roll pins. 3 End By: a. Install carriage, raise the inner mast and insert the carriage from the bottom of inner mast. IBCD512P NOTICE Place identification marks on all hydraulic connectors and hoses to assure proper installation. Plug and cap all hydraulic connectors and hoses to avoid debris and contamination from entering the system. 2. Disconnect hose(3). NOTE : For B15/18/20T-2(36V), see article 6 prior to disconnecting hose (3). Lift Trucks Mast System 9 Disassembly & Assembly 9 6 IBCD513P 5 4 8 WARNING IBCD502S Tilt cylinders (4) can drop when pin(6) is removed. To avoid component damage or personal injury, support tilt cylinder (4) while removing pin(6). 6. B15/18/20T-2(36V) Raise the carriage and mast to open outer lower part. Remove bolt (9) from the front of mast each side. Remove bolt (8) from the pit each side. Disconnect hose (3) of article 2. 3. Remove bolt (5) from each side of mast assembly (2). 4. Remove pin (6) from the tilt cylinders on each side of the mast assembly. 103 7 IBCD582I IBCD514P 7. B16/18/20X, B13/15/18/20T-2(48V) Tilt forward mast assembly with the hoist. Remove bolts (8) from each side. 5. D,G15/18/20S(C)-2, GC15/18/20S(C)-2, B15/18S Tilt forward mast assembly about 8° with the hoist. Remove four bolts (7) from pit each side of the base of mast assembly. WARNING Loosen the tension of straps to be connected with hoist when mast assembly is tilted forward. If straps are too tight, mast assembly could slide off when bolts (7), (8), (10) are removed. 8. Use the hoist to remove mast assembly from the truck. 9. Install the mast in the reverse order of removal. End By: a. Install forks. Lift Trucks Mast System 10 Disassembly & Assembly Disassemble Mast Start By: a. Remove lift chain to be connected primary lift cylinder. b. Remove primary lift cylinder. 5 NOTE: The following disassembly and assembly procedure is for a full free triple lift mast. IBCD520P 4. Disconnect and remove chains(5) from the bottom of the mast. 2 7 6 1 IBCD518P 1. Remove hoses (1) along with the hose support clamps (2). 8 IBCD521P 5. Remove clamp (6) and bolt (7) from stationary mast and disconnect regulator (8) from secondary cylinder(For D,G15/18/20S(C)-2, GC15/18/20S(C)-2, B15/18S). 3 2 4 10 IBCD519P 2. Remove hose sheave (3). 9 3. Remove chain nut(4) from the top of the mast (each side). 10 IBCD504S 6. Remove tube ass’y (9) and bolt (10) from stationary mast and disconnect regulator (8) from secondary cylinder (For B13/15/18/20T-2, B16/18/20X). Lift Trucks Mast System 11 Disassembly & Assembly 15 IBCD523P 11 16 7. Remove top cylinder retainer bolts (11) from each side of the mast. 17 D,G15/18/20S(C)-2, GC15/18/20S(C)-2, B15/18S 12 16 IBCD524P 8. Remove cylinder retainer brackets(12) from each cylinder. 15 17 B15/18/20T-2(36V) IBCD527P 13 9. Remove secondary cylinders(13). Each cylinder weighs 38 kg (84 lb). 17 14 B16/18/20X, B13/15/18/20T-2(48V) IBCD584I 11. Remove bearing mounting pins(15) and screw (16) from the mast lower hinge mounting part. IBCD526P 12. Check the condition of the bearings(17) located in each of the mast mounting bracket. Replace the bearings (17) with new if worn or damaged. 10. Check the condition of bearings(14) located in each of the tilt cylinder pin bores. Replace bearings(14) with new if worn or damaged. Lift Trucks Mast System 12 Disassembly & Assembly 24 21 24 22 18 23 19 IBCD528P IBCD534P 13. Move inner mast channel (21) downward. 18. Move intermediate mast channel (24) downward. 14. Remove bearings (18) and shims from the intermediate mast channel (24). 19. Remove bearings (22) and the shims from the stationary mast channel. 15. Remove nylon pads (19) and shims. 20. Remove nylon pads (23) and the shims. 20 24 25 IBCD533P IBCD529P 21. Remove bearings (25) and the shims from the intermediate mast channel (24). 16. Remove bearings (20) and shims from the inner mast channel (21). 21 24 IBCD535P IBCD530P 22. Fasten nylon straps and a hoist to the intermediate mast channel (24). Remove intermediate mast channel. The intermediate mast channel weighs 112kg (247 lb). 17. Fasten nylon straps and hoist to inner channel (21). Remove inner channel. The weight of the inner channel is 110 kg (243 lb). Lift Trucks Mast System 13 Disassembly & Assembly Assemble Mast NOTE: The standard, Full Free Lift and Full Free Triple Lift mast load bearings are all adjusted the same way. The mast shown in the following illustrations is the Full Free Triple Lift mast. 1. Make sure all parts are clean and free of dirt and foreign material. 2. Check all parts for damage, use new parts for replacement. IBCD541P A. Lower Bearing Adjustment of Intermediate Mast 4 5 4. Find narrowest point by ruler on the stationary mast in the area where the bearings make contact at 420 mm (16.5 in) channel lap. NOTICE When the correct amount of shim has been installed behind bearings (1) there will be contact (zero clearance) between the bearings and the inner mast at most narrow point of mast. 6 3 A C B IBCD505S Mast Adjustment Lower Bearings (A) Zero clearance. (B) Minimum clearance. (C) Zero clearance. (3) Bearing. (4) Bearing. (5) Shims. (6) Shims. IBCD535P 5. Lifting by crane, insert intermediate mast into stationary mast from the upper side. 3. Select lower bearings (3) and (4) from the chart to obtain minimum clearance (B) between bearing and channel leg for full channel length. Use same bearing on left and right side. Mast And Carriage Bearings Part No. Bearingsize Bearing O.D.* D580006 Undersize 98.5 mm (3.878 in) D580007 Standard 99.0 mm (3.898 in) D580008 Oversize 99.5 mm (3.917 in) * Permissible tolerance L 0.08 mm (.003 in) Lift Trucks Mast System 14 Disassembly & Assembly 1 4 3 IBCD534P IBCD533P 9. Install 1mm shim and bearing (4) of intermediate lower basically. 6. Install 1mm shim and bearing (1) of stationary upper basically. 2 1 4 5 6 3 IBCD538P A NOTE: When installing shims (2) behind bearings (1), make sure the amount of shim is divided equally when positioned behind each bearing. B 7. Install the correct amount of shim (2) behind rollers until contact (zero clearance) is made between the bearings. C IBCD505S 8. Install pads (3) to each side. Refer to “Upper Pad Adjustment” of Disassebly & Assembly. Mast Adjustment Lower Bearings (A) Zero clearance. (B) Minimum clearance. (C) Zero clearance. (3) Bearing. (4) Bearing. (5) Shims. (6) Shims. NOTE: When installing shims (5) behind bearings (4), make sure the amount of shim is divided equally when positioned behind each bearing (4). Lift Trucks Mast System 15 Disassembly & Assembly IBCD531P IBCD534P 13. Install 1 mm shim to each bearing of stationary mast upper basically. Bearing should be selected D580006 undersize bearing. 10. Make sure intermediate mast lower bearings are properly shimmed in the stationary mast by rolling up and down and moving intermediate mast to right and left. If clearance between both masts can be detected, pull out the intermediate mast from the stationary mast with crane and add shim 0.5 mm or 1 mm to both intermediate lower bearings. 4 11. In case of standard and full free mast, inner lower bearings can be easily extruded by pulling down the inner mast from the bottom of stationary mast. If intermediate mast is stuck and cannot move by rolling up and down, there might be excessive shim. Pull out the intermediate mast from the stationary mast and remove shim 0.5 mm to both intermediate lower bearings. Repeat same procedure of above until properly shimmed. There is to be contact zero clearance (C) between intermediate lower bearings and stationary channel at approximately 420 mm (16.5 in) channel lap. IBCD533P 14. Install 1mm shim and bearing (4) of intermediate lower basically. B. Upper Bearing Adjustment of Stationary Mast IBCD535P 12. Lift by crane, insert intermediate mast into stationary mast from the upper side. Lift Trucks Mast System 16 Disassembly & Assembly Repeat same procedure of above until properly shimmed. There is to be contact zero clearance (F) between stationary upper bearings and the widest point of intermediate mast to be checked before. D E 7 C. Upper Pad Adjustment 8 E F 7 7 8 9 10 E 8 F 7 IBCD506S 9 Mast Adjustment Upper Bearings (D) Zero clearance. (E) 0.80 mm (.031 in) Clearance maximum. (F) Zero clearance. (7) Pads. (8) Shims. (9) Shims. (10) Shims. 8 10 E IBCD506S Mast Adjustment Upper Bearings (D) Zero clearance. (E) 0.80 mm (.031 in) Clearance maximum. (F) Zero clearance. (7) Pads. (8) Shims. (9) Shims. (10) Shims. 17. Install shims (8) behind each pad (7) until there is 0.80 mm (.031 in) maximum clearance (E) between the pads and the inner and intermediate masts with the masts at full extension. Lift by crane, and pull out intermediate mast from stationary mast and insert the shims behind each pad. In case of standard and full free mast, the pads of stationary upper can be easily extruded by pulling down the inner mast from the bottom of stationary mast. IBCD532P 15. Make sure stationary mast upper bearings are properly shimmed by rolling up and down and moving intermediate mast to right and left. If clearance between both masts can be detected, pull out the intermediate mast from the stationary mast with crane and add shim 0.5 mm or 1 mm to both stationary upper bearings. 16. In case of standard and full free mast, stationary upper bearings can be easily extruded by pulling down the inner mast from the bottom of stationary mast. If intermediate mast is stuck and cannot move by rolling up and down, there might be excessive shim. Pull out the intermediate mast from the stationary mast and remove shim 0.5 mm to both stationary upper bearings. Lift Trucks Mast System 17 Disassembly & Assembly D. Lower Bearing Adjustment of Inner Mast 4 5 6 3 IBCD542P A 19. Find narrowest point by ruler on the intermediate mast in the area where the inner lower bearings make contact full length of intermediate mast excluding minimum channel lap 420 mm (16.5 in). C B 12 11 IBCD505S Mast Adjustment Lower Bearings (A) Zero clearance. (B)Minimum clearance. (C)Zero clearance. (3)Bearing. (4)Bearing. (5)Shims. (6)Shims. IBCD530P 18. Select lower bearings (3) and (4) from the chart to obtain minimum clearance (B) between bearing and channel leg for full channel length. Use same bearing on left and right side. 20. Lifting by crane, insert inner mast (11) into intermediate mast (12) from the upper side. Mast And Carriage Bearings Part No. Bearing Size Bearing O.D.* D580006 Undersize 98.5 mm (3.878 in) D580007 Standard 99.0 mm (3.898 in) D580008 Oversize 99.5 mm (3.917 in) 13 * Permissible tolerance L 0.08mm (.003in) IBCD528P 21. Install 1 mm shim and bearing (13) of intermediate upper basically. Lift Trucks Mast System 18 Disassembly & Assembly E. Upper Bearing Adjustment of intermediate Mast 14 Follow same procedure with above B. F. Upper Pad Adjustment of Intermediate Mast Follow same procedure with above C. 24. If the bearings were removed from the mast mounting brackets, install new ones. IBCD529P 25. Put a small amount of clean grease on mounting bearing. Install mounting pins and screw into mast mounting brackets. Refer to Mast Mounting Group Adjustment of Testing & Adjusting. 22. Install 1mm shim and bearing (14) of inner lower basically. 4 5 6 3 A 15 B IBCD526P C 26. If the bearings were removed from the tilt cylinder pin bores (15), install new ones. IBCD505S Mast Adjustment Lower Bearings (A) Zero clearance. (B) Minimum clearance. (C) Zero clearance. (3) Bearing. (4) Bearing. (5) Shims. (6) Shims. 23. Make sure inner mast lower bearings are properly shimmed in the intermediate mast by rolling up and down and moving inner mast to right and left. If clearance between both masts can be detected, pull down the inner mast from the bottom of intermediate mast. Inner lower bearings can be easily extruded. Add shim 0.5 mm or 1 mm to both inner lower bearings. If inner mast is stuck and cannot move by rolling up and down, there might be excessive shim. Pull out the inner mast from the intermediate mast and remove shim 0.5 mm to both inner lower bearings. Repeat same procedure of above until properly shimmed. There is to be contact zero clearance (C) between inner lower bearings and intermediate channel at narrowest point. Lift Trucks Mast System 16 IBCD527P 27. Install secondary cylinders (16) into the stationary mast. 19 Disassembly & Assembly 24 10 17 9 23 IBCD524P 22 10 28. Install secondary cylinder mounting brackets (17) over the secondary cylinders. IBCD504S 31. Install regulator (22) to secondary cylinder and tube ass’y (23) and bolts (24) to stationary mast. (For B13/15/18/20T-2, B16/18/20X) 18 IBCD523P 29. Install top cylinder retainer bolts (18) for the secondary cylinders. 25 IBCD520P 20 32. Connect chains (25) at the bottom of the mast. 19 21 27 IBCD521P 30. Install regulator (21) to secondary cylinder and clamp (19) and bolt (20) to stationary mast. (For D,G15/18/20S(C)-2, GC15/18/20S(C)-2, B15/18S) 26 IBCD519P 33. Connect chains (26) at the chain bracket of stationary mast upper. 34. Install sheave (27) of lift hose. Lift Trucks Mast System 20 Disassembly & Assembly 28 IBCD518P 35. Install hoses (28) along with the hose support clamps. End by : a. Install primary lift cylinder. b. Install lift chain to be connected primary lift cylinder. Lift Trucks Mast System 21 Disassembly & Assembly Testing & Adjusting Mast And Carriage Bearings Carriage Adjustment NOTE: The standard, Full Free Lift and Full Free Triple Lift carriage load bearings are all adjusted the same way. The Full Free Triple Lift carriage is shown in the following illustrations. A A D580006 Undersize 98.5 mm (3.878 in) D580007 Standard 99.0 mm (3.898 in) D580008 Oversize 99.5 mm (3.917 in) 4. Shim bolt as needed to obtain a 4.0 to 6.0 mm (.157 to .242 in) overlap (B) between bolt (3) and the carriage stop on the inner upright. (See Carriage Adjustment in Testing & Adjusting). 4 5(STD) B Bearing O.D.* 3. Equally shim both sides until contact (A) is made (zero clearance) between bearings and inner mast at narrowest point Use the procedure that follows to adjust carriage load bearings. A Bearing Size * Permissible tolerance of L 0.08mm (.003in) To make the carriage clearance adjustments, carriage must be removed from the mast. A Part No. 3 C D 5. Torque for screw.............34 L 7 NIm (25 L 5 lbIft) C 6. Refer to “Carriage Assembly” of Disassembly & Assembly. C B B 6 5 (FF, FFT) VIEW A-A C C 7 10 9 8 A VIEW C-C VIEW B-B IBCD581I Carriage Adjustment (3) Upper Bearings. (4) Shims. (5) Bolt. (6) Screw. (7) Side-roller Bearings. (8) Lower Bearings. (9) Pin-adjust. (10) Bolt. (A) Zero Clearance. (B) 4.0 to 6.0 mm. (.157 to .242 in) Clearance. (C) Minimum Clearance. (D) 4.5 L 0.5 mm 1. Select lower bearings from the chart to obtain minimum clearance (C) between bearings and channel leg for full channel length. Use same bearing in all two locations. 2. Select upper bearing from the chart to obtain minimum clearance (C) between bearings and channel leg for full channel length. Use same bearing at all two locations. (For G20SC-2, GC20SC-2, B20T, D20SC-2, and B20X, bearings are same with upper, middle 4 locations.) Lift Trucks Mast Systems 22 Testing & Adjusting 2. Make adjustments to chain anchor nuts (1) or bolts (2) for equal tension of the mast and carriage chains. Chain Adjustments Chain Adjustment Check 3. Put LOCTITE NO.242 Thread Lock on the threads of the locknuts after the adjustment is completed. IBCD505P 2 IBCD508P Lift the carriage and mast high enough to put their full weight on the carriage and mast chains. Check the chains, and make sure the tension is the same. Outer Lift Chains (2) Chain Anchor Bolts. Chain Adjustment Chain Wear Test If the tension is not the same on both chains, do the procedure that follows: Chain wear test is a measurement of wear of the chain links and pins. Do the steps that follow to check chain wear. WARNING 1. Lift the mast and carriage enough to put tension on the lift chains. Personal injury can be caused by sudden movement of the mast and carriage. Blocks must be used to prevent the mast and carriage from any movement while the adjustments are made. Keep hands and feet clear of any parts that can move. 2. Measure precisely ten links of chain distance at the center of pins in millimeter. A chain wear gauge can also be used. 3. Calculate chain wear rate. New one pitch = 15.88 mm Chain wear rate (%) Actual measurement - 158.8 = 158.8 x 100 WARNING Do not put a lift truck into service if the chain wear indication is 2% or more. A reading of 2% or more could cause damage or injury to persons. 1 IBCD506P Inner Lift Chains (1) Chain Anchor Nuts. 4. If the chain wear indication is 2% or more, replace the lift chain. 1. Lift the mast and carriage and put blocks under the mast and carriage to release the tension from the lift chains. Lift Trucks Mast Systems 23 Testing & Adjusting Carriage and Mast Height Adjustment Forks Parallel Check 1. Move the mast either forward or backward so it is in the vertical position. 1. Lift the mast and operate the tilt control lever, until the top surface of the forks is parallel with the floor. Place two straight bars, that are the same width as the carriage, across the forks as shown. Measure the distance from the bottom of each end of the two bars to the floor. The forks must be parallel within 3 mm (.12 in) for Full Tapered and Polished (FTP) forks, all other forks 6.4 mm (.25 in), for their complete length. 2. Lower the carriage completely. 2. If not parallel, determine which one is defective and replace it. A IDCS130S Forks Parallel Check (Typical Example) IBCD585I 3. On Full Free Lift and Full Free Triple Lift models, the bottom of the inner mast must be even with the bottom of the stationary mast. 4. Measure the distance from the bottom of the inner upright to the bottom of carriage bearing end. 5. The measurement (A) must be as follows: <STD> D,G15/18/20S(C)-2.......................22 mm(0.866 in) B15/18S .........................................7 mm (0.276 in) B16/18/20X, GC15/18/20S(C)-2, B13/15/18/20T-2 ..........................- 6 mm(-0.236 in) <FFL & FFTL> D, G15/18/20S(C)-2......................36 mm (1.417in) B15/18S .......................................21 mm (0.827 in) GC15/18/20S(C)-2 .......................11 mm (0.433 in) B16/18/20X, B13/15/18/20T-2 NOTE : If the above measurements are not correct, make adjustments to the chains to get the correct measurement. See Chain Adjustments in TESTING AND ADJUSTING. Lift Trucks Mast Systems 24 Testing & Adjusting Tilt Cylinder Length Check Tilt Cylinder Alignment If the tilt cylinders are out of alignment, extra stresses in the mast assembly and the mast hinge area will result. To prevent damage, the tilt cylinders must stop evenly at the end of the tilt back and tilt forward strokes. Tilt Angle Check IDCD009P 1. Tilt the mast to full forward position. Measure the extended length of the cylinder rods from the cylinder housing to the mast. The difference of length between the two cylinder rods must be within 3.18 mm (.125 in) of each other. IDCD008P Tilt Angle Check (Typical Example) Drift Test The tilt angle of the mast must be checked in the full tilt back and full tilt forward positions. A tilt indicator or a protractor can be used to measure the angle. Both sides of the mast must be checked to make sure that the mast is not twisted. Drift is movement of the mast or carriage that is the result of hydraulic leakage in the cylinders or control valve. Before testing the drift: The tilt angle is determined by the tilt cylinders used. See tilt cylinders in specifications to determine the tilt angle from the cylinder being used. WARNING Personal injury can be caused by sudden movement of the mast or carriage. Use wood blocks and clamps to hold the mast in this position. Keep hands and feet clear of any parts that can move. 1. Check the chain adjustment and tilt cylinder alignment and make necessary adjustments. 2. Lift the mast approximately 762 mm (30 in). Use wood blocks and clamps to hold the mast in this position. 3. Check the mast hinge bolts to make sure they are tight. 4. Remove the blocks and clamps and lower the mast. Lift Trucks Mast Systems 25 Testing & Adjusting Drift Test For Lift System 1. Secure a rated capacity load on the forks of the lift truck. Operate the lift truck through a complete lift and tilt cycle until the oil is at normal temperature of operation, 45 to 55 °C (113 to 131 °F). 2 2. Put the mast in a vertical position. Raise a rated capacity load to a sufficient height to test the lift cylinders. 3 3. Measure any drift of the carriage for a ten minute period. Drift for all models shall not exceed 100.0 mm (4.00 in). 1 IBCD513P Tilt Cylinder Adjustment (1) Pivot eye. (2) Bolt. (3) Rod. 1. Loosen bolt (2) at pivot eye (1). Tilt Cylinder Adjustment 2. Turn rod (3) into or out of pivot eye (1) to obtain the correct length. The minimum length from the end of rod to the rear face of eye is 16 mm. WARNING Tilt cylinder pivot eyes can loosen if the torque on the pivot eye clamping bolt is not tight enough. This will let the tilt cylinder rod turn in the tilt cylinder eye. The cylinder rod may twist out of the pivot eye and the tilt cylinder will be out of alignment or may let the mast fall and cause personal injury or damage. When the rod lengths are made even, the tilt angle differences or the mast alignment will no longer be a problem. 16mm To correct the tilt angle or tilt cylinder length, an adjustment must be made to the tilt cylinder as follows : EHCS046S 3. Tighten bolt (2) and the nut to a torque of 95 L 15 N•m (70 L 10 lb•ft). Lift Trucks Mast Systems 26 Testing & Adjusting (1) With chains adjusted for equal tension, run mast to full lift. If mast does not kick (move) to one side, no shims are needed. If mast does kick (move) to one side, disconnect cylinder from the bar on that side. Add shim, connect cylinder, adjust chains and run mast to full lift to check for kick. Repeat process if necessary. The total shim pack must not be more than three shims maximum. Lift & Tilt Mounting Group Adjustment (2) Install bearing outer race to a depth of (F) ............................4.5 L 0.8 mm (.177 L .031 in). A (3) Tilt cylinder installation shown. (4) (Full Free Lift Mast Only): Tighten nuts until U-bolt is firm against cylinder, do not apply standard torque. 1 3 VIEW A-A B B 2 (F) VIEW B-B 4 IBCD508S Lift Trucks Mast Systems 27 Testing & Adjusting Mast mounting Group Adjustment 2 3 2 1 IBCD502S For B15/18/20T-2(36V) 1 3 IBCD509S For D,G15/18/20S(C)-2, GC15/18/20S(C)-2 3 2 IBCD582I For B16/18/20X, B13/15/18/20T-2(48V) 1 3 1. Tighten screw (1) that holds bearing (3) to hinge bracket of stationary mast to a torque of 34 L7 NIm (25 L 5 lbIft). IBCD510S 2. Install roll pin (2) to a depth 2 ~ 3 mm (0.079 ~ 0.118 in) from surface of bearing. For B15/18S 3. Apply the crean grease to a surface of bearing. 4. Apply Loctite No242 to bolts and tighten with a torque 180 L 20 NIm (130 L 15 lbIft). Lift Trucks Mast Systems 28 Testing & Adjusting SB2315E02 6. 2002 Operation & Maintenance Manual LIFT TRUCKS B13T-2, B15T-2, B18T-2, B20T-2 (48V) B15T-2, B18T-2, B20T-2 (36V) Information Section Table of Contents Information Section Maintenance Section Table of Contents..................................................1 Foreword ...............................................................2 Inspection, Maintenance and Repair of Lift Truck Fork...................................................................... 66 Tire Inflation Information .................................... 70 Torque Specifications......................................... 71 Lubricant Specifications ..................................... 73 Battery Discharge Indicator ................................ 76 Battery ................................................................ 77 Cold Storage Applications .................................. 79 Lubricant Viscosities and Refill Capacities......... 80 Maintenance Intervals ........................................ 81 When Required .................................................. 83 Every 10 Service Hours or Daily ...................... 101 First 50 -100 Service Hours or a Week ............ 107 First 250 Service Hours or a Month ................. 109 Every 250 Service Hours or Monthly................ 110 Every 500 Service Hours or 3 Months ............. 114 Every 1000 Service Hours or 6 Months ........... 119 Every 2000 Service Hours or Yearly ................ 126 Every 2500 Service Hours or 15 Months ......... 130 Safety Section Owner/Operator Safety Overview .........................4 Safety Information .................................................9 Safety Operating Practices ...............................9 Capacity/Nameplate........................................10 Warning Signs and Labels ..............................10 General Hazard Information............................14 Operating Safety .............................................18 Operator Restraint System .............................19 Avoiding Lift Truck Tipovers............................22 How to Survive in a Tipover ............................27 General Section Specifications ......................................................29 Noise and Vibration.............................................32 Capacity Chart ....................................................33 Serial Number .....................................................37 Operator’s Warning and Identification Plate .......38 Environment Protection Section Environment Protection .................................... 132 Index Section Operation Section Index ................................................................ 133 Operator's Station and Monitoring Systems........40 Lift Truck Controls ...............................................46 Before Operating the Lift Truck ...........................50 Lift Truck Operation ............................................53 Operating Techniques.........................................56 Parking the Lift Truck ..........................................60 Lift Fork Adjustment ............................................62 Storage Information ............................................63 Transportation Hints............................................64 Towing Information .............................................65 • WORLDWIDE NETWORK -1- Information Section Foreword About This Manual About Safety Section This manual tells you how to operate your DAEWOO lift truck safely and maintain it for long truck life. Keep the manual in the storage pocket of the seat so you can easily refer to it. We recommend that all operators carefully read and understand this manual before operating the lift truck. Both new and experienced operators will find its information useful. The first two sections of this manual discuss safety. First is an overview of owner and operator responsibilities, along with a summary of OSHA/ ASME expectations. It also presents some suggestions for operator training. The second safety section gives you basic safety precautions. It also shows you where to find warning labels used on the lift truck. The warnings are reproduced here for you to read. You may notice slight differences between your lift truck and trucks as they are shown and described in this manual. This is normal. Because we strive continuously to improve our lift trucks, your lift truck may include advancements not presented here. And, sometimes we remove guards and covers to show details we couldn’t otherwise. Before you operate or perform any maintenance on this lift truck, read the safety information sections carefully. Also locate and read the warning decal’s on the truck itself. Operator Restraint System(If Equipped) If you ever have questions about your truck or about this manual, your DAEWOO dealer can provide you with latest available information. Forklift trucks seldom tipover, but in the rare event they do, the operator may be pinned to the ground by the lift truck or the overhead guard. This could result in serious injury or death. Operator training and safety awareness is an effective way to prevent accidents, but accidents can stil happen. The DAEWOO operator restraint system can minimize injuries. The DAEWOO operator restraint system keeps the operator substantially within the confines of the operator’s compartment and the overhead guard. Photographs or illutrations in this section guide the operator through correct procedures of checking, operation and maintenance of the DAEWOO operator restraint system. About General Section This section tells you where to locate the various serial numbers on your machine. Space is provided for you to record the numbers right in this book for easy reference should you ever need the numbers for identification, warranty work, parts ordering, and so on. We also explain here (and also in the safety section) the importance of your machine’s capacity load. -2- Information Section About Operation Section About Environment Section This section tells you about checking, starting, operating, and stopping the lift truck. It describes lift truck controls, gauges, and switches. It has information about transporting and towing your lift truck. Protection Note that Daewoo Industrial Vehicle Division is ISO 14001 certified which is harmonized with ISO 9001. Periodic Environmental Audits & Environmental Performance Evaluations have been made by internal and external inspection entities. Life-cycle Analysis has also been made through out the total product life. Environmental Management System includes Design for Environment from the initial stage of the design. Remember, however, the operating techniques presented here are basic. Skill comes with experience and training in using the lift truck and learning what it can and cannot do. Environment Management System considers environmental laws & regulations,reduction or elimination of resource consumption as well as environmental emission or pollution from industrial activities, energy saving, environment-friendly product design(lower noise, vibration, emission, smoke, heavy metal free, ozone depleting substance free, etc.), recycling, material cost reduction, and even environmentally oriented education for the employee. About Maintenance Section The Maintenance Section tells you how to service the lift truck. Topics are organized by service intervals. Items without specific intervals are listed under “When Required”. Maintenance Intervals We recommend using the truck service hour meter to determine servicing intervals. You may also use calendar intervals (daily, weekly, monthly, etc.) if this is more convenient. Calendar intervals should come as close as possible to service hour meter intervals. Perform service at whichever interval comes first. Also note the following : • If you operate your truck under extremely dusty or wet conditions, lubricate it more often than is specified in the “Maintenance Interval” chart. • At each higher interval, also service the items serviced at all previous intervals. For example, at “Every 500 Service Hours or 3 Months,” also service those items listed under “Every 250 Service Hours or Monthly,” and “Every 10 Service Hours or Daily”. -3- Safety Section Owner/Operator Safety Overview Safety Message for Owner and Operators for the lift truck operator to be familiar with the proper operation of the lift truck, to be alert and to avoid actions or conditions which can result in an accident. Your DAEWOO equipment has been designed with the safety of the persons who will operate and service it in mind. However, our care in designing this equipment does not guarantee that it will be used in a safe manner. Safe operating practice is where your responsibility and the responsible actions of the persons who operate and maintain this equipment take over. Do not operate a lift truck if in need of repair, defective or in any way unsafe. Report all defects and unsafe conditions immediately. Do not attempt any adjustments or repairs unless trained and authorized to do so. Owner/Employer Responsibility The safety rules and regulations in this section are representative of some, but not all rules and regulations noted under the Occupational Safety and Health Act (OSHA) and are paraphrased without representation that the OSHA rules and regulations have been reproduced verbatim. Both the proposed Occupational Safety and Health Act (OSHA) and the American Society of Mechanical Engineers (ASME) make you, the employer, responsible for providing formal training and a safe workplace environment for the use of this equipment. Your responsibility includes establishing daily inspections and scheduled maintenance practices to ensure the equipment’s ongoing safe operating condition. Please refer to 1910. 178 in Federal Register Vol. 37, No. 202, the National Fire Protection Association No. 505 (NFPA), American Mational Standard, ANSI B56. 1 Safety Standard for Low lift and High Lift Trucks and subsequent revisions for a complete list of OSHA rules and regulations as to the safe operation of powered industrial lift trucks. Since regulations vary from contry to country outside in U.S.A., operate this lift truck in accordance with local regulations. This manual is intended to help you meet your responsibilities. It identifies warning labels on the equipment and explains what they mean. It describes some of the general and specific hazards to be aware of when operating the equipment. It also offers some suggestions for establishing workplace rules and operator training programs. Proposed changes to OSHA Safety and Health Standards (29 CFR 1910) would adopt the ASME B56.1a - 1995 Consensus Safety Standard for Low Lift and High Lift Trucks. As the owner/employer, you have the additional responsibility to be certain that the equipment you have placed into service is capable of doing its intended job. This includes matching equipment design to working conditions, capacity to the size of loads it will be handling, and selecting suitable attachments and options. This section of the manual discusses these issues as well. At the end of this overview, we list specific OSHA, ASME, UL, NFPA and other published resources you can consult for ways to help you comply with safety requirements for the use of this equipment in your workplace. ASME B56.1a - 1995, Part II, Section 4 (General Safety Practices), and Section 5 (Operating Safety Rules and Practices) contains requirements for the users (Owners and Operators) of powered industrial trucks. Requirements include : Operator qualifications and training, operating safety rules, and maintenance practices. DAEWOO lift trucks are manufactured according to the regulations and standards laid down in EU Machinery Directive 98/37/EC and EMC directive 89/336//EC. Please refer to the Directives 89/6555/ EC and 89/391/EC and its amendments for the safe use of DAEWOO lift trucks. The most effective method of preventing serious injury or death to the lift truck operator or others is -4- Safety Section Operator Responsibility Maintaining a Safe Workplace If your job includes operating this equipment, you should review this manual and get formal training in how to operate it properly and safely. Furthermore, you should ensure that your workplace is maintained to assure your continued safety and the safety of others around whom you work. In addition, you, the operator, have responsibility to : As we said, operators should recognize and avoid hazards in the workplace. Although some injuries occur because of unsafe operating practices, others result from unnecessary workplace hazards. To maintain a safe workplace environment for this equipment, do the following : • Remove physical hazards where the equipment will be operated, in either the plant or the yard. • Follow the safety practices in which you are trained at all times, every day. • Separate pedestrian and equipment traffic wherever possible. • Recognize and avoid potential hazards in your work-place. • Place convex mirrors at blind intersections. • Understand and abide by the Warning labels attached to the equipment. • Require the use of horns at intersections or when approaching pedestrian areas. • Inspect the equipment for its serviceability at the beginning of each shift. • Establish equipment speed limits. • Report immediately any service problems you notice before you use the equipment or that develop while you are using it. • Consider installing and maintaining backup alarms and flashing caution lights on equipment. • Use edge guards, levelers and trailer locks on docks. • Report immediately any unsafe workplace conditions that threaten your safety or the safety of others. • When the equipment is driven onto trailers, use wheel chocks and jack supports if necessary to prevent creeping and possible collapse. • Avoid horseplay or other reckless actions that may endanger yourself or others. • Develop workplace safety rules for all employees. In short, every operator of this equipment has the responsibility to use common sense at all times and to make safety his or her number one job priority. • Post these rules conspicuously in the areas where they apply. Many appropriate workplace rules are published by OSHA, ASME, and the National Safety Council. (See the list below under "Information Resources for Operation, Maintenance, and Safety.") We recommend that you consult these publications as you develop safety rules for your workplace. -5- Safety Section Maintaining the Machine to the Job Maintenance Practices Well maintained equipment is safer equipment. A regular program of scheduled maintenance should be part of your facility’s ongoing safety program. Daily inspections or inspections at the start of every shift are required by OSHA. Your DAEWOO dealer can help you train your operators for this task and provide you with genuine replacement parts and service equipment when scheduled (or unscheduled) maintenance and repairs are needed. Every employer must ensure that equipment is properly suited to the job it must perform. It should be selected with conditions and capacity well in mind, otherwise operators and other workers may face hazards resulting directly from wrong equipment selection. Furthermore, equipment suited for one job or environment may not be suitable at all when moved to a different work area. Although operators have a daily responsibility to inspect and report service problems, OSHA and ASME standards require that equipment maintenance and repair be performed by authorized mechanics only. Understand what is reasonable to expect in this area, and leave the serious maintenance and repair tasks to professional mechanics and technicians. Equipment should be used for its intended purpose only. For example, lift truck forks should never serve as man-lifts or mobile work platforms. Warning Signal Options ASME section 4.15 Warning Devices, requires that every truck be equipped with an operator controlled horn, whistle, gong or other sound producing device. The user (Owner/Operator) shall determine if operating conditions require the truck to be equipped with ADDITIONAL sound – producing or visual devices, and be responsible for providing and maintaining such devices. Your DAEWOO dealer can provide effective warning signal devices to meet the conditions of your application. Modifications Many times the addition of a special attachment can affect the ability of equipment to operate at the capacity originally intended. When modifications potentially change equipment safety, OSHA and ASME require you to obtain written approval from the manufacturer. If a modification changes a machine’s capacity, the machine’s capacity/ nameplate must also be changed. Consult your DAEWOO dealer before making modifications to your equipment. -6- Safety Section Operator Safety Training • What are the specific features of our loading docks, ramps, or railcar loading facilities? Although this manual contains much information about safety practices, it is not meant to be a training manual for new operators. An employer’s responsibility extends far beyond handing an employee this or any other document and saying "read this to learn how to operate this equipment." • What specialized attachments are used on our equipment? • What personal equipment or special clothing is necessary to operate the equipment in our work environment? (hard hats, seat restraints, respirators, protective shoes or gloves, etc.) Formal Training • Are operators conducting daily inspections prior to shift start? OSHA and ASME require formal training for new operators and refresher training for experienced operators, along with appropriate on-the-job supervision. Furthermore, training must be tailored to the specific conditions of your workplace and the workplace rules you have developed to protect your employees. Whenever work conditions change in ways that affect operator safety, training for the new conditions must be provided. Of course, before any employee can be selected to operate industrial or construction type equipment, the employee must meet the employer’s specific visual, auditory, physical and mental ability standards. • Does our equipment require any special refueling procedures? One additional recommendation: ask those employees who work around (but do not operate) the equipment for suggestions about what the operators should be aware of. Practical Training The questions above and others like them can help you design an appropriate training course for your operators. But above all, be sure that your training incorporates a significant portion of practical experience. Inspection Training OSHA furthermore requires that operators be trained to conduct daily equipment safety inspections. The goal of these inspections is to prevent any piece of equipment in need of repairs from being placed into service and thereby endangering personnel. Your DAEWOO dealer can help with suggestions as you develop training to comply to this and to other OSHA/ASME requirements. Recognition A key part of any training program is recognition. Think of ways you can recognize the achievement of those who successfully complete this important training. Certificates, licenses, patches, authorization cards and the like set these individuals apart and help create a lasting attitude of commitment to the job. Training Program Development As noted above, OSHA/ASME requires your training to be designed around the conditions present in your operation. To ensure this, ask yourself specific questions, including (but not limited to) the following : • In what areas of our workplace does operating ing the equipment pose hazards to pedestrians? • What hazards must operators be trained to deal with? • Does our workplace have any one-way aisles, speed zones, high noise, low light, or fire hazard areas? -7- Safety Section Information Resources for Operation, Maintenance and Safety • Publications Concerning Safe Handling and Storage of LP Gas. Available from: National LP Gas Association, 1301 West 22nd Street, Oakbrook, IL 60521. The following publications contain instructions and standards for the operation, maintenance, and safety issues you may want to consider : • Other OSHA regulations which may be applicable to the place of use. You can receive help in applying information from these sources to your workplace by contacting OSHA or your Worker’s Compensation Insurance Company. • General Industry Standards, OSHA 2206: "OSHA Safety and Health Standards (29 CFR 1910)", "Subpart N-Materials Handling and Storage", 29 CFR 1910.178 powered industrial trucks; 1910.177 – "Servicing Multi-Piece and Single Rim Wheels." Available from: Superintendent of Documents, U.S. Government Printing Office, Washington, DC 20402. • National Fire Protection (NFPA) 505, "Powered Industrial Trucks, Type Designation, Areas of Use, Maintenance, and Operation. Available from: Superintendent of Documents, U.S. Government Printing Office, Washington DC 20402. • ASME B56.1a – 1995: "Safety Standard for Low Lift and High Lift Trucks" (Safety Code or Powered Industrial Trucks). Available from: Society of Mechanical Engineers, United Engineering Center, 345 E. 47Th Street, New York, NY 10017. • NFPA 58: "Storage and Handling Liquefied Petroleum Gases". Available from: National Fire Protection Association. Inc.. Batterymarch Park, Quincy, MA 02269. • National Safety Council Data Sheets: "1-66 Writing and Publishing Employee Safety Regulations; "479 - Liquefied Petroleum Gases for Industrial Trucks"; "195.71 - The "In-Plant "Pedestrian". Available from: National Safety Council, 444 North Michigan Avenue, Chicago, IL 60611. • Accident Prevention Manual for Industrial Operations : Two volumes: "Administration and Programs", and "Engineering and Technology". Available from: National Safety Council, 444 North Michigan Avenue, Chicago, IL 60611. • UL 583 Standard for Safety for Electric – Battery Powered Industrial Trucks. • UL 558 Standard for Internal Combustion Engine – Powered Industrial Trucks. -8- Safety Section Safety Information The following section of this manual discusses both general and specific safety issues for your equipment. It gives you basic safety precautions. It also shows you where to find warning labels used on this equipment. The warnings themselves are reproduced here for you to read. WARNING WARNING : Indicates a potentially hazardous situation which, if not avoided, COULD result in DEATH or SERIOUS INJURY. Before you operate or perform any maintenance on this equipment, read this Safety Information section carefully. Also carefully read the operation and other sections of this manual and heed all of the safety information they contain. Also locate, read, and understand the warning decal’s on the equipment itself. CAUTION CAUTION : Indicates a potentially hazardous situation which, if not avoided, MAY result in INJURY. Pay attention to this safety alert symbol. Be alert to its warning. It means your safety is involved. Safe Operating Practices Warning messages appear with the safety alert symbols. They explain the hazard, either in words or by internationally recognized pictures. Always use common sense and be alert for possible hazards. Most accidents happen because someone failed to follow basic safety rules or take obvious precautions. Often you can avoid an accident by recognizing situations that might be hazardous. Furthermore, anyone who operates, maintains, or repairs this equipment should have the necessary training, skills, and tools. The dangers, warnings, and cautions in this manual and on the equipment cannot cover every possible circumstance that might involve a hazard. You must ensure that your operating techniques, tools, and work procedures are safe for you and others. You should also make sure that the equipment will not be damaged or made unsafe by your chosen operation, maintenance, or repair procedures. Improper operation, maintenance, or repair of this equipment can be dangerous and could result in injury or death. The information in this manual was current at the time the manual was written. However, specifications, torques, pressures, measurements, adjustments, and illustrations can change at any time. These changes can affect equipment service. Before starting any job, obtain the most current and complete information. Consult your DAEWOO dealer for the most current information. Do not operate or perform any lubrication, maintenance, or repair on this equipment until you have read and understood the operation, maintenance, and repair information in this manual. You will find safety precautions and warnings both in this manual and on the equipment itself. If you ignore these warnings, bodily injury or death could occur to you or to others. The safety rules and regulations in this section represent some, but not all rules and regulations of the Occupational Safety and Health Act (OSHA). They are paraphrased without representation that the OSHA rules and regulations have been reproduced verbatim. Hazards are identified by the exclamation point (!) "Safety Alert Symbol" followed by words such as "DANGER," "WARNING," or CAUTION." DANGER The best method for preventing serious injury or death is for the operator to be familiar with the proper operation of the equipment. Be alert and avoid actions or conditions that can result in an accident. DANGER : Indicates an imminently hazardous situation which, if not avoided, will result in DEATH or SERIOUS INJURY. -9- Safety Section Capacity/Nameplate Warning Signs and Labels DO NOT exceed machine capacity load as described on the capacity/nameplate attached to your machine. Many specific warning labels (safety signs) are displayed on your lift truck. This section of the manual shows their exact location and describes the hazard involved. Please take the time to become familiar with these warning labels. Also make sure that you can read all warning labels. Clean or replace any you cannot read or in which you cannot see the pictures. Clean warning labels with a cloth, water, and soap. Never use solvent, gasoline, or any other cleaning agent that may damage the label and make it unreadable. Replace any damaged, missing, or unreadable label. If a replaced part had a label, install a new label on the replacement part. Your DAEWOO dealer has new labels. Located on the right side of the operator’s seat on the battery cover. The remainder of this safety section presents the wording of the safety labels that should be on your lift truck. It also tells you where on the truck to find the labels. The capacity/nameplate gives the lift truck capacity by weight and distance to the load center. For example, a capacity load of 3000 lb at 24 in means that the machine can lift 3000 lb if the load center is not more than 24 in from both the horizontal and vertical faces of the forks. General Warnings to Operator To determine the load center: measure from the face of the forks to the gravitational center of the load. Before you lift any load, be sure that the weight and load center combination is within the capacity given on the capacity/nameplate. The capacity shown on the nameplate is for the lift truck as it left the factory. Later changes to the truck or its attachments can reduce its actual rating. Located on the battery cover to the right side of the operator’s seat. WARNING Only trained and authorized personnel may operate this machine. For safe operation, read and follow the Operation and Maintenance Manual furnished with this machine and observe the following warnings : 1. Before starting machine, check all controls and warning devices for proper operation. 2. Refer to machine capacity/nameplate for allowable machine capacity. Do not overload. - 10 - Safety Section Operate machines equipped with attachments as partially loaded machines when not handling a load. 3. Put directional control or shift lever in neutral before "ON-OFF" switch is turned on. 4. Start, turn, and brake smoothly. Slow down for turns and slippery or uneven surfaces. Use extreme caution when turning on inclines. 5. Travel with load as low as possible and tilted back. If load interferes with visibility, travel with load trailing. 6. On grade operations, travel with load up grade. 7. Watch out for pedestrians and obstructions. Check overhead clearances. Located on the right side of the operator station. 8. Do not permit riders on forks or machine at any time. Battery Restraint Warning 9. Do not allow anyone to stand or pass under the elevated portion of any machine. 10. Be sure operating surface can safely support machine. 11. Operate machine and attachments only from operator's position. 12. Do not handle unstable or loosely stacked loads. 13. Use minimum tilt when picking up or depositing a load. 14. Use extreme care when handling long, high, or wide loads. IA9O2001 15. Forks should be completely under load and spread apart as far as load permits. Located on the front of battery cover. 16. Machine should be equipped with overhead guard or equivalent protection where load requires it. Use load back rest extension. Use extreme caution if operating without these devices. WARNING Before operating truck, ensure that hood is securely locked by hood latch, and turn stopper to locking position. Otherwise, a battery may come out of a truck in case of tipover. It could cause the risk of serious injury or death. 17. Parking-Lower lifting mechanism to floor. Put directional control or shift lever in neutral. Set parking brake. Turn "ON-OFF" switch off. Chock wheels if machine is on incline. Disconnect battery when storing electric machines. 18. Observe safety rules when handling fuel for engine powered machines and when charging batteries for electric machines. Training Required Service Warning To Operate Or WARNING Improper operation or maintenance could result in injury or death. Do not operate or work on this truck unless you are properly trained. Read and understand the operation and maintenance manual. Additional manuals are available from DAEWOO dealers. - 11 - Safety Section No Riders Warning No Standing On Forks Warning, No Standing Under Forks Warning WARNING WARNING To avoid personal injury, allow no riders. A lift truck is designed for only one operator and no riders. Do not stand or ride on the forks. Do not stand or ride on a load or pallet on the forks. Do not stand or walk under the forks. Hand Placement Warning WARNING IA8O1005 Located on the mast. Load Backrest Warning No hands. Do not place hands in this area. Do not touch, lean on, or reach through the mast or permit others to do so. Must Be In Place WARNING Operation without this device in place may be hazardous. Located on the mast. Located on the load backrest. - 12 - Safety Section Apply Parking Brake Warning Battery Disconnect Before Servicing Warning WARNING WARNING When leaving machine apply parking brake! Parking brake is not automatically applied. Disconect battery from truck and also discharge high voltages from capacitor banks with a 150 ohm, 25 watt Resistor before attempting to service this truck. IA8O1007 Located on the top left side of the cowl. IA8O4006 Overhead Guard Must Be In Place Warning B15/18/20T-2 (36V) WARNING Operation without this device in place may be hazardous. This guard conforms to A.N.S.I.B56.1 and F.E.M. Section IV. This design has been tested with an impact. B13/15/18/20T-2 (48V) IA8O1008 Located outside top frame member of overhead guard. - 13 - Safety Section General Hazard Information WARNING Many countries apply recognized standards and/or regulations to lift truck use, operation, and maintenance. Install any seat to this seat frame. Switch must shut off all power when operator is not seated. In the USA, see current revisions of : • 29 Code Federal Register 1910.178 powered industrial trucks. WARING • American National Standard, ANSI B56.1a - 1995 Safety Standard for Low Lift and High Lift trucks. INSTALL ANY SEAT TO THIS SEAT FRAME SWITCH MUST SHUT OFF ALL POWER WHEN OPERATION IS • National Fire Protection (NFPA) 505, Powered Industrial Trucks, Type Designation, Areas of Use, Maintenance, and Operation. NOT SEATED. IA1O1010 • Other OSHA regulations which may be applicable to the place of use. Lift Trucks Temporarily Out Of Service IOSO014P • Attach a tag that says "DO NOT OPERATE" (or similar warning) to the start switch or somewhere obvious on other controls before the truck is serviced or repaired. You can get these tags from your DAEWOO dealer. Protective Clothing/Gear • Always wear a hard hat, safety glasses, and other protective gear, according to your job conditions. • Never wear loose clothing or jewelry. These can catch on controls or on moving parts of the lift truck and cause you to lose control or pull you into the equipment. - 14 - Safety Section Protective Guards and Covers Maintenance • Double-check that all guards and protective covers are securely in place on your truck. Whenever you perform all maintenance, do the following : • Be careful when removing cover plates. Gradually back off the last two bolts or nuts located at opposite ends of the cover but do not remove them completely. Pry the cover loose to relieve any spring or other pressure. Then remove the last two bolts or nuts. • Park the lift truck in an authorized area. This area should be LEVEL. If the area is not level, block the drive wheels. Housekeeping • Apply the parking brake. • Keep the lift truck clean. Be sure the steps and floor are free of dirt and debris, grease and oil, tools or other items. • Turn key switch OFF. Remove the key. • Fasten down all loose items, such as tools, that are not part of the lift truck. • Never store maintenance fluids in glass containers. • Air under pressure can cause personal injury. Wear a protective face shield, protective clothing, and protective shoes when you use pressure air for cleaning. The maximum air pressure permitted for cleaning is 205 kPa (30 psi). • Use cleaning fluids carefully. Fluid Penetration • Report any needed repairs as soon as you become aware of them. • When you check for fluid leaks, especially if the fluid is under pressure, always use a board or cardboard. NEVER USE YOUR BARE HAND. Fluid escaping under pressure can penetrate your skin and muscle tissue, causing serious injury and possible death. Fluid that is injected into your skin must immediately be removed (surgically) by a doctor. • Lower the forks and tilt the mast forward until the fork tips touch the ground or floor. Pressure Air • Learn and use work site hand signals. Accept signals from one person only. • Never permit any unauthorized person on the lift truck. • Before operating the lift truck, properly latch the engine compartment. Asbestos No asbestos is used in any component of this lift truck. • Never clean electrical components with steam, solvent, or high pressure air. Crushing or Cutting Prevention Lift Chains • Support the mast and carriage when working beneath them. Hydraulic cylinders should not be depended on to hold them up. If a control is moved or if a hydraulic line breaks, the component will fall. • Before operating the lift truck, inspect the part of the chain that travels over the crosshead roller. The movement of the chain over the roller is a special source of wear. • Never make adjustments when the lift truck is moving. When the engine is operating, make adjustments only when specified. • Inspect chain link pins before operating the truck. They must not extend outside of the bore hole. Any link pin that extends beyond its connecting link may be broken inside its bore hole. • Remember that clearances for implement linkages will increase or decrease as the implement moves. • Inspect the chain anchor and links for wear. - 15 - Safety Section Burn Prevention • Keep a safe distance from all rotating and moving parts. Oils • Moving fan blades will throw or cut any object that falls or is pushed into them. Make sure no objects come near fans. • Avoid contact with hot oil and the components that carry or contain hot oil. Personal injury can result from such contact. • Handle wire rope cable with gloves. A kinked or frayed wire rope cable is not safe to use. • At operating temperature, the hydraulic oil and hydraulic tank are hot and can be under pressure. • When driving retainer pins, clear the area of people. Wear protective glasses. Retainer pins struck with force can fly out and cause injury. • The hydraulic tank filler cap should be removed only after the engine is stopped and the filler cap is cool enough to remove with your bare hand. • Before striking any object, clear the area of people. Flying chips and debris can cause injury. • Remove the hydraulic tank filler cap slowly. This will relieve pressure, if any. Falling Objects Protective Structure (FOPS) Overhead Guard • Before you disconnect or remove any lines, fittings, or related items, relieve all pressure in the oil system. • This is an attached guard located above the operator's compartment and secured to the lift truck. Batteries • Battery acid can cause severe burns. Fumes from batteries can explode or cause fire. • To avoid possible weakening of the Falling Objects Protective Structure (FOPS), consult a DAEWOO dealer before altering, by adding weight to, welding on, or cutting or drilling holes into the structure. • When checking, charging, or servicing a battery, never smoke or in any other way expose the battery to flames or sparks. Never set chains or metallic tools on top of a battery. This could cause an electrical short circuit, arcing, flames, and explosion. • The overhead guard is not intended to protect against every possible impact. The overhead guard may not protect against some objects penetrating into the operator's station from the sides or ends of the lift truck. • The end of the charging period, as the battery approaches a full charge condition, is an especially hazardous time for highly explosive gases. • The lift truck is equipped with an overhead guard (FOPS) as standard. If there is a possibility of overhead objects falling through the guard, the guard must be equipped with smaller holes or a plexiglass cover. • Any altering done that is not specifically authorized by DAEWOO invalidates DAEWOO's FOPS certification. • Add only distilled water to a "wet" battery. Never add acid. • Always follow the battery manufacturer's instructions when preparing a dry charged battery for service. • The protection offered by this FOPS will be impaired if it has been subjected to structural damage. Structural damage can be caused by an overturn accident, by falling objects, etc. • Do not mount any item such as fire extinguishers, first aid kits and lights by welding brackets to or drilling holes in any FOPS structure. See your DAEWOO dealer for mounting guidelines. - 16 - Safety Section Fire or Explosion Prevention • Tighten all hose and line connections to the recommended torque. Replace if you find any of the following conditions : • Always remember that most lubricants are flammable. - Damaged or leaking end fittings. - Chafed or cut outer covering and exposed wire reinforcing. • Never smoke in areas where batteries are charged or where flammable materials are stored. - Local ballooning in any outer covering. • Keep electrical connections tight and clean. Check for loose or frayed wiring every day. Before operating the lift truck, have any loose or frayed electrical wires tightened, repaired, or replaced. - Kinking or crushing in a flexible part of the hose. - Armor that is embedded in the outer covering. - Displaced end fittings. • Store all lubricants in properly marked containers. Keep such containers where unauthorized persons will not have access to them. • Check all clamps, guards, and heat shields for proper installation. Prevent these parts from vibrating or rubbing against other parts and causing excessive heat during operation. • Oily rags or other flammable material must also be stored in a protective container in a safe place. Do not change any factory set adjustment values unless you have both authorization and training. Especially Safety equipment and switches may not be removed or adjusted incorrectly. Repairs, adjustments and maintenances that are not correct can make a dangerous operating condition. • Never weld or flame cut on pipes or tubes that contain flammable fluids. Before welding or flame cutting, empty the pipes and tubes of the flammable fluids and clean them thoroughly with nonflammable solvent. For any checkup, repair, adjustments, maintenance and all other work concerning your forklift truck, please contact your DAEWOO dealer. We would like to draw your attention to the fact that any secondary damages due to improper handling, insufficient maintenance, wrong repairs or the use of other than original DAEWOO spare parts waive any liability by DAEWOO. • Do not allow flammable materials, such as oil and grease, accumulate on the lift truck. • Never expose the lift truck to burning brush. • Be sure that shields that protect hot exhaust components from oil in the event of a line, tube, or seal failure are properly installed. • Keep a fire extinguisher available and know how to use it. Inspect and service the fire extinguisher as recommended on its instruction plate. Lines, Tubes and Hoses • Never bend or strike high pressure lines. Lines, tubes, or hoses that are bent or damaged should not be installed on the lift truck. • Leaking oil lines, tubes, and hoses can cause fires. Repair any that are loose or damaged. Contact your DAEWOO dealer. • Use caution when checking for leaks. Use a board or cardboard; never use your bare hand. See "Fluid Penetration" in the Safety section for more details. - 17 - Safety Section Operating Safety • Before operating the lift truck move all hydraulic controls to the HOLD(center) position and place the directional control lever in NEUTRAL. Mounting and Dismounting • Apply the parking brake. • Use only the steps and/or handholds provided to mount and dismount the lift truck. • Remove any obstacles from the path of the lift truck. Watch for hazards such as curbs, blocks, and posts. • Face the lift truck and use both hands. Be especially careful in wet or slippery conditions. • Make sure all controls work properly. • Do not try to climb on or off the lift truck when you are carrying anything that prevents you from using both hands. While Operating the Lift Truck • Do not jump off the lift truck. • Always wear seat belt. • Never get on or off a lift truck that is moving. • Always obey traffic rules and posted warning signs. Before Operating the Lift Truck • Be aware of load limits on floors (including truck bed and railcar floors) and watch for adequate overhead clearance. • Operate the lift truck from the operator's station only. • Always use an overhead guard, especially in high stacking area or with unstable loads. • Fasten the seat belt. • Adjust the seat so you have full pedal travel when your back is against the seat back. • Watch for falling objects when stacking. Be sure the truck has a load back rest extension and an overhead guard. • Verify that the horn, lights, and backup alarm (if equipped) are working properly. • Never turn or travel with an elevated load. • Before turning on the key or beginning to move the lift truck, be sure no one is working on, underneath, or close to it. There should be no people in the immediate area. • Operate the lift truck in reverse when carrying bulky loads, for better visibility. Look in your direction of travel. • Travel with load uphill on inclines and downgrades. • Avoid turning on grades or use extreme caution. • Tilt an elevated load forward as low as possible and only when you are directly over the unloading area. • Apply the parking brake any time you leave the lift truck. Lift Truck Parking IOSO014P • If there is a "DO NOT OPERATE" or similar warning tag attached to the start switch or controls, do not move the lift truck or operate any of its controls. • Park in authorized areas only. Never block traffic. • Exposure to the elements can cause lift truck system electrical damage or failure. If you are parking the lift truck for an extended period of time, - 18 - Safety Section Operator Restraint System (If Equipped) choose an area where the electrical system will be protected from moisture. • Park the lift truck on a level surface. (If you must park on an incline, block the drive wheels.) Warning Signs and Labels Your DAEWOO lift truck has the following tipover warning decals. • Lower the forks and tilt the mast forward until the fork tips touch the ground or floor. Make sure that you can read all safety signs. Clean or replace these if you cannot read the words or see the pictures. when cleaning the labels use a cloth, water and soap. Do not use solvent, gasoline, etc. You must replace a label if it is damaged, missing or cannot be read. If a label is on a part that is replaced, make sure a new label is installed on the replaced part. See you DAEWOO Lift Truck dealer for new labels. The most effective method of preventing serious injury or death to yourself or others is to familiarize yourself with the proper operation of the lift truck, to be alert, and to avoid actions or conditions which can result in an accident. • Place the directional control lever in NEUTRAL. • Apply the parking brake. • Turn the key switch OFF and remove the key. WARNING Tipover can occur if the truck is improperly operated. In the event of a tipover, injury or death could result. "Survive in tipover" decal IB9O0002 "Survive in tipover" decal IB9O0003 - 19 - Safety Section WARNING "Fasten seat belt" decal Your DAEWOO truck comes equipped with a DAEWOO operator restraint system. Should it become necessary to replace the seat for any reason, it should only be replaced with another DAEWOO operator restraint system. "Survive in tipover" decal If Optional Suspension Seat Equipped IB9O0004 The “Survive in tipover” warning is located on the overhead guard. It shows the proper use of the operator restraint system. Forward and Backward Adjustment Seat Adjustment Front-to -backadjustment adjustment Front-to-back IC1O0085 Lever Backrest Inclination IB9O0005 Move the lever, slide the seat to the desired position, and release the lever. IC1O0086 Weight adjustment Press the weight adjustment lever only downwards. Adjustment to driver's weight in 9 steps. Press the appropriate lever at the bottom against the stop the weight adjustment. Switches over automatically to the 50 kg position. IB9O0006 Adjust the seat before operating the lift truck. After adjusting, joggle the seat to make sure it is properly locked, DO NOT adjust the seat while the truck is in motion. IC1O0087 - 20 - Safety Section Seat Belt 2. Replace the seat belt assembly every 3 years even if it passes visual inspection. For replacement, see the date of manufacture labelled on the back side of the belt. IB9O0007 The Operator Restraint System, Prevents the operator from jumping from the operator’s compartment in the event of a forward or side tipover. INSO019S 3. In the event of a tipover, the seat and restraint system should be inspected for damage and replaced, if necessary. The system is designed to keep the operator on the seat and in the operator’s compartment in the event of a tipover. NOTE : Operator restraints shall be examined at the regular truck service intervals, it is recommended that they be replaced if any of the following conditions are found : Inspection • Cut or frayed strap • Worn or damaged hardware including anchor points • Buckle or retractor malfunction • Loosen stitching WARNING The seat belt may cause the operator to bend at the waist. If you are pregnant of have suffered from some abdominal disease, consult a doctor before you use the seat belt. INSO017S 1. If the seat belt is torn, if pulling motion is interrupted during extension of the belt, or if the belt cannot be inserted into the buckle properly, replace the seat belt assembly. Fasten the Seat Belt Tung Buckle INSO020S IB9O0009 - 21 - Safety Section Avoiding Lift Truck Tipovers 1. Grip the plate (connector) of the belt and pull the belt from the retractor. Then insert the plate into the slot of the buckle until a snap is heard. Pull on the belt to confirm it is latched. Lift Truck Stability 2. Make sure the belt is not twisted. WARNING If you fasten the belt across your abdomen, the belt may injure your abdomen in an accident. INSO023I Counterbalanced lift truck design is based on the balance of two weights on opposite sides of a fulcrum (the front axle). The load on the forks must be balanced by the weight of the lift truck. The location of the center of gravity of both the truck and the load is also a factor. This basic principle is used for picking up a load. The ability of the lift truck to handle a load is discussed in terms of center of gravity and both forward and sideways stability. INSO021S Center of Gravity (CG) 3. Be sure to fasten the belt across your hips, not across your abdomen. NOTE : The belt is designed to automatically adjust to your size and movement. A quick pull on the belt will confirm that the automatic adjuster will hold the belt position in the event of an accident. Release the Seat Belt CG INSO024I The point within an object, at which the whole weight of the object may be regarded as being concentrated, is called the center of gravity or CG. If the object is uniform, its geometric center will coincide with its CG. If it is not uniform, the CG could be at a point outside of the object. When the lift truck picks up a load, the truck and load have a new combined CG. INSO022S Push the button of the buckle to release the belt. The belt will automatically retract when released. Hold the plate of the belt and allow the belt to slowly retract. - 22 - Safety Section Stability and Center of Gravity CG truck Combined CG Lift Truck Stability Base CG load CG-Truck will tip over INSO025I INSO027I The stability of the lift truck is determined by the location of its CG; or, if the truck is loaded, the combined CG of the truck and load. The lift truck has moving parts and, therefore, has a CG that moves. The CG moves forward or backward as the mast is tilted forward or backward. The CG moves up or down as the mast moves up or down. The CG and, therefore, the stability of the loaded lift truck, is affected by a number of factors such as: For the lift truck to be stable (not tip over forward or to the side), the CG must stay within the area of the lift truck stability base – a triangular area between the front wheels and the pivot of the steer wheels. If the CG moves forward of the front axle, the lift truck will tip forward. If the CG moves outside of the line on either side of the stability base, the lift truck will tip to the side. WARNING • the size, weight, shape and position of the load • the height to which the load is lifted Dynamic forces (braking, acceleration, turning) also affect stability and can produce tipover even when the CG is within the stability triangle. • the amount of forward or backward tilt • tire pressure Capacity Load (Weight and Load Center) • dynamic forces created when the lift truck is accelerated, braked or turned • condition and grade of surfaces on which the lift truck is operated CG load Combined CG INSO028I The capacity load of the lift truck is shown on the capacity/nameplate riveted to the truck. It is determined by the weight and load center. The load center is determined by the location of the CG of the load. CG truck INSO026I These same factors are also important for unloaded lift trucks. They tip over sideways easier than a loaded lift truck carrying its load in the lowered position. The load center shown on the nameplate is the horizontal distance from the front face of the forks, or the load face of an attachment, to the CG of the - 23 - Safety Section load. The location of the CG in the vertical direction is the same as the horizontal dimension. Remember that, unless otherwise indicated, the capacity load shown on the nameplate is for a standard lift truck with standard backrest, forks and mast, and having no special-purpose attachment. In addition, the capacity load assumes that the load center is no further from the top of the forks than it is from the face of the backrest. If these conditions do not exist, the operator may have to reduce the safe operating load because the truck stability may be reduced. The lift truck should not be operated if its capacity/nameplate does not indicate capacity load. INSO031S DON’T go over rough terrain! If unavoidable, slow down. NOTE : If the load is not uniform, the heaviest portion should be placed closer to the backrest and centered on the forks. NOTICE 1. Capacity/Nameplates originally attached to forklifts sold by DAEWOO shall not be removed, altered or replaced without DAEWOO’s approval. 2. DAEWOO assumes no responsibility for lift trucks placed in service without a valid DAEWOO Nameplate. INSO032S DON’T start, turn, or stop quickly. Sudden movement can cause the lift truck to tipover. 3. If necessary to change your specification, contact your DAEWOO lift truck dealer. Safe Driving Practices INSO033S DON’T crowd. Maintain a safe distance from the edge of docks, ramps and platforms. Always watch “tail swing” INSO030S DON’T overload. Always handle loads within the rated capacity shown on the capacity plate. - 24 - Safety Section INSO037S INSO034S DON’T drive on soft ground. DON’T elevate tilted loads ! This can also cause the lift truck to tipover forward. INSO035S INSO038S DON’T turn on, or drive across an incline. DON’T pick up an off center load ! Such a load increases the possibility of a tipover to the side. INSO036S DON’T tilt elevated loads forwards ! This can cause the lift truck to tipover forward. INSO039S DON’T drive on slippery surfaces ! Sand, gravel, ice or mud can cause a tipover. If unavoidable, slow down. - 25 - Safety Section INSO040S INSO043I DON’T attempt to pick up or deposit a load unless the lift truck is level. DON’T travel with the mast raised. INSO041S DON’T jump off if your truck starts to tipover ! Stay in your seat to survive. INSO042I DON’T compromise safety. Wear a hard hat if required on your job site. - 26 - Safety Section How to Survive in a Tipover FASTEN SEAT BELT WARNING WARNING TIPOVER CAN OCCUR IF TRUCK IS IMPROPERLY OPERATED. INJURY OR DEATH COULD RESULT. DON'T JUMP HOLD ON TIGHT TO STEERING WHEEL BRACE FEET LEAN AWAY FROM IMPACT LEAN FORWARD IN CASE OF TIPOVER HOLD ON TIGHT INSO048I Hold on tight. FASTEN SEAT BELT INSO045I FASTEN SEAT BELT In the event of a tipover, the risk of serious injury or death will be reduced if the operator is using the operator restraint system and follows the instructions provided. WARNING TIPOVER CAN OCCUR IF TRUCK IS IMPROPERLY OPERATED. INJURY OR DEATH COULD RESULT. DON'T JUMP HOLD ON TIGHT TO STEERING WHEEL BRACE FEET LEAN AWAY FROM IMPACT LEAN FORWARD IN CASE OF TIPOVER BRACE FEET FASTEN SEAT BELT WARNING TIPOVER CAN OCCUR IF TRUCK IS IMPROPERLY OPERATED. INJURY OR DEATH COULD RESULT. DON'T JUMP HOLD ON TIGHT TO STEERING WHEEL BRACE FEET LEAN AWAY FROM IMPACT INSO049I LEAN FORWARD IN CASE OF TIPOVER Brace your feet and keep them within the operator’s compartment. FASTEN SEAT BELT FASTEN SEAT BELT INSO046I WARNING TIPOVER CAN OCCUR IF TRUCK IS IMPROPERLY OPERATED. INJURY OR DEATH COULD RESULT. DON'T JUMP HOLD ON TIGHT TO STEERING WHEEL BRACE FEET LEAN AWAY FROM IMPACT LEAN FORWARD IN CASE OF TIPOVER Always use operator restraint system. FASTEN SEAT BELT WARNING TIPOVER CAN OCCUR IF TRUCK IS IMPROPERLY OPERATED. INJURY OR DEATH COULD RESULT. DON'T JUMP HOLD ON TIGHT TO STEERING WHEEL BRACE FEET LEAN AWAY FROM IMPACT LEAN AWAY LEAN FORWARD IN CASE OF TIPOVER INSO050I Lean away from the direction of fall. DON'T JUMP INSO047I DON’T jump. - 27 - Safety Section FASTEN SEAT BELT WARNING TIPOVER CAN OCCUR IF TRUCK IS IMPROPERLY OPERATED. INJURY OR DEATH COULD RESULT. DON'T JUMP HOLD ON TIGHT TO STEERING WHEEL BRACE FEET LEAN AWAY FROM IMPACT LEAN FORWARD IN CASE OF TIPOVER LEAN FORWARD INSO051I Lean forward. - 28 - General Section Specifications CHARACTERISTICS 1 Manufacturer DHI&M 2 Model 3 4 5 6 7 8 Capacity Load center Power type Operator type Tire Wheels (x=driven) 9 10 12 DIMENSIONS maximum fork height with rated load Lift with std. two-stage mast free lift Fork carriage ISO Class at rated load center distance Electric, Diesel, Gasoline, LP-Gas Stand-on, Rider-seated P=pneumatic, E=elastic, C=cushion number of front/rear Spacing (Min. X Max.) Tilt of mast forward / backward Overall dimensions length to fork face width mast lowered height mast extended height overhead guard height seat height 23 23a Aisle width with pallets 1000 X 1200 crosswise Aisle width with pallets 800 X 1200 lengthwise PERFORMANCE Out side turning radius Load moment constant (from center of front wheel to fork face) 24 25 Speeds 26 28 30 32 Travel loaded/unloaded Lift loaded/unloaded Lowering loaded/unloaded Max. Drawbar pull loaded Max. gradeability loaded WEIGHT Total weight (With minimum weight of battery) 33 with load front/rear without load front/rear Axle load 34 B15T-2 1500(3000) 500(24) Electric Rider-seated P, E, C 2 X /1 mm in mm in deg 3300(130) 130(5) II 35 X 100 X 900 1.4 X 4 X 35.4 240 X 905 9.4 X 35.6 5/7 3300(130) 130(5) II 35 X 100 X 900 1.4 X 4 X 35.4 240 X 905 9.4 X 35.6 5/7 mm(in) mm(in) mm(in) mm(in) mm(in) mm(in) mm(in) mm(in) 1838(72.4) 1070(42.1) 2149(84.6) 4350(171.3) 1970(77.6) 904(35.6) 1472(58.0) 366(14.4) 1853(73.0) 1070(42.1) 2149(84.6) 4350(171.3) 1970(77.6) 904(35.6) 1487(58.5) 366(14.4) mm(in) mm(in) 3164(124.6) 2983(117.4) 3179(125.2) 2998(118.0) km/h mph mm/s fpm mm/s fpm kg(lb) % 14.5/16.0 9.0/9.9 390/630 76.8/124.0 500/450 98/89 1750(3852) 23 13.8/15.5 8.6/9.6 370/630 72.8/124.0 500/450 98/89 1450(3190) 23 kg kg lb kg lb 2883(6343) 3484/649 7665/1428 1377/1506 3029/3313 2957(6505) 3910/547 8602/1203 1364/1593 3007/3511 2/1 18 X 7-8 18 X 7-8 1242(48.9) 890/0(35/0) 85(3.3) 100(3.9) foot/hydraulic hand/mech 2/1 18 X 7-8 18 X 7-8 1242(48.9) 890/0(35/0) 85(3.3) 100(3.9) foot/hydraulic hand/mech 48/440 700(1540) 4.0(5.3) X 2 8.5(11.4) TR ODB 15580(2260) 13960(2025) 48/440 700(1540) 4.0(5.3) X 2 8.5(11.4) TR ODB 17170(2490) 13960(2025) mm(in) mm(in) Fork 14 15 16 17 18 19 20 21 22 B13T-2 1250(2500) 500(24) Electric Rider-seated P, E, C 2 X /1 kg(lb) mm(in) thickness X width X length 13 DHI&M 48V CHASSIS 35 36 37 38 39 40 41 42 43 number of front/rear size front size rear Tires Wheelbase Tread Ground clearance Brake front/rear loaded loaded Service brake Parking brake mm(in) mm(in) mm(in) mm(in) loaded loaded DRIVE 45 Battery 47 Electric motors 54 55 Control type Axle 57 System pressure Volt/Capacity-Max. Weight (Minimum) Drive motor (1HR Rating) Hydraulic motor (20% Duty) Drive/Pump Brake type Lift Attachment V/AH kg(lb) kw(hp) kw(hp) Type Type kPa(psi) kPa(psi) - 29 - General Section 1 DHI&M DHI&M DHI&M 36V DHI&M B18T-2 1750(3500) 500(24) Electric Rider-seated P, E, C 2 X /1 B20T-2 2000(4000) 500(24) Electric Rider-seated E 2 X /2 B15T-2 1500(3000) 500(24) Electric Rider-seated P, E, C 2 X /1 B18T-2 1750(3500) 500(24) Electric Rider-seated P, E, C 2 X /1 B20T-2 2000(4000) 500(24) Electric Rider-seated C 2 X /1 3300(130) 130(5) II 35 X 100 X 900 1.4 X 4 X 35.4 240 X 905 9.4 X 35.6 5/7 1961(77.2) 1070(42.1) 2149(84.6) 4350(171.3) 1970(77.6) 904(35.6) 1595(62.8) 366(14.4) 3300(130) 135(5.3) II 40 X 100 X 900 1.4 X 4 X 35.4 240 X 905 9.4 X 35.6 5/7 2006(79.0) 1102(43.4) 2149(84.6) 4350(171.3) 1970(77.6) 904(35.6) 1635(64.4) 371(74.6) 3000(118) 130(5) II 35 X 100 X 1050 1.4 X 4 X 41 240 X 905 9.4 X 35.6 5/7 1853(73.0) 1070(42.1) 2000(78.7) 4045(159.2) 2120(83.5) 904(35.6) 1487(58.5) 366(14.4) 3000(118) 130(5) II 35 X 100 X 1050 1.4 X 4 X 41 240 X 905 9.4 X 35.6 5/7 1961(77.2) 1070(42.1) 2000(78.7) 4045(159.2) 2120(83.5) 904(35.6) 1595(62.8) 366(14.4) 3000(1180) 130(5) II 10 X 100 X 1050 1.4 X 4 X 41 240 X 905 9.4 X 35.6 5/7 1997(78.6) 1070(42.1) 2000(78.7) 4045(159.2) 2120(83.5) 904(35.6) 1626(64) 371(14.6) 9 10 12 3287(129.4) 3106(122.3) 3320(130.7) 3139(123.6) 3179(125.2) 2998(118.0) 3287(129.4) 3106(122.3) 3323(130.8) 3142(123.7) 23 23a 13.5/15.5 8.4/9.6 350/630 68.9/124.0 500/450 98/89 1100(2420) 23 13.0/15.0 8.1/9.3 320/630 63.0/124.0 500/450 98.4/88.6 1255(2767) 23 12.4/13.1 7.8/8.2 350/560 69/110 500/450 98/89 1080(2736) 24 12.1/12.8 7.6/8 330/560 65/110 500/450 98/89 1130(2486) 23.5 11.8/12.5 7.4/7.8 280/560 55/110 500/450 98/89 1240(2728) 23.1 3080(6776) 4292/538 9442/1184 1419/1661 3122/3554 3580(7893) 5012/568 11050/1252 1759/1821 3878/4015 3137(6916) 3992/645 8734/1182 1462/1675 3223/3693 3265(7198) 4377/638 9550/1148 1505/1760 3318/3880 3577(7885) 4888/689 10509/1376 1566/2011 3452/4433 32 2/1 18 X 7-8 18 X 7-8 1350(53.1) 890/0(35/0) 85(3.3) 100(3.9) foot/hydraulic hand/mech 2/2 200 X 50-10 16 X 6-8 1390(54.7) 912/197(36.0/7.8) 85(3.3) 100(3.9) foot/hydraulic hand/mech 2/1 18 X 7 X 12.12 18 X 7 X 12.12 1242(48.9) 890/0(35/0) 85(3.3) 100(3.9) foot/hydraulic hand/mech 2/1 18 X 7-12.12 18 X 7-12.12 1350(53.1) 890/0(35/0) 85(3.3) 100(3.9) foot/hydraulic hand/mech 2/1 18 X 7-12.12 18 X 7-12.12 1350(53.1) 890/0(35/0) 85(3.3) 100(3.9) foot/hydraulic hand/mech 35 36 37 38 39 40 41 42 43 48/510 800(1760) 4.0(5.3) X 2 8.5(11.4) TR ODB 17170(2490) 13960(2025) 48/585 1050(2315) 4.0(5.3) X 2 8.5(11.4) TR ODB 21550(3126) 13960(2025) 36/680 880(1936) 3.6(4.8) X 2 7.8(10.4) TR/TR ODB 17170(2490) 13960(2025) 36/765 985(2167) 3.6(4.8) X 2 7.8(10.4) TR/TR ODB 19440(2820) 13960(2025) 36/850 1090(2398) 3.6(4.8) X 2 7.8(10.4) TR/TR ODB 21575(3128) 13960(2025) DHI&M 48V - 30 - 2 3 4 5 6 7 8 13 14 15 16 17 18 19 20 21 22 24 25 26 28 30 33 34 45 47 54 55 57 General Section 100 mm 23 100 mm 16 39 17 S.I.P 10 20 4 19 9 18 13 21 INTERSECTING RIGHT ANGLE AISLE 22 38 15 IA8O3006 - 31 - General Section Noise and Vibration Noise unit:dB(A) Noise Level [ Unit : dB(A) ] Sound Pressure Level at Operator's Ear (Leq.) Model Sound Pressure Level at By-stander Position (AS 3713) AS 3713 prEN 12053 Drive-By Lifting Mode 70.7 73.1 71.0 71.0 65.4 69.8 68.0 68.0 B15T-2 (36V) B18T-2 (36V) B20T-2 (36V) B13T-2 (48V) B15T-2 (48V) B18T-2 (48V) B20T-2 (48V) * Test Model : B20T-2(36V), B20T-2(48V) Vibration (weighted overall value) unit:m/sec2 Measuring Place Model B13T-2 (48V) B15T-2 (48V) B18T-2 (48V) B20T-2 (48V) Seat Steering Wheel Floor Plate 0.27 0.49 0.40 * Test course : Concrete road - 32 - General Section Capacity Chart SOLID SOFTER TIRE MODEL STD, FFL B13T-2 (48V) kg FFT kg 1600 1400 1200 1000 800 600 400 A B C D 1600 1400 1200 1000 800 600 400 A B C 500 600 700 800 900 1000 1100 1200 500 600 700 800 900 1000 1100 1200 mm A. 3700 ~ 5000 mm MAST B. 5500 mm MAST C. 6000 mm MAST A. 2000 ~ 4500 mm MAST B. 5000 mm MAST C. 5500 mm MAST D. 6000 mm MAST B15T-2 (48V) kg 1600 1400 1200 1000 800 600 400 mm kg A B C D E 1600 1400 1200 1000 800 600 400 A B C D E F 500 600 700 800 900 1000 1100 1200 500 600 700 800 900 1000 1100 1200 mm A. 2000 ~ 4000 mm MAST B. 4500 mm MAST C. 5000 mm MAST D. 5500 mm MAST B18T-2 (48V) kg 1800 1600 1400 1200 1000 800 600 400 mm A. 3700 ~ 4000 mm MAST B. 4500 mm MAST C. 4800 mm MAST D. 5000 mm MAST E. 6000 mm MAST A B C kg D E F 500 600 700 800 900 1000 1100 1200 1800 1600 1400 1200 1000 800 600 400 E. 5500 mm MAST F. 6000 mm MAST A B C D E 500 600 700 800 900 1000 1100 1200 mm A. 2000 ~ 3700 mm MAST B. 4000 mm MAST C. 4500 mm MAST D. 5000 mm MAST E. 5500 mm MAST F. 6000 mm MAST mm A. 3700 ~ 4000 mm MAST B. 4500 mm MAST C. 4800 ~ 5000 mm MAST D. 5500 mm MAST - 33 - E. 6000 mm MAST ID5O0004 General Section Capacity Chart SOLID SOFTER TIRE MODEL STD, FFL B20T-2 (48V) kg 2000 1800 1600 1400 1200 1000 800 A FFT kg B 500 600 700 800 900 1000 1100 1200 2000 1800 1600 1400 1200 1000 800 A B C D E F 500 600 700 800 900 1000 1100 1200 mm mm A. 4000 mm MAST B. 4500 mm MAST C. 4750 mm MAST D. 5000 mm MAST A. 2700 ~ 4000 mm MAST B. 4500 mm MAST E. 5500 mm MAST F. 6000 mm MAST ID5O0007 - 34 - General Section Capacity Chart - with side shifter SOLID SOFTER TIRE MODEL STD, FFL B13T-2 (48V) kg 1600 1400 1200 1000 800 600 400 kg A B C D E F 1600 1400 1200 1000 800 600 400 A B C D E F 500 600 700 800 900 1000 1100 1200 500 600 700 800 900 1000 1100 1200 mm A. 2000 ~ 3300 mm MAST B. 3500 ~ 4000 mm MAST C. 4500 mm MAST D. 5000 mm MAST B15T-2 (48V) kg 1600 1400 1200 1000 800 600 400 mm A. 3700 ~ 4000 mm MAST B. 4500 mm MAST C. 4800 mm MAST D. 5000 mm MAST E. 5500 mm MAST F. 6000 mm MAST kg A B C D E F 1600 1400 1200 1000 800 600 400 E. 5500 mm MAST F. 6000 mm MAST A B C E D F 500 600 700 800 900 1000 1100 1200 500 600 700 800 900 1000 1100 1200 mm A. 2000 ~ 3300 mm MAST B. 3500 ~ 4000 mm MAST C. 4500 mm MAST D. 5000 mm MAST kg B18T-2 (48V) FFT 1800 1600 1400 1200 1000 800 600 400 mm A. 3700 ~ 4000 mm MAST B. 4500 mm MAST C. 4800 mm MAST D. 5000 mm MAST E. 5500 mm MAST F. 6000 mm MAST kg A B C D E F G 500 600 700 800 900 1000 1100 1200 1800 1600 1400 1200 1000 800 600 400 E. 5500 mm MAST F. 6000 mm MAST A B C D E F 500 600 700 800 900 1000 1100 1200 mm A. 2000 ~ 3300 mm MAST B. 3500 ~ 3700 mm MAST C. 4000 mm MAST D. 4500 mm MAS E. 5000 mm MAST F. 5500 mm MAST G. 6000 mm MAST mm A. 3700 ~ 4000 mm MAST B. 4500 mm MAST C. 4800 mm MAST D. 5000 mm MAST - 35 - E. 5500 mm MAST F. 6000 mm MAST ID5O0006 General Section Capacity Chart - with side shifter SOLID SOFTER TIRE MODEL STD, FFL B20T-2 (48V) kg 2000 1800 1600 1400 1200 1000 800 A FFT B kg 500 600 700 800 900 1000 1100 1200 2000 1800 1600 1400 1200 1000 800 A B C D E F 500 600 700 800 900 1000 1100 1200 mm mm A. 4000 mm MAST B. 4500 mm MAST C. 4750 mm MAST D. 5000 mm MAST A. 2700 ~ 4000 mm MAST B. 4500 mm MAST E. 5500 mm MAST F. 6000 mm MAST ID5O0007 - 36 - General Section Serial Number Serial Numbers Locations Both the lift truck and its motors have serial numbers. You can record them in this manual for quick reference. Use the spaces provided below the illustrations. ID5O0029 B15/18/20T-2 (36V) IA8O2001 Lift Truck Serial Number I B13/15/18/20T-2 (48V) Drive Motor Serial Number Left : Right : ID5O0008 B13/15/18/20T-2 (48V) ID5O0009 B15/18/20T-2 (36V) Hydraulic/Power Steering Motor Serial Number I - 37 - General Section Operator’s Warning and Identification Plate Familiarize yourself with the information on the ldentification, Lift Capacity and Attachment Plates. Do not exceed allowable lift truck working capacity load ratings. Operator’s Warning Plate Identification, Lift Capacity and Attachment Plate Lift Truck Capacity Rating DO NOT exceed allowable lift truck working capacity load ratings. The capacity of the lift truck is given by weight and distance to the load center. For example: a capacity of 1200kg(2540 lb) at 600mm (24in) means that the lift truck can lift 1200kg (2640lb) if the load center is 600 mm (24in) from both the vertical and horizontal faces of the forks. Located on the battery cover to the right side of the operator’s seat. Before attempting to lift any load, ensure that the weight and load center combination is within the capacity of the lift truck as shown on the capacity rating plate. To determine the load center, measure the distance from the face of the carriage to the gravitational center of the load. The rated capacity on the plate refers to the capacity of the lift truck as it left the factory. Subsequent changes of any form to the equipment or battery can alter the lift truck’s rating. The rated capacity of the lift truck applies to operating conditions where the lift truck is on level ground. The capacity of the lift truck is reduced on inclines. Below are abbreviations that may appear on the Identification, Lift Capacity and Attachment Plate and their meanings. Mast Abbreviations The identification plate indicates the type of mast installed on the lift truck when it left the factory. The type of mast is indicated by an abbreviation. - 38 - STD - Standard Mast(single inner member, low free lift). FF - Full Free Lift Mast (single inner member, with high free duplex or multiple cylinder.) General Section FFT - Triple Lift Mast (two inner members) with either low or full free lift. QUAD - Quadruple (Quad) Mast (three inner members). C SPEC - Special Mast, such as non-telescopic or double mast, not within the other classifications. NOTE : When only a mast-type is listed on the identification plate, a standard carriage and forks are used. Attachment Abbreviations Special Forks) - Special Carriage-increased width, height or outreach. SSS - Shaft-type Sideshift Carriage. HSS - Hook-type Sideshift Carriage(ITA). ISS - Integral Sideshift Carriage(ITA). CW - Special Counterweight. SF - Special Forks. SS-SWS - Sideshift-Swing Shift. ROTC - Rotating Carriage. - Carton Clamp. RC - Roll Clamp. LS - Load Stabilizer. LH - Log Handler. PWH - Pulp Wood Handler. SS-ST - Sideshift-Side Tilt Carriage. NOTE : Numbers following this abbreviation indicate number and/or length of forks. - Ram or Boom CC (Includes SC RAM BC - General Clamp (other than Bale, Carton or Roll). - Bale Clamp. DBCBH - Double Cube Block Handler HFP - Hydraulic Fork Positioner, Non Sideshift. CR - Crane Arm or Crane Boom. TH - Tire Handler. CTH - Container Top Handler. CSH - Container Side Handler LP - Load Push Device, Non Sideshift. LPP - Load Push-Pull Device, Non Sideshift. - 39 - Operation Section Operator’s Station and Monitoring Systems Read and understand the “Safety”, “Operation” and “Maintenance” sections before operating the lift truck. Key Switch Seat Switch IA8O3001 IB9O008P The key switch is located on the right side of the steering column. The seat switch is located under the operator’s seat. OPEN - When the operator’s seat is in the up position the electrical circuits are disconnected. CLOSE - When the operator’s seat is in the down position(operator seated) the electrical circuits are connected. The power steering pump motor is activated when the key switch is turned to ON and the seat switch is closed. IA8O3002 OFF - Turn the key switch to OFF (1) to disconnect the electrical circuits. ON - Turn the key switch the ON (2) to con nect the electrical circuits. If the key switch is left in the ON position when the operator leaves the lift truck, the LCD display will show a flashing “EE”. The power steering pump motor is activated when the key switch is turned to ON and the seat switch is closed. NOTE : The power steering pump motor will shut off if the directional lever is left in NEUTRAL and no control levers are actuated for approximately six seconds. The motor will be turned on when any control lever is used. - 40 - Operation Section Monitoring Systems Indicator Battery Discharge Indicator with Interrupt IA8O3007 IA8O3007 Located on the middle of the console cover panel. Indicates the battery state of charge, as shown by the LCD display on the instrument panel. A fully charged battery will cause a “6” segments displayed on the display. As the battery is discharged, the LCD display will count down 6,5,4,3 etc, until “EL” is displayed. The symbols shown on the instrument panel identify different features of the lift truck. The symbol for each feature is identified and an explanation of the function and location is described on the following pages. Run Time Diagnostic When “1 segment” is flashed the battery has reached 80% discharge level, the Micro-Controller will cause the display to continuously index through the entire range to signal, to the operator, that the battery is discharged and lift interrupt is imminent. If the warning is ignored lift interrupt will prevent the lift and tilt from operating and a “EL” (zero) will be flashed on the display. Replacement of the discharged battery will reset the lift interrupt and normal operation will resume again. IA8O3007 While operating the lift truck, diagnostic checks are constantly being made. The LCD display is used to indicate the following discrepancies from normal operation. - 41 - Operation Section Power On Indicator Fault Detection Circuit IA8O3007 IA8O3007 When the key switch is on and the seat switch is open an “EE” will flash on the display. This is to remind the operator to turn the key switch OFF when leaving the During lift truck operation the drive hydraulic pump circuits are continuously monitored for power circuit failure. Additional drive and pump circuit components are tested each time the key switch is turned on. Should a fault be detected, the lift truck will shut off and the display will alternately flash “F” and a code. lift truck. Static Return to Off The “F” plus code indicates the component failure. (Codes are listed on the schematic diagram on the inside of the control panel door and in the service manuals.) No LCD Display IA8O3007 If the directional control lever is placed in forward or reverse and/or the accelerator is depressed before both the key switch is turned to ON and the seat switch is closed, an “EE” will be shown on the display and the lift truck will not operate. The directional control lever must be returned to neutral and/or the accelerator released before the lift truck will operate. IA8O3007 If the LCD display does not show any indication when the key switch is on and theseat switch is closed, the line fuse and key fuse should be checked. On performance modes it is necessary to release the park brake to clear the “EE” from the display. NOTE : The LCD display indicates the lift truck discrepancies described, but will automatically return to the battery discharge with interrupt function when the problem is corrected. - 42 - Operation Section Over Temperature Self-Diagnostics Indicator IA8O3007 IA8O3007 IIf the control panel or motors should overheat, The high temperature symbol will be shown on the LCD display. Lift truck performance will be reduced until operating temperatures return to normal. When this occurs, the lift truck should be parked and permitted to cool. The LCD display is also used as an indicator for the self-diagnostics system built into the “MicroController.” A service mechanic can completely troubleshoot the electrical functions without additional diagnostic equipment. See the topic “Self-Diagnostics” in the Maintenance Section of this manual for further information on your particular model for self-diagnostics. NOTE : Refer to the “Test and Adjusting” section of the Service Manual or contact your DAEWOO Lift Truck dealer. Brief instructions are also printed on the wiring diagram and schematic, located on the back side of the control panel cover. Motor Brushes Wear Indicator IA8O3007 The “E1” or “E2” code is displayed when the motor brushes are worn and need to be replaced. Replace the brushes to reduce the risk of armature damage from overworn brush. - 43 - Operation Section Parking Brake Indicator Front and Rear Floodlights Switch IA8O3009 IB9O061P P The LCD below parking brake symbol will be lit when the park brake is applied. Located on the right side of the instrument panel, below the display panel. OFF - Push down on the left side of the switch to turn both front and rear flood lights off. Service Hour Meter Front Floodlights - Push down on the right side of the switch, to the first position, to turn the front floodlights on. Front and Rear Floodlights - Push down on the right side of the switch, to the second position, to turn both the front and rear floodlights on. The rear floodlights are optional. IA8O3008 Located on the RIGHT side of cowl. Indicates the total number of hours the lift truck has operated. Use it to determine service intervals. - 44 - Operation Section Horn Button Seat Adjustment Adjust the seat at the beginning of each shift or when changing operators. Adjust the seat to allow full travel of all pedals with the operator seated against the seat back. The seat must be adjusted with the operator seated. IA8O3010 Located in the center of the steering wheel. Push in on the horn button to sound the horn. Tilt Steering Column IA1O3013 Move the lever to adjust the seat forward or backward. Release the lever. Move the seat slightly to lock it. Emergency Switch (If Equipped) 1 ON OFF IA8O3011 Located on the lower front of the steering column. To adjust the steering column, raise the handle(1) and move the steering column to the desired position. Release the handle and the steering column will remain in the desired position. ID5O0011 OFF - Push the emergency switch button to disconnect the electrical circuits. (It must be done after the key switch is turned off) ON - Pull the emergency switch button to connect the electrical circuit. - 45 - Operation Section Lift Truck Controls Parking Brake Lever Service Brake Pedal NOTICE Do not engage the parking brake while the lift truck is moving unless an emergency arises. The use of the parking brake as a service brake in regular operation will cause severe damage to the parking brake system. IB9O020P Service Brake - The service brake pedal is located on the floor of the operator’s compartment. Depress the service brake pedal to slow or stop the lift truck. Drive circuit will be interrupted while the pedal is depressed. Release the service brake pedal to allow the lift truck to move. IA8O3012 B15/18/20T-2(36V), B13/15/18T-2(48V) B20T-2(48V) P Parking Brake - The parking brake lever is located on the left side of the cowl. Parking Brake Engaged - Pull the parking brake lever up, which will engage the interlock switch that shuts off power to the drive motor. Parking Brake Disengaged - Push the parking brake lever down to release the parking brake. - 46 - Operation Section Accelerator Pedal Directional Control Lever NOTICE The service brake and accelerator pedals should not be used at the same time, except for emergency situations. Use of both the brake and accelerator pedals at the same time may cause the drive motor to overheat. IA8O3016 Forward - Push the lever forward. The lift truck will move forward. Neutral - Move the lever to center position. The lift truck should not move when lever is in neutral. If the operator leaves the seat, or turns the key switch off, the lever must be returned to NEUTRAL. The lift truck will not move until accelerator pedal is released and lever is returned to NEUTRAL. ID5O0016 Accelerator Pedal - The accelerator pedal is located on the floor of the operator’s compartment. NOTE : Wait Mode of Operation - This condition will go into effect when the following occurs. The seat switch is closed, key switch is on and the directional control lever is left in NEUTRAL for more than five seconds, with no operator input to any control. Push down the pedal to increase travel speed. If the accelerator pedal is depressed before the key switch is turned to the ON position, the lift truck will not move until the pedal is released and depressed again. The line contactor will open and the power steering motor will turn off to conserve energy. The lift truck will remain in this mode until the operator moves the directional control lever, pushes on the accelerator pedal and/or moves any control valve lever. Release the pedal to decrease travel speed. Film for Function of Pedals (If Equipped) Reverse - Pull the lever toward the operator. The lift truck will move in reverse. NOTE : The directional control lever can be used for electrical braking(plugging). To slow or stop the lift truck when traveling in either direction, move the directional control lever to the opposite direction of travel while keeping the accelerator depressed. The lift truck will slow to a complete stop and then accelerate in the opposite direction. IB9O013P This film shows the function of the brake and accelerator pedals. When the operator raises off the seat (seat switch opens) while the lift truck is in motion, the drive - 47 - Operation Section Tilt Control Lever motor will lose power. When this occurs, release the accelerator, close the seat switch(operator seated), move the directional control lever to NEUTRAL and then to desired direction of travel. Push down on the accelerator. Lift Control Lever ID5O0014 The forks’ tilt control is located at the operator’s right side front. The tilt control lever is the lever at the center. Tilt Forward - Push the lever forward smoothly to tilt the forks forward. ID5O0013 The forks’ lift control is located at the operator’s right side front. The lift control lever is the lever at the left. Hold - Release the tilt lever. The lever will return to the center(hold) position and the forks will remain in the position they are in. Lower - Push the lever forward smoothly to lower the lift forks. Tilt Back- Pull the lever back smoothly to tilt the forks back. Hold - Release the lift lever. The lever will return to the center(hold) position and the forks will remain in the position they are in. NOTE : To prevent a sudden change of position of the load, operate all lift, tilt and attachment controls smoothly. Never tilt an elevated load forward past vertical. Raise - Pull the lever back smoothly to raise the lift forks. NOTE : To prevent a sudden change of position of the load, operate all lift, tilt and attachment controls smoothly. - 48 - Operation Section Sideshift Attachment Control (If Equipped) ID5O0015 The sideshift attachment control is located at the operator’s right side front. The sideshift attachment control lever is the lever at the right. Sideshift Left - Push the lever forward smoothly to shift the carriage to the left. Sideshift Hold - Release the sideshif attachment lever. The lever will return to the center(hold) position and sideshifting action will stop. Sideshift Right - Pull the lever back smoothly to shift the carriage to the right. NOTE : To prevent a sudden change of position of the load, operate all lift, tilt and attachment controls smoothly. - 49 - Operation Section Before Operating the Lift Truck Walk-Around Inspection For your own safety and maximum service life of the lift truck, make a thorough walk-around inspection before mounting the lift truck or starting to move it. Look for such items as loose bolts, trash build-up, oil leaks, condition of tires, mast, carriage, forks or attachments. IA8O3022 6. Inspect the tires and wheels for proper inflation, cuts, gouges, foreign objects and loose or missing nuts. 7. Inspect the overhead guard for damage, loose or missing mounting bolts. 8. Inspect the hydraulic system for leaks, worn hoses or damaged lines. IA8O3020 1. Inspect the operator’s compartment for looseitems and clean any mud or debris from the floor plates for safe footing. 9. Inspect the drive axle housing and the ground for oil leaks. 2. Inspect the instrument panel for damage to the indicator display. 3. Test the horn and other safety devices for proper operation. 10 IA8O3045 10. Disconnect the battery. Raise the lever bracket assembly to the full upright position. Tilt the steering column to the full upright position. IA8O3021 WARNING 4. Inspect the mast and lift chains for wear, broken links, pins and loose rollers. Batteries give off flammable fumes that can explode. 5. Inspect the carriage, forks or attachments for wear, damage and loose or missing bolts. Do not smoke when observing the battery electrolyte levels. Electrolyte is an acid and can cause personal injury if it contacts skin or eyes. Always wear protective glasses when working with batteries. - 50 - Operation Section IA8O3024 IA8O3025 11. Release the battery restraint lever in front of battery cover. Raise the seat and cover assembly. 15. Adjust the steering wheel to comfortable position. Grasp the steering wheel and raise the handle to release the steering column. PULL the steering column BACK or PUSH FORWARD to obtain the most comfortable position. RELEASE the knob and make sure the steering column is locked in this position. 12. Inspect the battery compartment for loose connections and frayed cables. 13. Observe the battery electrolyte level for proper level. Lower the seat and cover assembly and the lever bracket assembly and connect the battery to the lift truck. Secure the battery restraint properly. WARNING Personal injury may occur from accidents caused by improper seat adjustment. Always adjust the operator’s seat before operating the lift truck. IA8O3026 16. With the seat switch closed and the directional lever in NEUTRAL, turn the key switch ON. Observe the battery discharge indicator. Seat adjustment must be done at the beginning of each shift and when operators change. IA1O3013 IA8O3007 14. Position the seat by operating the lever and moving the seat forward or backward to a comfortable position. 17. Make sure the battery is charged before operating the lift truck. A fully charged battery will cause “6 Segments” to be displayed on the BDI display. - 51 - Operation Section Better Battery Performance NOTICE The lift truck operator must not start his shift with a battery that has been taken off a charger too soon. A battery should never be disconnected from a charge until the charge cycle has been completed. The batteries that have been fully charged should have a tag attached for identification. In Operation, a battery should be discharged then recharged in 8 to 12 hours, depending on the charger type. Then, they should be allowed to cool and stabilize 4 to 8 hours. Repeated undercharging must be prevented. It can damage the battery. If there is an indication of low battery operation, the lift truck operator should return the lift truck to the battery charging area. NOTE : Refer to the Maintenance Section of this guide for additional battery exchanging and charging information. - 52 - Operation Section Lift Truck Operation Be sure no one is working on or near the lift truck. Keep the lift truck under control at all times. Reduce speed when maneuvering in tight quarters or when braking over a rise. Do not allow the lift truck to overspeed downhill. Use the service brake pedal to reduce speed when traveling down hill. IB9O020P 4. Push down on the service brake pedal and release the parking brake. NOTICE Do not move directional control lever from one direction to the other(plug) when the drive wheels are off the ground and rotating at full speed. Damage can occur to the control panel. 1. Adjust the operator’s seat. IA8O3029 5. Turn the key switch ON. Raise the attachments to the travel position. IB9O018P 2. Fasten the seat belt (if equipped). 3. Move the directional control lever into the NEUTRAL position, if it is not already in this position. IA8O3030 6. Move the directional control lever to the desired direction of travel. - 53 - Operation Section IB9O020P IB9O020P 7. Release the service brake pedal. 11. Hold the accelerator pedal down until the lift truck nearly comes to a complete stop. Release the accelerator pedal. 12. Push down on the service brake pedal to bring the lift truck to a complete stop and hold it. 13. To change direction, continue to push down on the accelerator pedal until the desired travel speed in the opposite direction is obtained. 14. Do not use electrical braking (plugging) to stop the lift truck where the stopping distance is too short. Instead, release the accelerator pedal, push down on the service brake pedal, and bring the lift truck to a smooth stop. ID5O0016 8. Push down on the accelerator pedal to reach the travel speed. Release the pedal to decrease travel speed. 9. Electrical braking (plugging) can be used to slow or stop the lift truck or to change the lift truck direction of travel. See the section below, “Eletrical Braking (Plugging)” for an explanation of electrical braking. IA8O3032 10. Move the directional control lever to the opposite direction of lift truck travel. - 54 - Operation Section Electrical Braking (Plugging) IA8O3030 Electrical braking uses the drive motor’s own power to slow, stop or change direction when traveling in either direction. It is a more gradual type of stop, compared to using the service brakes. Electrical braking can be used for normal operation where there is adequate time and distance to stop safely. Electrical braking should NOT be used for sudden or emergency stops. To start electrical braking, move the directional control lever to the opposite direction while keeping the accelerator pedal depressed. The lift truck dirve control senses that the motors are turning opposite to the vehicle direction of travel and immediately goes into the plugging mode. Motor rotation is retarded at a predetermined rate by electrical braking (plugging). If the accelerator pedal is kept depressed, the drive control will slow the lift truck to a complete stop and then accelerate in the opposite direction. - 55 - Operation Section Operating Techniques NOTE : The illustrations used here are typical examples and may not look exactly like to your particular lift truck. Inching into Loads Lifting the Load 1. Move the lift truck slowly forward into position and engage the load. Lift truck should be square with load. The forks should be spaced evenly between pallet stringers and as far apart as the load will permit. IC6O005I 1. Lift the load carefully and tilt the mast back a short distance. 2. Tilt the mast further back to cradle the load. IC6O003I 2. Move the lift truck forward until the load touches the carriage. IC6O006I 3. Operate the lift truck in reverse until the load is clear of the other loads. IC6O004I 4. Lower the load to the travel position before turning or traveling. CAUTION The forklift truck must not be used to push loads or other vehicles. Only the moving equipment supplied or the rear hook for towing must be used. - 56 - Operation Section Traveling Turning Whether you are traveling with or without a load, keep the fork as low as possible, while still maintaining good clearance above the floor. IA103040 1. When turning sharp corners, keep close to the inside corner. Begin the turn when the inside drive wheel meets the corner. IC6O007I 1. Carry the load as low as possible, but maintain clearance. IA103041 2. In narrow aisles, keep as far from the stockpile as possible when making a turn into the aisle. Allow for counterweight swing. IC6O007I 2. On grades, alway travel with the load on the “uphill” side, as shown above. NOTE : The MicroCommand control uses the steer wheel angle signals to adjust drive motor speeds to match the steering cramp angle. With steer wheel cramp angles of 20° or more, the MicroCommand control limits drive motor speed to both drive motors. Limiting motor speed when turning reduces lift truck rotational speed while maintaining traction and power to both drive wheels. IC6O008I 3. Travel in reverse with bulky loads. This gives you better vision. - 57 - Operation Section Unloading IA8O3039 3. As the steer wheel angle increases, the inside drive motor speed is progressively slowed down with respect to the outside drive motor speed. It is essentially switched OFF when the steer wheel cramp angle is 45°. IC6O009I 1. Move the lift truck into the unloading position. 2. Do not tilt the mast forward until it is directly over the unloading area. WARNING Do not tilt the mast forward with the load unless directly over the unloading area, even if the power is off. IA8O3040 4. At a steer wheel cramp angle of 75°, the inside drive motor rotation is reversed and its speed will progressively increase as the cramp angle increases. 5. At a steer wheel cramp angle of 90°, the inside drive motor rotation, in reverse, is as fast as the outside drive motor rotation in forward. IC6O010I This causes the lift truck to turn about a point midway between the two drive tires. 3. Deposit the load and back away carefully to free the forks. 4. Lower the carriage and forks to either travel position or park position. - 58 - Operation Section Lifting Drums or Round Objects IA1O3043 1. Block the drums or round objects. Tilt the mast forward and slide the fork tips along the floor to get under the load. IA1O3044 2. Tilt the mast back slightly until the load is cradled on the forks before lifting. 3. Lift the load to the travel position. - 59 - Operation Section Parking the Lift Truck NOTICE Parking or storage of electric lift trucks outdoor can cause lift truck system damage or failure. Park or store all electric lift trucks inside a building to protect electrical system from moisture damage. When leaving the operator’s station, park the lift truck in authorized areas only. Do not block traffic. IA8O3043 B15/18/20T-2(36V), B13/15/18T-2(48V) Park the lift truck level, with the forks lowered and the mast tilted forward until the fork tips touch the floor. Block the drive wheels when parking on an incline. B20T-2(48V) IB9O020P 3. Engage the parking brake. 1. Apply the service brake to stop the lift truck. IA8O3044 ID5O0017 4. Tilt the mast forward and lower forks to the ground. 2. Move the directional control lever into NEUTRAL. - 60 - Operation Section IA8O3001 IA8O3046 7. Block the wheels if parking on an incline. 5. Turn key switch to OFF and remove the key. ID5O0018 B15/18/20T-2(36V) B13/15/18/20T-2(48V) 6. Disconnect the battery. - 61 - Operation Section Lift Fork Adjustment WARNING When adjusting the fork spread, be careful not to pinch your hand between forks and the carriage slot. Hook-on type Fork IB9O019P 1. Move up the hook pin to the free position in each fork to side the fork on the carriage bar. 2. Adjust the forks in the position most appropiate for the load and as wide as possible for load stability. 3. When adjusting the forks, make sure that the weight of the load is centered on the truck. 4. After adjustment, set the fork locks to keep the forks in place. WARNING Make sure the forks are locked before carrying a load. - 62 - Operation Section Storage Information Before Storage When storing the lift truck for an extended period of time, take the following measures to ensure that it can be returned to operation with minimal service. 1. After every part is washed and dried, the machine should be housed in a dry building. Never leave it outdoors. In case it has to be left outdoors, lay wooden boards on the ground, park the machine on the boards and cover it with canvas, etc. 2. Lubricate, grease and replace oil before storage. 3. Apply a thin coat of grease to exposed hydraulic cylinder piston rods. 4. Cover the battery after removing terminals, or remove it from the machine and store it separately. During Storage Drive the truck for a short at least once a month. This coats moving part surfaces with a new film of oil. Charge the battery at this same time. After Storage After storage(when it is kept without cover or rustpreventive operation once a month is not made), you should apply the following treatment before operation. 1. Remove the drain plug on hydraulic tank and drain any accumulated water. 2. Wipe off grease from hydraulic cylinder piston rod. 3. Measure specific gravity and check that the battery is charged. 4. Drive at low speed to make sure moving parts in drive gear boxes are well oiled. - 63 - Operation Section Transportation Hints Shipping 6. Disconnect the battery. Check travel route for overpass clearances. Make sure there is adequate clearance if the lift truck being transported is equipped with a high mast, overhead guard or cab. 7. Block the tires and secure the lift truck with tiedowns. Machine Lifting Information To prevent the lift truck from slipping while loading, or shifting in transit, remove ice, snow or other slippery material from the loading dock and the truck bed before loading. and Tiedown NOTICE Improper lifting or tiedowns can allow load to shift and cause injury and/or damage. NOTICE Obey all state and local laws governing the weight, width and length of a load. Observe all regulations governing wide loads. 1. Weight and instructions given herein apply to lift trucks as manufactured by DAEWOO. 2. Use properly rated cables and slings for lifting. Position the crane for level lift truck lift. NOTICE 3. Spreader bar widths should be sufficient to prevent contact with the lift truck. Remove ice, snow or other slippery material from the shipping vehicle and the loading dock. 4. Use the tiedown locations provided for lift truck tiedown. Check the state and local laws governing weight, width and length of a load. Contact your DAEWOO Lift Truck dealer for shipping instructions for your lift truck. IA1O3049 1. Always block the trailer or the rail car wheels before loading the lift truck. 2. Position the lift truck on the trailer or the rail car. 3. Apply the parking brake and place the transmission control in NEUTRAL. 4. Tilt the mast forward and lower forks to the floor. 5. Turn key switch OFF and remove the key. - 64 - Operation Section Towing Information Consult your DAEWOO Lift Truck dealer for towing a disabled lift truck. WARNING Personal injury or death could result when towing a disabled lift truck incorrectly. Block the lift truck wheels to prevent movement before releasing the brakes. The lift truck can roll free if it is not blocked. Follow the recommendations below to properly perform the towing procedure. The towing instructions given here are for moving a disabled lift truck only a short distance at low speed [no faster than 1.2 mph (2 km/h)] to a convenient location for repair. These instructions are for emergencies only. If long-distance moving is required, always haul the lift truck. IB9O011P B15/18/20T-2(36V), B13/15/18T-2(48V) You must provide shielding on the towing lift truck to protect the operator if the tow line or bar should break. Do not allow an operator to sit on the lift truck being towed unless the steering and braking can be controlled. The operator on the towed lift truck must always steer in the direction of the tow line pull. Inspect the tow line or bar and make sure it is in good condition and has enough strength for the towing situation involved. For a disabled lift truck stuck in mud or when towing on a grade, use a towing line or bar with a strength of at least 1.5 times the gross weight of the towing lift truck. B20T-2(48V) 1. Release the parking brake. Keep the tow line angle to a minimum. Do not exceed a 30˚ angle from the straight-ahead position. Connect the tow line as low as possible on the lift truck being towed. NOTICE Release the parking brake to prevent excessive wear and damage to the parking brake system. Use gradual and smooth lift truck movement. Moving the lift truck quickly could overload the tow line or bar and cause it to break. 2. Release the service brake pedal. 3. Turn the key switch OFF. Normally, the towing lift truck should be at least as large as the disabled lift truck. It should have enough brake capacity, weight, and power to control both lift trucks for the grade and distance involved. 4. Disconnect the battery. 5. Fasten the tow bar to the lift truck. A larger towing lift truck or additional lift trucks connected to the rear could be required to provide sufficient control and braking when moving a disabled lift truck downhill. This will prevent it from rolling uncontrolled. 6. Remove any wheel blocks. Tow the lift truck slowly. Do not tow any faster than 2 km/h (1.2 mph). The requirements of each towing situation will be affected by many conditions. Minimum towing lift truck capacity is required on smooth, level surfaces, while maximum capacity is needed on inclines or on poor surface conditions. Be sure all necessary repairs and adjustments have been made before a lift truck that has been towed to a service area is put back into operation. Personal injury or death could result. WARNING - 65 - Maintenance Section Inspection, Maintenance and Repair of Lift Truck Forks The following section gives practical guidelines for inspection, maintenance and repair of lift truck forks. It also provides general information on the design and application of forks and the common cause of fork failures. Users may also refer to the International Organization For Standardization-ISO Technical Report 5057-Inspection and Repair of Fork Arms and ISO Standard 2330-Fork Arms-Technical Characteristics and Testing. Lift truck forks can be dangerously weakened by improper repair or modification. They can also be damaged by the cumulative effects of age, abrasion, corrosion, overloading and misuse. While there are no specific standards or regulations in the United States, users should be familiar with the requirements for inspection and maintenance of lift trucks as provided by the 29 Code Federal Register 1910.178 Powerd Industrial Truck, and ANSI/ASME Safety Standard(s) B56.1, B56.5 or B56.6 as applicable to the type of machine(s) in use. A fork failure during use can cause damage to the equipment and the load. A fork failure can also cause serious injury. A good fork inspection and maintenance program along with the proper application can be very effective in preventing sudden on the job failures. Repairs and modifications should be done only by the fork manufacturer or a qualified technician who knows the material used and the required welding and heat treatment process. Users should evaluate the economics of returning the forks to the manufacturer for repairs or purchasing new forks. This will vary depending on many factors including the size and type of fork. Forks should be properly sized to the weight and length of the loads, and to the size of the machine on which they are used. The general practice is to use a fork size such that the combined rated capacity of the number of forks used is equal to or greater than the “Standard(or rated) Capacity” of the lift truck. The individual load rating, in most cases, will be stamped on the fork in a readily visible area. This is generally on the top or side of the fork shank. • A fork rated at 1500 pounds at 24 inch load center will be stamped 1500 X 24. • A fork rated at 2000 kg at 600 mm load center will be stamped 2000 X 600. The manufacturer identification and year and date of manufacture is also usually shown. Some countries have standards or regulations which apply specifically to the inspection and repair of forks. - 66 - Maintenance Section Causes of Fork Failure • Repetitive Overloading Repetitive cycling of loads which exceeds the fatigue strength of the material can lead to fatigue failure. The overload could be caused by loads in excess of the rated fork capacity and by use of the forks tips as pry bars. Also, by handling loads in a manner which causes the fork tips to spread and the forks to twist laterally about their mountings. Improper Modification or Repair Fork failure can occur as a result of a field modification involving welding, flame cutting or other similar processes which affect the heat treatment and reduces the strength of the fork. In most cases, specific processes and techniques are also required to achieve proper welding of the particular alloy steels involved. Critical areas most likely to be affected by improper processing are the heel section, the mounting components and the fork tip. • Wear Forks are constantly subjected to abrasion as they slide on floors and loads. The thickness of the fork blade is gradually reduced to the point where it may not be capable of handling the load for which it was designed. Bent or Twisted Forks • Stress Risers Forks can be bent out of shape by extreme overloading, glancing blows against walls or other solid objects or using the fork tip as a pry bar. Scratches, nicks and corrosion are points of high stress concentration where cracks can develop. These cracks can progress under repetitive loading in a typical mode of fatigue failure. Bent or twisted forks are much more likely to break and cause damage or injury. They should be removed from service immediately. Overloading Extreme overloading can cause permanent bending or immediate failure of the forks. Using forks of less capacity than the load or lift truck when lifting loads and using forks in a manner for which they were not designed are some common causes of overloading. Fatigue Parts which are subjected to repeated or fluctuating loads can fail after a large number of loading cycles even though the maximum stress was below the static strength of the part. The first sign of a fatigue failure is usually a crack which starts in an area of high stress concentration This is usually in the heel section or on the fork mounting. As the crack progresses under repetitive load cycling, the load bearing cross section of the remaining metal is decreased in size until it becomes insufficient to support the load and complete failure occurs. Fatigue failure is the most common mode of fork failure. It is also one which can be anticipated and prevented by recognizing the conditions which lead up to the failure and by removing the fork service prior to failing. - 67 - Maintenance Section Fork Inspection First Installation 1. Inspect forks to ensure they are the correct size for the truck on which they will be used. Make sure they are the correct length and type for the loads to be handled. If the forks have been previously used, perform the “12 Month Inspection”. If the forks are rusted, see “Maintenance and Repair”. 2. Make sure fork blades are level to each other within acceptable tolerances. See “Forks, Step 4,” in the “2000 Service Hours or Yearly” in “Maintenance Intervals” ID5O0019 Establish a daily and 12 month inspection routine by keeping a record for the forks on each lift truck. Initial information should include the machine serial number on each the forks are used, the fork manufacturer, type, original section size, original length and capacity. Also list any special characteristics specified in the fork design. 3. Make sure positioning lock is in place and working Lock forks in position before using truck. See “Forks, Step 7”, in the “2000 Service Hours or Yearly” in “Maintenance Intervals”. Record the date and results of each inspection, making sure the following information is included. Daily Inspection • Actual wear conditions, such as percent of original blade thickness remaining. 1. Visually inspect forks for cracks, especially in the heel section, around the mounting brackets, and all weld areas. Inspect for broken or jagged fork tips, bent or twisted blades and shanks. • Any damage, failure or deformation which might impair the use of the truck. • Note any repairs or maintenance. 2. Make sure positioning lock is in place and working. Lock the forks in position before using the truck. See “2000 Service Hours or Yearly” in “Maintenance Intervals”. An ongoing record of this information will help in identifying proper inspection intervals for each operation, in identifying and solving problem areas and in anticipating time for replacement of the forks. 3. Remove all defective forks from service. - 68 - Maintenance Section 12 Months Inspection With the fork restrained in the same manner as its mounting on the lift truck, apply the test load twice, gradually and without shock. Maintain the test for 30 seconds each time. Forks should be inspected, at a minimum, every 12 months. If the truck is being used in a multi-shift or heavy duty operation, they should be checked every six months. See “Forks” in the “2000 Service Hours or Yearly” in “Maintenance Intervals.” Check the fork arm before and after the second application of the test load. It shall not show any permanent deformation. Consult the fork manufacturer for further information as may be applicable to the specific fork involved. Testing is not required for repairs to the positioning lock or the markings. Maintenance and Repair 1. Repair forks only in accordance with the manufacturer’s recomendations. Most repairs or modifications should be done only by the original manufacturer of the forks or an expert knowledgeable of the materials, design, welding and heat treatment process. 2. The following repairs or modifications SHOULD NOT be attempted. • Flame cutting holes or cutouts in fork blades. • Welding on brackets or new mounting hangers. • Repairing cracks or other damage by welding. • Bending or resetting. 3. The following repairs MAY be performed. • Forks may be sanded or lightly ground, to remove rust, corrosion or minor defects from the surfaces. • Heel sections may be ground with a carbon stone to remove minor surface cracks or defects. Polish the inside radius of the heel section to increase the fatigue life of the fork. Always grind or polish in the direction of the blade and shank length. • Repair or replace the positioning locks on hook type forks. • Repair or replace most fork retention devices used with other fork types. 4. A fork should be load tested before being returned to service on completion of repairs authorized and done in accordance with the manufacturer’s recommendations. Most manufacturers and standards require the repaired fork to be tested with a load 2.5 times the specified capacity and at the load center marked on the fork arm. - 69 - Maintenance Section Tire Inflation Information Tire Inflation Tire Shipping Pressure The inflation pressures shown in the following chart are cold inflation shipping pressures for tires on DAEWOO lift trucks. Size Ply Rating or Strength Index Shipping Pressure kPa psi 1000 145 B13/15/18T-2 18 x 7 -8 IA1O4001 16 The operating inflation pressure is based on the weight of a ready-to-work lift truck without attachments, at rated payload, and in average operating conditions. Pressures for each application may vary and should always be obtained from your tire supplier. WARNING Personal injury or death could result when tires are inflated incorrectly. Use a self-attaching inflation chuck and stand behind the tread when inflating a tire. Tire Inflation Pressures Adjustment A tire inflation in a warm shop area, 18˚C to 21˚C (65˚F to 70˚F), will be underinflated if the lift truck works in freezing temperatures. Low pressure shortens the life of a tire. Proper inflation equipment, and training in using the equipment, are necessary to avoid overinflation. A tire blowout or rim failure can result from improper or misused equipment. NOTICE Set the tire inflation equipment regulator at no more than 140 kPa(20 psi) over the recommended tire pressure. - 70 - Maintenance Section Torque Specifications Torque for Standard Bolts, Nuts and Taperlock Studs Metric Hardware - This lift truck is almost totally metric design. Specifications are given in metric and U.S. Customary measurement. Metric hardware must be replaced with metric hardware. Check parts books for proper replacement. NOTICE NOTE : Use only metric tools on most hardware for proper fit. Other tools could slip and possibly cause injury. The following charts give general torques for bolts, nuts and taperlock studs of SAE Grade 5 or better quality. Torque for Standard Hose Clamps - Worm Drive Band Type Torques for Bolts and Nuts With Standard Threads NOTICE The following chart gives the torques for initial installation of hose clamps on new hoses and for reassembly or retightening of hose clamps on existing hose. 1 1 1 Newton meter (N•m) is approximately the same as 0.1 kg•m. - 71 - 1 Newton meter (N•m) is approximately the same as 0.1 kg•m. Maintenance Section Torque for Metric Fasteners Torques for Taperlock Studs NOTICE Be very careful never to mix metric with U.S. customary (standard) fasteners. Mismatched or incorrect fasteners will cause lift truck damage or malfunction and may even result in personal injury. Original fasteners removed from the lift truck should be saved for reassembly whenever possible. If new fasteners are needed, they must be of the same size and grade as the ones that are being replaced. The material strength identification is usually shown on the bolt head by numbers.(8.8, 10.9, etc.) The following chart gives standard torques for bolts and nuts with Grade 8.8. 1 NOTE : Metric hardware must be replaced with metric hardware. Check parts book for proper replacement. 1 Newton meter (N•m) is approximately the same as0.1 kg•m. - 72 - 1 1 Newton meter (N•m) is approximately the same as 0.1 kg•m. 2 ISO-International Standard Organization. Maintenance Section Lubricant Specifications Lubricant Information Hydraulic Oil Some classifications and abbreviations we use in this section follow S.A.E. (Society of automotive Engineers) J754 nomenclature and others follow S.A.E. J183. All MIL specifications are U.S.A. Military. Recommended oil viscosities are given in the “Lubricant Viscosities” chart later in this section of the manual. Greases are classified according to the National Lubricating Grease Institute (NLGI) based on ASTM D217-68 worked Penetration characteristics which give a defined consistency numbel. The following commercial classifications can be used in the hydraulic system. Chain and Linkage Oils (DEO or EO) • ISO 6743/4 • AFNOR NFE 48-603 • DIN 51524 TEIL 2 • HAGGLUNDS DENISON • CINCINNATI HM HM H-LP HFO-HF2 P68, 69, 70 Viscosity : ISO VG 32 These oils should have antiwear, antifoam, antirust and antioxidation additives for heavy duty use as stated by the oil supplier. ISO viscosity grade of 32 would normally be selected. NOTICE Correct Hydraulic Oil should be used to achieve maximum life and performance from hydraulic system components. The following hydraulic Oil is recommended in most hydraulic and hydrostatic systems. IA8O4001 Use following engine oils are recommended for use on chains and linkages. • European oil specification CCMC D3. Make-up oil added to the hydraulic tanks must mix with the oil already in the systems. Use only petroleum products unless the systems are equipped for use with special products. • API Specification CD, CD/SF, CE • Military specifications MIL-L-2104D or E If the hydraulic oil becomes cloudy, water or air is entering the system. Water or air in the system will cause pump failure. Drain the fluid, retighten all hydraulic suction line clamps, purge and refill the system.Consult your DAEWOO Lift Truck dealer for purging instructions. - 73 - Maintenance Section Drive Axle Oil B13/15/18/20T-2 (48V) B15/18/20T-2 (36V) NOTE : Do not use Gear Oil in the final drives or differentials. Gear Oil can cause seal material to fail and possibly leak oil. Select an oil that meets below specifications. NOTE : Failure to follow the recommendation will cause shortened life due to excessive gear wear. Automatic Transmission Fluid (ATF) The following AFT products are authorized for use. TOTAL AGIP ARAL AVIA BP CHEVRON DEA ELF ESSO FINA MOBIL PENNZOIL SHELL TEXACO WINTERSHALL The API CD/TO-2 specification or MIL-L-2104D, E or F oils could be used. FLUIDE II D ROTRA ATF DEXRON II ATF 33/F SGF 84 ATF 33 FLUID ATF 66M FLUID ATF 33G AUTRAN ATF AUTRAN DX II AUTRAN G AUTOMATIC TRANSMISSION FLUID DEAFLUID 1585 DEAFLUID 9226 DEAFLUID 9330 TRANS-O-MATIC ELFMATIC G2 DEXRON 22329 ELFMATIC G2 DEXRON 22011 ELFMATIC F TYPE SUFFLIX A ATF D-21065 ATF D-21611 ATF D-22079 Purfimatic FLUID DEXRON II D-22233 Purfimatic 33G ATF 200 ATF 210 ATF 220 TYPE F ATF DONAX TM ATF DEXRON II D-21666 DONAX TG PLUS D-22543 DONAX TG D-21126 DONAX TF TEXAMATIC FLUID 1585 TEXAMATIC FLUID 9226 TEXAMATIC FLUID 9330 ATF 2543 A ATF DEXRON ATF 33F NOTE : Multi-grade oils are not blended by DAEWOO for use in transmissions. Multigrade oils which use high molecular weight polymers as vicosity index improvers lose their viscosity effectiveness by permanent and temporary shear of the viscosity index improver and therefore, are not recommended for transmission and drive train compartments. Lubricating Grease Use Multipurpose Molybdenum Grease (MPGM) for all lubrication points. If MPGM grease can not be used, a multipurpose type grease which contains 3% to 5% molybdenum disulfide can be used. NLGI NO.2 grade is suitable for most temperatures. Use NLGI No.1 or No.0 grade for extremely low temperature. - 74 - Maintenance Section Brake Fluid B15/18/20T-2 (36V) B13/15/18/20T-2 (48V) IA8O4003 Located on the right side of the control valve cover. Located on the left side of the cowl. Use heavy duty hydraulic brake fluid certified by the oil supplier to meet SAE J1703f latest revision, DOT 3 or DOT 4 specifications. Use heavy duty hydraulic brake fluid certified by the oil supplier to meet ISO 6743/4 HM, ISO VG 10 latest revision. - 75 - TOTAL Azolla ZS 10 AGIP Acer 10 BP Energol HP 10 HLP 10 CALTEX Spindurn 10 ELF Spinelf 10 ESSO Nuto H 10 Spinesso 10 FINA Hydran 10 MOBIL Velocite oil No. 5 Velocite oil E SHELL Tllvs oil C10 Morlina 10 Maintenance Section Battery Discharge Indicator The battery discharge indicator should be observed frequently before and during operation. gravity. This specification varies with different battery manufacturers. See the manufacturer’s specifications for specific gravity at 80% discharge. If information is not available from the battery supplier, use 1.140 specific gravity level. IA8O3007 A fully charged battery will cause a “6 segments” to be displayed on the LCD display. As the battery is discharged, the LCD display will count down, 6, 5, 4, and etc., until “EL” is displayed. When the battery reaches 80% discharge level, the Micro-Controller will cause the LCD display to continuously index through the entire range (1 through 6 segments ) to signal that the battery is discharged and lift interrupt is imminent. IA8O3007 If the warning is ignored, lift interrupt will prevent the hydraulic pump motor from operating and an “EL” will be displayed on the LCD display. To prevent over-discharge, the lift interrupt should not be reset by disconnecting and reconnecting the battery. If the batteries are weak, have them charged or replaced. The batteries should not be discharged below 80% of the full charge as indicated by their specific - 76 - Maintenance Section Battery to cool and stabilize, A battery should never be disconnected from a charger until the charge cycle has been completed. WARNING When using pressure air for cleaning purposes, wear a protective face shield and protective clothing. Maximum air pressure must be below 207 kPa (30 psi). Low battery operation must be prevented. Operation with a low battery may cause damage to the battery. Low battery operation will cause higher than normal current in the electrical system. This can damage contactor tips or shorten motor brush life. Do not smoke near batteries that are being stored or when checking the electrolyte level. Electrolyte is an acid solution and can cause personal injury. Avoid contact with skin and eyes. Batteries that have been fully charged should have a tag attached for identification. A battery should be recharged in 8 to 12 hours after being discharged, depending on the charger type, then allowed to cool and stabilize 4 to 8 hours. Repeated undercharging must be prevented because it can damage the battery. Maximum life and performance of lift truck batteries is dependent on the operator, battery charging, maintenance and service. A battery requires an equalizing charge at least once every 20 normal charge/discharge cycles. This helps correct and prevent unequal cell specific gravity (SG) readings. An “equalizing charge” is a cycle charge with modification, given usually at an interval to bring all cells up to a state of equal charge. An equalizing charge usually adds three to four more hours to the cycle charge, at a low finish rate. It is usually given when the specific gravity (SG) of electrolyte has a variation of more than 20 points (.020) from cell to cell, after a regular cycle charge. Most dirt and dust picked up by the battery can usually be blown off with low pressure compressed air. However, if cells are overfilled and electrolyte collects on the covers, the top of the battery will stay wet. If necessary, clean the top of the battery with a solution of baking soda and hot water. NOTICE A “cycle charge” will completely recharge the battery. The typical cycle charge for a fully discharged battery usually is an eight-hour charge. The battery must be recharged before it has been discharged over 80% of the rated capacity of the battery. The work shift of the lift truck can be planned so the battery will not be discharged more than 80%. Vent caps must be tight to prevent soda solution from entering battery cells. To make the solution, add 0.5 kg (1 lb) of baking soda to 4 liters (1 gallon) of water. Use a brush having flexible bristles. Apply the soda solution to the top of the battery until the cleaning action of the soda stops. A battery should never be left in a discharged state because of sulfate formation. This reduces battery life drastically. To extend life always recharge the battery without delay after it has been discharged. After cleaning action has stopped, rinse batteries thoroughly with water. Dry the batteries with low air pressure. Repeated over discharging of the battery will damage the cells, which will shorten battery life and increase operating cost. Battery life(number of cycles) decreases as the depth of discharge increases. The estimated life of the battery The lift truck operator must not start his shift with a battery that has been taken off a charger too soon. Batteries are designed to be charged and allowed - 77 - Maintenance Section discharged to 80% will be approximately twice as long as if it were discharged 100%. NOTICE The battery’s maximum temperature is critical. The electrolyte temperature should never exceed 43˚C (110˚F) either while operating or charging. If higher temperatures are maintained through use or abuse, reduced battery service life can be expected. • DISPOSAL OF OLD BATTERY Careless disposal of a battery can harm the environment and can be dangerous to persons. Always dispose of a battery to an authorized personnel only. Do not attempt to open or dismantle a battery or a cell. Battery condition is important for a long life. The elecrolyte level should be maintained at the recommended levels and the battery should be kept clean and dry. “Washing down” batteries at different time periods will reduce the chance of “grounds” caused by electrolyte spills and corrosion. If done often enough, just washing with water alone will eliminate the need for using baking soda. If not, a solution of baking soda and water must be used to wash battery at different time periods. Add water at regular intervals. Enough water should be added to bring the electrolyte approximately 13.0 mm (.50 inch) above the plates. This is a simple matter with the use of an automatic cell filler, which shows a light when the correct level has been reached. Water should always be added before charging to be sure thorough mixing with acid when gassing occurs near the end of charging period. Use distilled water or have the water supply analyzed. Charge batteries correctly. It is important that all batteries should be charged according to the manufacturer’s instructions. Most of the charging equipment is fully automatic and should be checked periodically. Never operate the lift truck with a fully discharged battery because this will damage the battery. When charging, proper provision must be made for venting of the charging gases. Battery container lids and the covers of battery compartments must be opened or removed. The vent plugs should stay on the cells and remain closed. When a battery charger operates correctly and brings a good battery up to full charge, the current readings will level to the “finish rate.” The charging voltage will stabilize, the specific gravity will stop rising and normal gassing can be seen. - 78 - Maintenance Section Cold Storage Applications Hydraulic System When an electric lift truck is operated in cold storage applications, at temperatures as low as -20˚C (-4˚F), the battery capacity is decreased. Operation at cold temperatures can also cause mechanical failures, short circuits and too much wear due to the formation of ice crystals. The direct cause of these problems is the extreme changes in temperature in combination with humidity in the air which can result in condensation. To protect the electric lift truck’s components and decrease the effects of the cold temperature, perform the following items before you put the lift truck to work in cold storage applications. Drain the hydraulic system and fill it with SAE 5. MIL-H-5606A hydraulic oil Battery Lift Chains There is a reduction in battery capacity in cold storage applications. For this reason, it is important to : 1. Remove the chains Clean them in a nonflammable cleaning solvent. 1. Be sure the battery is completely charged at the start of each work cycle. 2. Put the chains in molybdenum disulfide (MPGM) grease for one hour. Then, before installation, hang the chains, where they will not move, for three hours. 2. If possible, keep the lift truck in a warm storage area when it is not in use. 3. Do not store a discharged battery at below freezing temperature. IA8O4004 3. Put MPGM grease on the chains at one-week intervals. IA8O3007 4. Check chains very carefully for wear on the link plate edges, caused when they run over the sheaves. Check the chains regularly for cracked links, loss of shape in the holes, and corrosion. Observe the battery discharge indicator frequently. - 79 - Maintenance Section Lubricant Viscosities and Refill Capacities Lubricant Viscosities Refill Capacities REFILL CAPACITIES-(APPROXIMATE) LUBRICANT VISCOSITIES FOR AMBIENT (OUTSIDE) TEMPERATURES C Compartment Oil or System Viscosities Min Max ISO VG 22 -30 Hydraulic and Power Steering ISO VG 32 -20 System ISO VG 46 -10 ISO 6743/4 HM ISO VG 68 0 36V ATF -20 SAE -20 *Drive 10 W API Axle 48V CD/TO-2 SAE Housing +10 30 *Brake 36V SAE J1703f Reservoir 48V ISO VG 10 -30 F Min Max +20 -22 +68 +30 -4 +86 +40 +14 +104 +50 +32 +122 +80 -4 +176 +22 -4 +72 +50 +50 +122 +50 -22 +122 * For the detailed information about the lubricant specifications, see “Lubricant Specifications” section. The SAE grade number indicates the viscosity of oil A proper SAE grade number should be selected according to ambient temperature. - 80 - Compartment or System Liters U.S. Gal Imperial Gal Hyraulic & Power Steering System 18 5 4.5 Drive Axle Housing 0.7 0.18 0.15 Brake Reservoir 0.6 0.16 0.13 Maintenance Section Maintenance Intervals Every 250 Service Hours or Monthly NOTICE Brake Oil Level - Check ................................... 110 Drive Axle Oil Level - Check ............................ 111 Parking Brake - Test ........................................ 111 Hydraulic Oil Level - Check .............................. 112 Wheel Bolts - Check......................................... 112 Mast, Carriage, Lift Chains & Attachments - Inspect, Lubricate .......................................................... 113 All maintenance and repair, except every 10 service hours or daily, on the lift truck must be performed by qualified and authorized personnel only. NOTICE Careless disposal of waste oil can harm the environment and can be dangerous to persons. Always dispose of waste oil to an authorized personnel only. Every 500 Service Hours or 3 Months Tilt Cylinders - Check, Adjust, Lubricate .......... 114 Crosshead Rollers - Inspect ............................. 115 Mast Hinge Pins - Lubricate ............................. 116 Steering Mechanism - Lubricate ...................... 116 Drive Axle Oil - Change.................................... 116 Overhead Guard - Inspect................................ 116 Control Panel - Clean, Inspect ......................... 117 Directional Lever - Check ................................. 118 Quick Reference to Maintenance Schedule..............................82 When Required Self Diagnostics - Test ........................................83 Carriage Roller Extrusion - Adjust.......................96 Head Capacitor - Discharge ...............................96 Brushes - Check, Replace ..................................97 Fuses - Replace ..................................................99 Seat - Lubricate.................................................100 Every 1000 Service Hours or 6 Months Drive Axle Oil - Change.................................... 119 Drive Motor - Clean, Inspect ............................ 119 Hydraulic Return Filter - Change...................... 121 Tires and Wheels - Inspect, Check .................. 121 Hydraulic Pump Motor - Clean, Inspect .......... 122 Lift Chains - Test, Check, Adjust ...................... 124 Every 10 Service Hours or Daily Walk-Around Inspection - Inspect .....................101 Mast Channels - Lubricate ................................103 Battery - Check, Exchange, Charge .................103 Indicator - Check ...............................................105 Tires and Wheels - Inspect ...............................106 Back-up Alarm (If Equipped) - Test...................106 Every 2000 Service Hours or Yearly Steer Wheel Bearings - Reassemble ............... 126 Forks - Inspect ................................................. 127 Air Breather - Change ...................................... 129 First 50 - 100 Service Hours or a Week Every 2500 Service Hours or 15 Months Drive Axle Oil - Change.....................................107 Hydraulic Oil & Strainer - Check, Change ........ 130 First 250 Service Hours or a Month Hydraulic Return Filter - Change.......................109 - 81 - Maintenance Section Air Breather Change Back-up Alarm(If Equipped) Battery Test 106 Check,Exchange,Charge 103 129 Brake Oil Level Brushes Check Check, Replace 110 97 Carriage Roller Extrusion Control Panel Crosshead Rollers Directional Lever Drive Axle Oil Drive Axle Oil Level Drive Axle Oil(36V) Adjust Clean, Inspect Check Check Change Check Change 96 117 116 118 107 111 119 Drive Axle Oil(48V) Drive Motor Change Clean, Inspect 116 119 Forks Fuses Head Capacitor Hydraulic Oil & Strainer Hydraulic Oil Level Hydraulic Pump Moter Hydraulic Return Filter Indicator Lift Chains Mast Carriage, Chains & Attachments Mast Channels Mast Hinge Pins Overhead Guard Parking Brake Seat Self Diagnostics Steer Wheel Bearings Steering Mechanism Tilt Cylinders Tires & Wheels Tires & Wheels Walk-Around Inspection Wheel Bolts Inspect 127 Replace 99 Discharge 96 Check,Change 130 Check 112 Clean, Inspect 122 Change 109,121 Check 105 Test, Check, Adjust 124 Inspect,Adjust,Lubricate 113 Lubricate 103 Lubricate 116 Inspect 116 Test, Adjust 111 Check, Lubricate 100 Test 83 Reassemble 126 Lubricate 116 Check,Adjust,Lubricate 114 Inspect 106 Inspect,Check 121 Inspect 101 Check, Inspect 112 - 82 - 2500 Service Hours or 15 Months 2000 Service Hours or a Year 1500 Service Hours or 9 Months 1000 Service Hours or 6 Months 250 Service Hours or a Week EVERY 10 Serive Hours or a Day 250 Service Hours or a Month PAGE 50-100 Service Hours or a Week SERVICES When Required ITEMS FIRST 500 Service Hours or 3 Months Quick Reference to Maintenance Schedule Maintenance Section When Required You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Self Diagnostics - Test 5. Move the key switch to OFF. Prepare for the Self - Diagnostic Test The Micro-Controller has a built-in diagnostic system to provide aid in rapid troubleshooting of lift truck problems. NOTE : Make sure the battery is fully charged before any of the following tests are made. After the self-diagnostics tests have been started, the procedure does not have to be completed. At any point the procedure can be interrupted, and the lift truck made ready for operation. ID5O0018 B15/18/20T-2(36V) IA8O4005 1. Park the lift truck level, with the forks lowered and the mast tilted forward until the fork tips touch the floor. B13/15/18/20T-2(48V) 6. Disconnect the battery. 2. Block the drive wheels. 3. Release the parking brake. IA8O4006 B15/18/20T-2 (36V) IA8O3026 4. Move the directional control lever to NEUTRAL. - 83 - Maintenance Section ID5O0020 B13/15/18/20T-2 (48V) B13/15/18/20T-2 (48V) 8. Discharge the head capacitor. See topic “Head Capacitor” in this section. 7. Remove the control panel cover. WARNING Personal injury could result if head capacitor has not been discharged properly. Battery voltage and high amperage are present. The HEAD capacitor must be discharged before any contact with the electrical control system is made. ID5O0021 Before touching any electrical components, remove rings, watches and other metallic objects from the hands and arms, then discharge the HEAD capacitor. B13/15/18/20T-2 (48V) ID5O0022 B15/18/20T-2 (36V) 9. Disconnect line fuse to prevent lift truck movement. IA8O4007 B15/18/20T-2 (36V) - 84 - Maintenance Section IA8O4065 IA8O4006 B15/18/20T-2 (36V) B15/18/20T-2 (36V) B13/15/18/20T-2(48V) B13/15/18/20T-2(48V) 12. Connect the battery. 10. Loosen the four screws to remove the logic unit cover. IA8O3002 13. Turn the key switch to ON. If the line fuse has not been disconnected the LCD display will show a “d”. Further testing is not possible until the line fuse is disconnected. IA8O4010 11. Toggle the diagnostic switch from the “Run” to the “Diagnostic” position. - 85 - Maintenance Section Perform the self - Diagnostic Tests The tests will be performed in order. The LCD display will advance one number upward, upon the successful completion of each test. If the test detects a failure, the number will not advance. See the “Service Manual” testing and adjusting section of “Lift Trucks Micro-Controller Control System” to see if the failed component should be replaced or repaired. A test that failed can be bypassed to test remaining components by moving the diagnostic toggle switch from “Diagnostic” to “Run” and back to “Diagnostic”. The tests are performed as follows : IA8O3007 An “A0” will be displayed, in the LCD, if the logic module circuitry is correct. An “F” will be displayed, in the LCD, if a failure is detected. Logic Module Circuitry A “d” will be displayed, in the LCD, if the line fuse has not been disconnected. Seat Switch ID5O0021 B13/15/18/20T-2 (48V) IB9O008P Close the seat switch by depressing the seat and then release. ID5O0022 B15/18/20T-2 (36V) The logic module circuitry will be automatically checked if the line fuse has been disconnected. IA8O3007 The seat is depressed, the LCD display “A1”. And the seat is released, the LCD display “A0”. If still “A0” or “A1”, a failure has been detected. - 86 - Maintenance Section Directional Control Lever IA8O3007 The directional control lever is forward, the LCD display “A3”. And the directional control lever is neutral, the LCD display “A0”. IA8O3026 Move the directional control lever from neutral to reverse to neutral. If still “A0” or “A3”, a failure has been detected. Lift Control Lever IA8O3007 The directional control lever is reverse, the LCD display “A2”. And the directional control lever is neutral, the LCD display “A0”. ID5O0013 Pull the lift control lever slowly to maximum position and then release. If still “A0” or “A2”, a failure has been detected. IA8O3026 IA8O3007 Move the directional control lever from neutral to forward to neutral. The LCD display the speed that the lift lever is set to. As lever is , , pulled back, 1 through 3 will be shown.And the lift control lever is released, the LCD display “A0”. If still “A0”, a failure has been detected. - 87 - Maintenance Section Tilt Control Lever IA8O3007 With the auxiliary control lever in maximum position, the LCD will display “A7” and “A0” when the lever is released. ID5O0014 Pull the tilt control lever to maximum position and then release. Parking Brake Lever IA8O3007 With the lift control lever in maxmum position, the LCD will display “A6” and “A0” when the lever is released. IA8O3043 Pull the parking brake lever to maximum position and then release. If still “A0” or “A6”, a failure has been detected. Auxiliary Control Lever IA8O3007 With the parking brake lever in maximum position, the LCD will display “A9” and “A0” when the lever is released. ID5O0015 Pull the auxiliary control lever to maximum position and then release. If there is no auxiliary control lever, skip to next procedure. If still “A0” or “A9”, a failure has been detected. - 88 - Maintenance Section Accelerator Pedal IA8O3007 The LCD display “AC” and then contactors are activated in order. (Line contactor bypass contactor left forward direction contactor right forward direction contactor left reverse direction contactor right reverse direction contactor) IA8O3031 Depress the accelerator pedal fully and then release. Reverse Side) Direction Contactor (Right This completes the self-diagnostics tests. Turn the key switch to the OFF position and disconnect the battery. IA8O3007 NOTE : If the lift truck still has a problem after the Self-Diagnostic tests have been completed, see the Service Manual or contact your DAEWOO Lift Truck dealer for additional information. The accelerator pedal is depressed, the speed symbols are increase from 0 to 10 on the LCD. The accelerator pedal is released, the speed symbols are decrease to 0. If the speed symbols are not full on the LCD, a failure has been detected. Contactor Test Switch IA8O4012 1. Move the slide switch to the “Run” position. IA8O4011 Move the DIAG/RUN/SETUP switch from DIAG to RUN and then back to DIAG position. - 89 - Maintenance Section ID5O0021 IA8O4006 B15/18/20T-2 (36V) B13/15/18/20T-2 (48V) ID5O0022 B13/15/18/20T-2 (48V) B15/18/20T-2 (36V) 2. Install the logic unit cover. 3. Connect line fuse. IA8O4013 4. Install the control panel cover. 5. Connect the battery. - 90 - Maintenance Section Diagnostic tests Diagnostic procedure is essentially the same as the standard model’s, but contains some additional tests. Refer to the following table, and previous text and pictures to determine correct diagnostic procedure. Display status Step Procedure Circuit Active Normal 1 Turn the key switch on with battery connected Internal circuit Fuse removal A0 2 Depress the seat and then release Seat switch A1 A0 3 Release the park brake level and move the directional lever to reverse then to neutral A2 A0 A3 A0 Directional switch 4 Move the directional lever to forward then to neutral 5 Pull the lift lever to maximum position and then release Lift switch 1, 2, 3 A0 6 Pull the tilt lever to maximum position and then release Tilt switch A6 A0 7 Pull the auxiliary lever to maximum position and then release Auxiliary switch A7 A0 8 Pull enough the parking brake lever and then release Parking brake switch A9 A0 9 Depress the accelerator pedal to maximum and then release Accelerator control Accelerator Speed symbol 10 Move the DIAG/SETUP switch to RUN position and then back to DIAG position Contactors Line Bypass Left Fwd Right Fwd Left Rev Right Rev AC 11 Pull the tilt lever and then release See "Store error codes" Error Codes 12 The end of the diagnostics E NOTE : You must ask DEAWOO service man for fine tuning of logic assembly. - 91 - Maintenance Section Stored error Codes Service Records Saving The logic card will remember up to 24 of the last error codes. This is useful in case the truck has an intermittent problem, or thermal condition, and the operator cannot remember what exactly happened. By analyzing the contents of the last 24 Error codes, one may recall the last thermal conditions or error codes that have appeared on the display. These error codes are accessed at the end of selfdiagnostics, by using the following procedure. To save service records, the following procedures are used at the end of self-diagnostics and service record are numbers between 1-9. 1. Move the direction control lever to the forward position after accessing the error codes and displaying “E”. 2. Display shows a solid “8d” move the DIAG/RUN/ SETUP switch to the SETUP position and back to DIAG two times. 1. Access the self diagnostics procedure as previously described. 3. Pull the tilt lever to maximum position and then release. 2. Either step through the diagnostic procedure, or override each test by moving the DIAG/RUN/ SETUP switch from DIAG to RUN and back to DIAG until the contactor testing is complete. 4. A saved service records will show for a few seconds. 5. Wait until the display will show a flashing “8d”, the display indicates that a service record have been saved. 3. Cycle the DIAG/RUN/SETUP switch once more, and cycle through the contactor testing again. The error codes can now be accessed one at a time by moving the TILT lever to maximum and then back to NEUTRAL position. This will display the most recent error code. By cycling the lever more times, more error codes will appear on the display, up to a total of twenty four. When the display shows a solid “E”, it indicates that all of the error codes have been displayed. It is also possible that all error codes may be the same, and the display will not change between lever cycles. 6. Turn OFF the key switch. Error Codes Erasing To erase all of the error codes, the following procedures are used at the start of self-diagnostics. 1. Move the direction control lever to the reverse and the DIAG/RUN/SETUP switch to the DIAG position. 2. Turn on the key switch and wait until display shows a solid “8b”, then move the DIAG/RUN/ SETUP switch to the SETUP position and back to DIAG two times. And move the direction lever to neutral. 3. Wait until the display show “A0”, the display indicates that all error codes have been erased. - 92 - Maintenance Section Programmable or Settable Feature The logic card contains a number of features which are either settable or programmable. The following is a list of the features, however the “Service Manual” or your DAEWOO dealer should be consulted in determining which options may be beneficial to the application. PROGRAM FEATURE DESCRIPTION 0 Creep Speed 1 Maximum steering speed 2 Electrical assist brake 3 Discharged battery reset value 4 Top travel speed Limit 6 Wait timer 7 Discharged battery drive speed 8 Acceleration travel speed time 9 Excessive Drive motor current 10 Battery type selection 11 Maximum idle speed 12 Maximum lift 1. speed 13 Maximum lift 2. speed 14 Maximum tilt speed 15 Maximum Auxiliary Speed 16 Hydraulic Ramp Timer - 93 - Maintenance Section Possible Stored Error The following are the possible error codes stored in memory. Most error codes are identical to the one displayed during RUN. See “Service Manual” for further explanation and troubleshooting of any of the following error codes. ERROR CODES DESCRIPTION F0 Excessive drive motor current F2 Drive circuit problem (Left side short) "F2" (Flashing) Drive circuit problem (Right side short) F3 Pump circuit problem (Short) F4 Drive and pump circuit problem (All short) F5 Drive circuit problem (Left side open) "F5" (Flashing) Drive circuit problem (Right side open) F6 Pump circuit problem (Open) F7 Drive and pump circuit problem (All open) FA Angle circuit problem Fb Battery abnormal condition Fd Pressure switch circuit problem E1 Drive motor brush problem E2 Pump motor brush problem Ec Controller thermal problem Ed Drive motor thermal problem EP Pump motor thermal problem EL Battery lock-out Non Stored Error The following are error codes not stored in memory. Most error codes are identical to the one displayed during RUN. See “Service Manual” for further0 explanation and troubleshooting of any of the following error codes. ERROR CODES EE "EE" (Flashing) DESCRIPTION Static Return to OFF error (SRO) Seat switch circuit problem - 94 - Maintenance Section General Displaying Codes The following are the general displaying codes and indicate any operation status GENERAL CODES DESCRIPTION OK System normal operation PP Wait operation E 8b/A0 8d/"8d" (Flashing) The end or the diagnostics Error code erase (preparation/completion) Service record save (preparation/completion) - 95 - Maintenance Section Carriage Roller Extrusion - Adjust Head Capacitor - Discharge 1. Set the mast vertical. WARNING 2. Lower the carriage completely. Personal injury could result if head capacitor has not been discharged properly. 3. On full free lift and full free triple lift models, the bottom of the inner mast must be flush with the bottom of the stationary mast. Battery voltage and high amperage are present. The HEAD capacitor must be discharged before any contact with the electrical control system is made. INNER MAST Before touching any electrical components, remove rings, watches and other metallic objects from the hands and arms, then discharge the HEAD capacitor. A Carriage roller extrusion IB2O638I 4. Measure the distance from the bottom of the inner upright to the bottom of carriage bearing. 5. The measurement (A) must be as follows in Chart below. Height of carriage roller extrusion (A) STD mast FF mast FFT mast -6 8 8 IA8O4007 B15/18/20T-2 (36V) ID5O0020 B13/15/18/20T-2 (48V) The head capacitor is located in the control panel at the rear of the lift truck. - 96 - Maintenance Section Brushes - Check, Replace Refer to “Drive Motor” and/or “Hydraulic Pump Motor” section in “Every 1000 Service Hours or 6 Months” section of “Maintenance Intervals” if brush wear is suspected. Brush Seating 1. All new drive and hydraulic motor brushes must be seated. For drive motor brush seating, lift the front of the lift truck until the drive wheels are off the floor and free to turn. Put adequate stands under the frame to support the lift truck. ID5O0018 B15/18/20T-2(36V) NOTICE Do NOT move the directional control lever from one direction to the other when the drive wheels are off the ground and rotating at full speed. Damage can be caused to the control panel. B13/15/18/20T-2(48V) 1. Disconnect the battery. ID5O0023 B15/18/20T-2 (36V) IA8O4013 2. Remove the control panel cover. 3. Before touching any electrical components, the HEAD capacitor must be discharged. Put a 90 ohm, 30 watt resistor in position between the terminals of the HEAD capacitor as shown. Hold the resistor in this position for approximately ten seconds. This will discharge the capacitor. 4. Perform any necessary maintenance and repair at this time. B13/15/18/20T-2 (48V) 5. Install the control panel cover. 2. Use a brush seating stone for drive and hydraulic motors. 6. Connect the battery. - 97 - Maintenance Section 3. Put the seating stone in position on the commutator. Operate the motor slowly and move the seating stone from side to side, at the back edge of the brushes for a short time. This will take the shine off the commutator and seat the brushes. NOTICE Do NOT let the seating stone stay in contact with the commutator for too long. It will cause more wear than necessary to the brushes and the commutator. ID5O0025 B15/18/20T-2 (36V) 4. Check the contact surface of the brushes. At least 85% of the brush contact surface must show contact with the commutator. If necessary repeat the seating procedure. NOTE : Do NOT use a brush seating stone that is shorter than 63.5 mm (2.50 inch). WARNING Pressure air can cause personal injury. When using pressure air for cleaning, wear a protective face shield, protective clothing and protective shoes. ID5O0024 B13/15/18/20T-2 (48V) The maximum air pressure must be below 205 kPa (30 psi) for cleaning purposes. 5. While operating the motor slowly, blow out all of the abrasive grit and dust with 205 kPa (30 psi) air pressure. - 98 - Maintenance Section Fuses - Replace The fuses are located in the control panel and fuse box at the rear of the lift truck. They protect the electrical system from damage caused by overloaded circuits. Change a fuse if the element separates. If the element of a new fuse separates, have the circuit checked and repaired. ID5O0034 NOTICE B13/15/18/20T-2 (48V) Replace fuses with the same type and size only. Otherwise, electrical damage can result. Key switch- 10 amps If it is necessary to replace fuses frequently, an electrical problem may exist. Contact your DAEWOO Lift Truck dealer. ID5O0021 B13/15/18/20T-2 (48V) Main Fuse - 600 amps IA8O4018 Horn - 10 amps DC/DC converter - 10 amps Lights(1) - 10 amps Lights(2) - 10 amps 2 1 ID5O0035 B15/18/20T-2 (36V) Main Fuse (1) - 600 amps HYD Fuse (2) - 350 amps IA8O4019 B15/18/20T-2 (36V) - 99 - Maintenance Section Seat - Lubricate IA8O3003 Check the operation of the seat adjusters. Make surethat the seat slides freely on its track. Lightly oil the seat slider tracks. - 100 - Maintenance Section Every 10 Service Hours or Daily You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Walk-Around Inspection - Inspect IA8O4025 IA8O4024 1. Inspect the operator’s compartment for loose item and clean any mud or debris from the floor plates. 6. Inspect the tires, valve stems and wheels for cuts, gouges, foreign objects and loose or missing nuts. Refer to “Tires and Wheels” in “Every 10 Service Hours or Daily” section, if repairs or replacement is necessary. 2. Inspect the instrument panel for damage to the Iindicator display. 3. Test the horn and other warning devices for proper operation. IA8O4026 7. Inspect the overhead guard for damage, loose or missing mounting bolts. IA8O4005 4. Inspect the mast and lift chains for wear, broken links, pins and loose rollers. 5. Inspect the carriage, forks or attachments for wear, damage and loose or missing bolts. IA8O4027 8. Inspect the hydraulic system for leaks, worn hoses or damaged lines. - 101 - Maintenance Section IA8O3026 IA8O4028 9. Inspect the drive axle housing and the ground for oil leaks. Refer to “Drive Axle Oil” in “Every 1000 Service Hours or 6 Months” section, if an oil leak is found. 12. Move the directional lever to NEUTRAL. IA8O3002 13. Turn the key switch to ON. IA8O4029 10. Adjust the operator’s seat. IA8O3007 IA8O4030 11. Adjust the steering wheel to a comfortable position. 14. Check the LCD display for battery discharge status. A fully charged battery will be displayed on the LCD display. 15. Check the operation of parking brake, service brake, controls and other devices that may be equipped on your lift truck. - 102 - Maintenance Section Mast Channels - Lubricate Battery - Check, Exchange, Charge Battery Access Park the lift truck level, with the forks lowered and the mast tilted forward until the fork tips touch the floor. IA8O4031 The channels on the roller-type mast require a break-in period. Apply a light film of lubricant on the channels where the rollers ride. This will prevent metal peel until the rollers set a pattern. ID5O0018 B15/18/20T-2(36V) B13/15/18/20T-2(48V) 1. Disconnect the battery. 2. Tilt the steering column to the full upright position and move the seat fully rearward. IA8O4033 3. Release the hood latch lever which retain the seat and battery cover. 4. Raise the seat and battery cover. - 103 - Maintenance Section Check Electrolyte 3. Check the specific gravity of the battery. If the specific gravity reading is below 1.150, the battery must be charged. NOTICE The battery should not be used if a difference in specific gravity between two cells is greater than .020. If this condition exists, the battery should be put on an equalization charge. If this does not correct the condition, consult your battery supplier. IA8O4034 1. Inspect the battery compartment for loose connections, frayed cables and properly secured battery restraint. 4. Check the electrolyte level of all cells. Maintain the electrolyte level about 13 mm (.50 inch) above the plates. Add water as needed. Use only distilled water. Add water before charging the battery. 2. Clean the top of the battery. If necessary, clean the top of the battery with a solution of baking soda and hot water. 5. Lower the seat and battery cover. To closed position and secure with the latch on the front of the cover. 6. Connect the battery. NOTICE Vent caps must be tight to prevent soda solution from entering battery cells. Battery Exchanging A clean battery top is essential to avoid conductive paths on higher voltage batteries. NOTE : Batteries should be changed, water added and charged only in areas where proper protective and ventilation facilities are provided. To make the solution, add 0.5 kg (1 lb) of baking soda to 4 liters (1 gallon) of water. Use a brush having flexible bristles. Apply the soda solution to the top of the battery until the cleaning action of the soda stops. After cleaning action has stopped, rinse batteries thoroughly with water. Dry the batteries with low air pressure. 1. Refer to “Battery Access” topic for battery access. 2. Cover the battery with hinged battery cover or with plywood. 3. Install insulated battery tree and hoist, of sufficient capacity, to the battery. 4. Remove the battery. Recharge the battery. 5. Install a fully charged battery. 6. Remove the battery tree. Remove hinged battery cover or plywood from the top of the battery. 7. Connect the battery. IA8O4035 8. Lower the seat and battery cover to closed position and secure with the latch on the front of the cover. 9. Adjust the seat position. - 104 - Maintenance Section Battery Charging WARNING When charging, proper provision must be made for venting of the charging gases. Battery container lids and the covers of battery compartments must be opened or removed. The vent plugs should stay on the cells and remain closed. With Battery Installed in Lift Truck B20T-2(48V) 1. Refer to “Battery Access” topic for battery access. 2. Engage the parking brake. 2. Connect the battery to the charger and charge the battery. Observe safety warnings for charging batteries. 3. When the battery is fully charged, disconnect the battery from the battery charger. 4. Connect the battery to the lift truck. 5. Lower the seat and battery cover to closed position and secure with the latch on the front of the cover. 6. Adjust the seat position. IA8O3026 Indicator - Check 3. Move the directional control lever to the NEUTRAL position. 4. Close the seat switch. IA8O3001 1. Turn the key switch to ON. IA8O3007 5. Check the indicator LCD display for the discharge state of the battery. IA8O3043 B15/18/20T-2(36V), B13/15/18T-2(48V) - 105 - Maintenance Section Tires and Wheels - Inspect IA8O4038 Inflate the tires, if necessary. See “Tire Inflation Information” section of this manual. IA8O4036 Inspect tires and valve stems for wear, cuts, gouges and foreign objects. Back-up Alarm (If Equipped) - Test IA8O4037 Check all components carefully and replace any cracked, badly worn, damaged and severely rusted or corroded parts with new parts of the same size and type. If there is any doubt, replace with new parts. Do not, under any circumstances, attempt to rework, weld, heat or braze any rim components. IA8O3026 With the key switch on, apply the service brake and move the directional control lever into REVERSE. The alarm should start to sound immediately. It will continue to sound until the directional control lever is moved to NEUTRAL or FORWARD. Check Inflation Pressure (If equipped with pneumatic tires) IA1O4001 Measure the tire air pressure on each tire. - 106 - Maintenance Section First 50 - 100 Service Hours or a Week You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Drive Axle Oil - Change 6. Maintain the oil level. B15/18/20T-2 (36V) 7. Screw the oil filling plug in with the seal ring. After the first 50~100 hour of operation, subsequently after every 1000 hour or 6 Months. 8. Raise the mast and remove the blocking. IA8O4062 Park the lift truck level, with the parking brake engaged and directional control lever in NEUTRAL. B13/15/18/20T-2 (48V) 1. Raise the mast and block in place. After the first 50 ~ 100 hour of operation, subsequently after every 500 hours or 3 months. 2. Turn the key switch to OFF. 3. Unscrew oil filling plug and remove the drain plug. Allow the oil to drain. 4. Clean and install the drain plugs. Park the lift truck level, with the parking brake engaged and directional control lever in NEUTRAL. 1. Raise the mast and block in place. 2. Turn the key switch to OFF. 5. Fill the drive axle housing with oil, the accurate amount of oil is defined by the opening for the oil filling plug. 3. Unscrew oil air - breather (Oil filling plug) (1), level checking plug (2) and remove the drain plug (3). Allow the oil to drain. - 107 - Maintenance Section 1 2 3 IB9O063P 5. Fill the drive axle housing with oil through air breather plug hole( 1 ) , the accurate amount of oil is defined by the opening of level checking plug( 2 ). 6. Maintain the oil level. 7. Screw the level checking plug( 2 ) and air breather in with the seal ring. 8. Raise the mast and remove the blocking. 1 2 IB9O064P - 108 - Maintenance Section First 250 Service Hours or a Month You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Hydraulic Return Filter - Change WARNING Hot oil and components can cause personal injury. Do not allow hot oil or components to contact skin. Park the lift truck level with the forks lowered, parking brake engaged, directional lever in NEUTRAL and the key switch to OFF. 1. Loosen the bolts of the hydraulic tank top plate assembly. Return Filter IC6O014I 2. Remove the return filter by hand and discard it. 3. Install a new filter assembly. 4. Install the tank top plate assembly and fasten the bolts. - 109 - Maintenance Section Every 250 Service Hours or Monthly You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Brake Oil Level - Check IA8O4039 B13/15/18/20T-2(48V) B15/18/20T-2(36V) 2. Maintain the brake fluid level in the brake system reservoir. 3. Clean and install the filler cap. B13/15/18/20T-2(48V) 1. Remove the filler cap. IA8O4041 B15/18/20T-2(36V) - 110 - Maintenance Section Drive Axle Oil Level - Check Parking Brake - Test NOTE : Be sure area around the lift truck is clear of personnel and obstructions. 1. Drive the lift truck with a rated load up a 15% incline. WARNING To prevent personal injury, the operator must be ready to use the service brake if the parking brake is not adjusted correctly and the lift truck starts to move. IA8O4074 1. Park the lift truck on a level surface. Raise the carriage high enough to gain access to the housing level/fill plugs. 2. Use blocking to secure the carriage in this position. IA8O3028 2. Halfway up the incline, stop the lift truck by applying the service brakes. IA8O4075 B15/18/20T-2(36V) IA8O3043 B15/18/20T-2(36V), B13/15/18T-2(48V) B13/15/18/20T-2(48V) 3. Remove the housing level/fill plugs. Maintain lubricant level to the bottom of the plug opening. Install the level/fill plugs. 4. Remove blocking. Lower the carriage. B20T-2(48V) 3. Engage the parking brake. 4. Release the service brake. If the parking brake has the correct adjustment, the lift truck will be held in place. NOTE : The lift truck may move slightly while the parking brake is engaging. 5. If the parking brake does not hold, adjust the parking brake lever screw. - 111 - Maintenance Section Hydraulic Oil Level - Check 1. Inspect tightness of wheel nuts in a sequence opposite each other 140 N•m (105 lb•ft). In case of dual steer tire, tighten the nuts 113 N•m (85 lb•ft) in B15/18/20T-2(36V) or 180 N•m (135 lb•ft) in B13/15/18/20T-2(48V). Drive Wheels 1. Operate the lift truck for a few minutes to warm the oil. 2. Park the lift truck level, with the forks lowered, mast tilted back (all cylinders retracted), parking brake engaged, directional control lever in NEUTRAL, and the key switch to OFF. IA8O4073 B15/18/20T-2(36V) 3. Open the hood. 4. Remove the dipstick 5. Maintain the oil level to the full mark on the breather/dipstick. 6. Install the dipstick. 7. Install the access cover. B13/15/18/20T-2(48V) Wheel Bolts - Check Steer Wheels 2. Inspect tightness of wheel nuts in a sequence opposite each other to 140 N•m (105 lb•ft) in B15/ 18/20T-2(36V). In case of B13/15/18/20T-2(48V), tighten the nuts 180 N•m (135 lb•ft). IA8O4022 Typical example - 112 - Maintenance Section Mast, Carriage, Lift Chains & Attachmemts - Inspect, Lubricate IA8O3001 5. Raise and lower the carriage a few times to work lubricant into the chain links. IA8O4044 1. Operate the lift, tilt and attachment controls. Listen for unusual noises. These may indicate a need for repair. NOTICE Lubricate chains more frequently than normal where the atmosphere can cause corrosion to components, or when lift truck must work in rapid lift cycles. IA8O4027 2. Inspect for loose bolts and nuts on the carriage and load backrest. Remove any debris from the carriage and mast. 3. Inspect the forks and attachments for free operation and damage. Have repairs made if needed. IA8O4051 6. Inspect the chain anchors and individual links for lwear, loose pins or cracked leaves. NOTE : Have all reparis and adjustments made as required. IA8O4004 4. Brush in a film of oil on all links of the chain. - 113 - Maintenance Section Every 500 Service Hours or 3 Months You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Tilt Cylinders - Check, Adjust, Lubricate Mast Pivot Eyes - Check, Lubricate Chassis Pivot Eyebolts - Lubricate IA8O4049 1. Lubricate the mast pivot eyes, one fitting on each side of the mast. IA8O4046 1. Remove floor plates. IA8O4050 IA8O4047 2. Lubricate pivot eyebolts, one fitting on each tilt cylinder. 2. Check the mast pivot eye pins for loose retainer bolts and wear. Cylinder Rod Extension - Adjust IA8O4052 IA8O4048 3. Check the pivot eye pins for loose retainer bolts and wear. 1. Tilt the mast to the full forward position. - 114 - Maintenance Section Crosshead Rollers - Inspect 1. Operate the mast through a lift cycle. Watch the chains move over the crosshead rollers. Make sure the chain is tracking over the rollers properly. IA8O4053 2. Measure the extended length of the cylinder rods from the cylinder housing to the pivot eye. The cylinder rods must be within 3.18 mm (.125 inch) of each other. IA8O4054 Typical example 2. Check for damaged crosshead rollers, guards and retainer rings. IA8O4053 3. To adjust the cylinder rod extension, loosen bolt. 4. Turn the cylinder rod in or out of pivot eye to obtain the proper adjustment. Turning the rod into pivot eye shortens the stroke. Turning the rod out of pivot eye lengthens the stroke. 5. Tighten bolt to a torque of 95L15 N.m (70L10 lb ft). Check the cylinder rods again for even travel. 6. With the mast at the tilt back position, install shims as required to permit no gap between pivot eye and spacer, so the mast does not twist at full tilt back position. - 115 - Maintenance Section Mast Hinge Pins - Lubricate Steering Mechanism - Lubricate Lubricate two fittings Lubricate one fitting IA8O4055 1. Lower the forks and tilt the mast forward. IA8O4057 Lubricate fitting on steer axle. Drive Axle Oil - Change B13/15/18/20T-2 (48V) Only See topic, “Drive Axle Oil - Change” in “First 50 - 100 Service Hours or a Week”. Overhead Guard - Inspect IA8O4056 B15/18/20T-2(36V) IA8O4044 B13/15/18/20T-2(48V) 2. Lubricate the mast hinge pins. One fitting on each side of the mast. Total of two fittings. Look for any loose or damaged bolts. Replace damaged bolts or missing bolts with original equipment part only. Retighten bolts to a torque of 60L10 N•m (45L7 lb•ft). Check the overhead guard for bent or cracked sections. Repair if needed. - 116 - Maintenance Section Control Panel - Clean, Inspect Park the lift truck level, with the forks lowered, parking brake engaged, directional control lever in NEUTRAL, and the key switch to OFF. Disconnect the battery. IA8O4059 2. Discharge the head capacitor. See “Head Capacitor” in “When Required” section of this manual. WARNING Pressure air can cause personal injury. IA8O4006 When using pressure air for cleaning, wear a protective face shield, protective clothing and protective shoes. B15/18/20T-2 (36V) The maximum air pressure must be below 205 kPa (30 psi) for cleaning purposes. B13/15/18/20T-2 (48V) 1. Remove the access cover. IA8O4060 WARNING Battery voltage and high amperage are present. The HEAD capacitor must be discharged before any contact with the control panel is made. Personal injury could result if it has not been discharged properly. 3. Clean the control panel with 205 kPa (30 psi) maximum air pressure, until dust is removed from the control panel. - 117 - Maintenance Section Directional Lever - Check IA8O4060 4. Check movement of contactors and inspect contactor tips for burning or pitting. Replace if needed. IA8O3025 Check the tightness of the directional lever mounting bracket. Adjust if needed. IA8O4061 5. Inspect all wiring for loose connections, frayed cables and loose mounting bolts. 6. Inspect the fuses for looseness, corrosion and broken connections. IA8O3025 Check for ease of movement of directional lever. Adjust if needed. Check for loose wiring. Secure wiring if needed. IA8O4065 B15/18/20T-2(36V) B13/15/18/20T-2(48V) 7. Install the access cover and connect the battery. - 118 - Maintenance Section Every 1000 Service Hours or 6 Months You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Drive Axle Oil - Change B15/18/20T-2 (36V) Only See topic, “Drive Axle Oil - Change” in “First 50 - 100 Service Hours or a week”. Drive Motor - Clean, Inspect IA8O4066 4. Fasten lift chains, of equal length, in lift openings in the front of the lift truck. 5. Slowly lift the front of the lift truck, until the drive wheels are just off the ground. 6. Put stands under the frame. Remove the tension on the lift chains. ID5O0018 B15/18/20T-2(36V) 7. Remove the battery. 8. Remove the floor plate. 9. Unlatch and remove the commutator screen cover. 10. Connect the battery. Turn the key switch to ON and apply pressure to the seat switch. B13/15/18/20T-2(48V) NOTICE 1. Disconnect the battery. Do not move directional lever from one direction to the other when the drive wheels are off the ground and rotating. 2. Block the steer wheels. 3. Remove the battery. See topic, “Battery” in “Every 10 Service Hours or Daily” section of this manual. Damage can be caused to the control panel. - 119 - Maintenance Section Ensure that all brushes move freely in their holders. Use compressed air until all brushes are free to move. WARNING Battery voltage and high amperage are present. The HEAD capacitor must be discharged before any contact with the control panel is made. Type of Motor Personal injury could result if it has not been discharged properly. 11. Operate the drive motor slowly. Blow off the drive motor brush area with 205 kPa (30 psi) maximum air pressure, until dust is removed from the motor. 1 12. Release the pressure on the seat. Turn the key switch to OFF. Disconnect the battery. Change Brush Minimum if Length is Allowable Brush Less Than Length Limit1 Drive Motor (48V) 22 mm (.87 in) 20 mm (.79 in) Drive Motor (36V) 20 mm (.79 in) 18 mm (.72 in) When the minimum brush length is less than the dimension shown, replace all brushes. When the brush is used beyond this dimension, motor damage could result. 2 1 IA8O4070 IA8O4068 Typical example Typical example 13. Remove the brush retainer clip by pushing down and in toward the brush to release it from the brush holder. Then, pull out on the clip to remove it. 15. To replace the brushes, loosen the retaining screws (1) and disconnect the wires (2). Remove the brushes from the holders. 16. Connect the wires on the new brushes. Install the brushes in the holders. 17. Install the brush retainer clips. Make sure the brushes move freely in the holder. 18. Seat the new brushes. See “Brushes” in “When Required” section of this manual. 19. Install the commutator screen cover. 20. Install the floor plate. IA8O4069 Typical example 14. Remove the brush from the holder. Measure the length of the brush on the longest side. 21. Slowly lift the front of the lift truck and remove the stands. Lower the lift truck to the floor. Remove the chains. - 120 - Maintenance Section 22. Install and connect the battery. Lower the battery cover and adjust the seat. Always stand behind the tread of the tire, NOT in front of the rim. Lift truck capacity is dependent on tire type. Your lift truck dealer should be consulted for possible down ratings when pneumatic tires are used to replace solid (cushion) tires. NOTE : To check the brush wear indicator wiring, connect one end of a jumper wire to the negative(-) side of the battery and touch the other end of the wire to the brush wear indicator terminal on the side of the motor. Hydraulic Return Filter - Change See topic, “Hydraulic Return Filter - Change” in “First 250 Service Hours or a Month”. Tires and Wheels - Inspect, Check IA8O4072 WARNING Servicing and changing tires and rims can be dangerous and should be done only by trained personnel using proper tools and procedures. If correct procedures are not followed while servicing tires and rims, the assemblies could burst with explosive force and cause serious physical injury or death. Follow carefully the specific information provided by your tire serving man or dealer. Do NOT inflate a tire that has been run while flat or underinflated, without first checking to make sure the locking ring on the wheel is not damaged and is in position. When tires are changed be sure to clean all rim parts, and if necessary, repaint to stop detrimental effects of corrosion. Sand blasting is recommended for removal of rust. Check all components carefully and replace any cracked, badly worn, damaged and severely rusted or corroded parts with new parts of the same size and type. If there is any doubt, replace with new parts. Do not, under any circumstances, attempt to rework, weld, heat or braze any rim components. IA8O4071 Inspect tires for wear, cuts, gouges and foreign objects. Look for bent rims and correct seating of locking ring. If equipped with pneumatic tires, check tires for proper inflation. See topic, “Tire Infaltion Pressure.” To inflate tires always use a clip-on chuck with minimum 60 cm (24 inches) length of hose to an inline valve and gauge. - 121 - Maintenance Section Hydraulic Pump Motor - Clean, Inspect 1. Disconnect the battery. 2. Remove the battery. See topic, “Battery - Check, Exchange, Charge” in the “Every 10 hours or Daily” section of this manual. 3. Open the hood. IA8O4073 B15/18/20T-2(36V) ID5O0024 B13/15/18/20T-2 (48V) B13/15/18/20T-2(48V) 1. Install drive wheel. Install two nuts opposite each other (144°) in B15/18/20T-2(36V) or (180°) in B13/15/18/20T-2(48V). 2. Install the remaining nuts. Tighten all nuts in a crisscross sequence opposite each other (144°) to 140L25 N•m (105L20 lb•ft) in B15/18/20T2(36V) or (180°) to 180 L25 N•m (135L20 lb•ft) in B13/15/18/20T-2(48V). 3. Reverse the lifting procedure for the front of the lift truck and lower it to the ground. ID5O0025 B15/18/20T-2 (36V) - 122 - Maintenance Section 4. Unlatch and remove the commutator screen cover. Change Brush Minimum if Length is Allowable Brush Less Than Length Limit1 Type of Motor 5. Connect the battery. Turn the key switch to ON and apply pressure to the seat switch. WARNING Pressure air can cause personal injury. When using pressure air for cleaning, wear a protective face shield, protective clothing and protective shoes. 1 The maximum air pressure must be below 205 kPa (30 psi) for cleaning purposes. 6. Operate the hydraulic pump motor slowly. Blow off the drive motor brush area with 205 kPa (30 psi) maximum air pressure, until dust is removed from the motor. Hyd. Motor (48V) 22 mm (.87 in) 20 mm (.79 in) Hyd. Motor (36V) 17 mm (.67 in) 15 mm (.60 in) When the minimum brush length is less than the dimension shown, replace all brushes. When the brush is used beyond this dimension, motor damage could result. 2 1 7. Release the pressure on the seat. Turn the key switch to OFF. Disconnect the battery. 8. Remove the brush retainer clip by pushing down and in toward the brush to release it from the brush holder. Then, pull out on the clip to remove it. ID5O0030 Typical example 10. Replace the brushes by loosening the retaining screws (1) and disconnect the wires (2). Remove the brushes from the holders. 11. Connect the wires on the new brushes. Install the brushes in the holders. 12. Install the brush retainer clips. Make sure the brushes move freely in the holder. 13. Seat the new brushes. See “Brushes” in “When Required” section of this manual. IA8O4079 14. Install the commutator screen cover. Typical example 15. Close the hood. 9. Remove the brush from the holder. Measure the length of the brush on the longest side. Ensure that all brushes move freely in their holders. Use compressed air until brushes are free to move. 16. Install and connect the battery. NOTE : To check the brush wear indicator wiring, connect one end of a jumper wire to the negative(-) side of the battery and touch the other end of the wire to the brush wear indicator terminal on the side of the motor. - 123 - Maintenance Section Lift Chains - Test, Check, Adjust Check for Equal Tension Lift Chain Wear Test Inspect the part of the chain that is normally operated over the cross head roller. When the chain bends over the roller, the movement of the parts against each other causes wear. Inspect to be sure that chain link pins do not extend outside of the link hole. If any single link pin is extended beyond its connecting corresponding link, it should be suspected of being broken inside of its link hole. Lift chains are required to check for wear about every 1,000 service hours or 6 months. IB2O640P Typical example Chain wear test is a measurement of wear of the chain links and pins. Take the following steps to check chain wear. 1. Lift the mast and carriage enough for getting ension on lift chains. Lift the carriage and the mast high enough for getting tension on lift chains. Check the chains, and make sure the tension is the same. Lift chains are required to check for equal tension about every 1,000 service hours or 6 months. WARNING Personal injury can be caused by sudden movement of the mast and carriage. Keep hands and feet clear of any parts that can move. Lift Chain Adjustment IB2O639P Typical example 2. Measure precisely ten links of chain distance at the center of pins in millimeter. 3. Calculate chain wear rate*. 4. If the chain wear rate is 2% or more, replace the lift chain. * Chain wear rate (%) Actual measurement - Pitch** X 10 = Pitch** X 10 ( **Chain Pitch = 15.88 mm(0.63 in) IB2O639P )x100 Typical example for carriage equal tension If the tension is not the same on both chains, take the procedure as follows. NOTE : If carriage height is not correct, make adjustments by following procedures. - 124 - Maintenance Section Carriage Chain Adjustment Mast Chain Adjustment - FF,FFT Mast Make sure that carriage height is correct. If correct, adjust the chain for equal tension. If not, adjust the chain for correct carriage height by adjusting anchor nuts(1),(2). 3 NOTE : See the previous section, “Carriage Roller Extrusion” in “When Required”. for proper height of carriage. 4 1. Fully lower the carriage and tilt mast forward or lift the carriage and put blocks under the carriage to release the tension from the lift chains. 2. Loosen nut(1) and adjust nut(2) to get proper distance from bottom of inner upright to the bottom of carriage bearing. IB2O643P Typical example for FF mast 3 2 4 1 IB2O644P Typical example for FFT mast IA8O4083 Make sure that mast height is correct. If correct, adjust chain for equal tension. If not, adjust mast chain for correct mast height by adjusting anchor nuts(3),(4). Typical example for carriage chain of STD mast 2 NOTE : See the previous section, “Carriage Roller Extrusion” in “When Required”. for proper inner mast height. 1. Lift the inner mast and put blocks under the inner mast to release the tension from the lift chains. 1 2. Loosen nut(3) and adjust nut(4) to make inner mast rail flush with outer mast rail bottom. IB2O642P 3. Make adjustment anchor nuts(3),(4) for equal chain tension. Typical example for carriage chain of FF,FFT mast 3. Make adjustment anchor nut(1),(2) for equal chain tension. 4. Raise the inner mast and check equal chain tension. If not equal, repeat the same procedure as step 1 through step 3. 4. Set the mast vertical and raise the carriage and check equal chain tension. If not equal, repeat the same procedure as step 1 through step 3. 5. Put LOCTITE No. 242 Tread lock on the threads of the anchor nuts(1),(2) after the adjustment is completed. 5. Put LOCTITE No. 242 tread lock on the threads of the anchor nuts(3),(4) after the adjustment is completed. - 125 - Maintenance Section Every 2000 Service Hours or Yearly You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Steer Wheel Bearings - Reassemble IA8O4091 IA8O4089 2. Remove wheel nuts (1). Remove steer wheel (2). 1. Turn steer wheel 90° with lug nuts exposed. IA8O4092 IA8O4090 NOTE : When lifting the rear of the lift truck, apply the parking brake and block the drive tires. Using two equal length chains, place chain hooks under counterweight lip, at each end of the steer wheel opening or a hydraulic floor jack and a block of wood in the center of the wheel opening. Raise the lift truck slowly and block under the counterweight at the outer ends. Lower the lift truck on the blocking. 3. Remove the cover. Bend lockwasher tab back and remove locknut (3). Remove the lockwasher, washer and spacers. Remove the hub group seal and the bearings. 4. Inspect the bearings and the seal for wear or damage. Replace if necessary. Reassemble the bearing. Install bearing (4) and seal (5). Lubricate seal lip (5) lightly with bearing lubricant. - 126 - Maintenance Section Forks - Inspect B A 5. Install hub group(6) . Pack area (7) with bearing lubricant. Install bearing (8). Install the spacers, washer, lockwasher and locknut (3). Hand tighten the locknut. IA1O4092 Forks should be inspected, at a minimum, every 12 months. If the truck is being used in a multi-shift or heavy duty operation, they should be checked every six months. 1. Inspect the forks carefully for cracks. Special attention should be given to the heel section (A), all weld areas and mounting brackets (B). Inspect the top and bottom hooks on forks used on hook type carriages and tubes on shaft mounted forks. Forks with cracks should be removed from service. IA8O4095 6. Install the steer wheel. Put two nuts opposite each other (144°) in B15/18/20T-2(36V) or (180°) in B13/15/18/20T-2(48V). Tighten both. Install all remaining nuts. Tighten all nuts in a crisscross sequence opposite each other (144°) to a torque of 140L25 N•m (105L20 lb•ft) in B15/18/20T2(36V) or (180°) to 180 L25 N•m (135L20 lb•ft) in B13/15/18/20T-2(48V). “Wet Test” magnetic particle inspection is generally preferred due to its sensitivity and the ease of interpreting the results. Portable equipment is usually recommended so it can be moved to the lift truck. Inspectors should be trained and qualified in accordance with The American Society for NonDestructive Testing, Level II Qualifications. Contact your local DAEWOO Lift Truck Dealer for further information. C IA8O4096 7. While rotating the wheel, tighten the locknut to 34 N•m (24 lb•ft). Loosen the nut completely. Tighten the nut again to a torque of 11L3 N•m (8L2 lb•ft) and lock within this range. Install the cover. 8. Raise the lift truck and remove the blocking. Lower the lift truck to the floor. IA1O4093 2. Check the angle between the upper face of the - 127 - Maintenance Section blade and the front face of the shank. The fork should be withdrawn from service if angle (C) exceeds 93 degrees or deviates by more than 3 degrees from an original angle other than 90 degrees, as may be found in some special application forks. H J E G D IA1O4096 difference. 5. Check the fork blade (J) and shank (H) for wear with special attention to the heel (G). The fork should be withdrawn from service if the thickness is reduced to 90 percent or less of the original thickness. IA1O4094 3. Check the straightness of the upper face of blade (D) and the front face of shank (E) with a straight edge. Fork blade length may also be reduced by wear, especially on tapered forks and platens. Remove the forks from service when the blade length is no longer adequate for the intended loads. The fork should be withdrawn from service if the deviation from straightness exceeds 0.5 percent of the length of the blade and/or the height of the shank respectively 5 mm/1000 mm (0.18”/36”). M K F IA1O4097 6. Check the fork mountings (K) for wear, crushing and other local deformation, which can cause excessive side to side wobble of the forks. Excessive clearance on hook type forks may allow them to fall from the carrier. Forks which show visible signs of such damage should be removed from service. L IA1O4095 4. Check the difference in height of one fork tip to the other when mounted on the fork carrier. A difference in fork tip height can result in uneven support of the load and cause problems with entering loads. The maximum recommended difference in fork tip elevation (F) is 6.5 mm (0.25”) for pallet forks and 3 mm (0.125”) for fully tapered forks. The maximum allowable difference in fork tip elevation between the two or more forks is 3 percent of blade length (L). Replace one or both forks when the difference in fork tip height exceeds the maximum allowable 7. Check the positioning lock and other fork retention devices to make sure they are in place and working. Hook type forks use a spring loaded pin (M), located in the top hook, to engage notches in the top carriage bar to hold the fork in place. When adjusting the fork spacing, the forks are prevented from sliding off the end of the carriage by stop blocks. These stop blocks are at both ends of the carriage and in the path of the bottom fork hook. - 128 - Maintenance Section The load backrest extension may be used in place of the stop blocks in some cases. Shaft mounted forks may use set collars or spacers on the shaft to either side of the fork. They may also use U bolts, pins, or similar devices which engage the fork through the top structure of the carriage. Air Breather - Change Park the lift truck level, with the forks lowered, parking brake engaged, directional lever in NEUTRAL and the key switch to OFF. 1. Open the hood. 2. Remove the right side top cover. N IC1O0102 8. Check fork markings (N) for legibiligy. Renew markings as required to retain legibility. 3. Remove and discard the air breather. Air Breather Dipstick Suction Strainer ID5O0031 IA8O4097 9. a. Lift the mast and operate the tilt control lever, until the top surface of the forks is parallel with the floor. Place two straight bars that are the same width as the carriage, accross the forks as shown. 4. Install a new air breather. 9. b. Measure the distance from the bottom of each end of the two bars to the floor. The forks must be parallel within 3 mm (.12 in) for Full Tapered and Polished (FTP) forks, all other forks 6.4 mm (.25 in), for their completer length. 9. c. Put one fork, one third from the tip, under a fixture that will not move. Then operate the tilt control with caution until the rear of the truck lifts just off the floor. Follow the same procedure with the second fork. Repeat Step a. 5. Install the right side top cover. 6. Close the hood. - 129 - Maintenance Section Every 2500 Service Hours or 15 Months You must read and understand the warnings and instructions contained in the Safety section of this manual, before performing any operation or maintenance procedures. Hydraulic Oil & Strainer - Check, Change 3. Remove and discard the strainer. IA8O4049 1. Operate the lift truck a few minutes to warm the oil. Air Breather Park the lift truck level, with the forks lowered, parking brake engaged, directional lever in NEUTRAL and the key switch to OFF. Dipstick Suction Strainer ID5O0031 4. Install the new strainer by hand. IA8O4086 2. Remove the hydraulic tank drain plug. Allow the oil to drain. Clean and install the plug. 5. Remove the dipstick/filler cap assembly. 6. Fill the hydraulic tank. See topic, “Refill Capacities”. Install the dipstick /filler cap assembly. - 130 - Maintenance Section 7. Turn the key switch to ON and close the seat switch. Operate the hydraulic controls and steering system through a few cycles, to fill the filter and lines. 8. Check for oil leaks. 9. Retract all cylinders. 10. Turn the key switch to OFF. 11. Maintain the oil level to the FULL mark on the dipstick. Add oil if necessary. - 131 - Environment Protection Section Environment Protection When servicing this lift truck, use an authorized servicing area and an approved container to collect coolant, oil, fuel, grease, electrolyte and any other potential environmental pollutant before any lines, fittings or related items are disconnected or removed. After servicing, dispose of those materials in an authorized place and container. When cleaning the lift truck, be sure to use an authorized area. - 132 - Index Section Index A C About Environment Protection Section ............... 3 About General Section ........................................ 2 About Maintenance Section ................................ 3 About Operation Section ..................................... 3 About Safety Section .......................................... 2 About This Manual .............................................. 2 Accelerator Pedal .............................................. 47 After Storage ..................................................... 63 Air Breather - Change ..................................... 129 Apply Parking Brake Warning ........................... 13 Asbestos ........................................................... 15 Attachment Abbreviations (Includes Special Forks) ........................................................................... 39 Avoiding Lift Truck Tipovers .............................. 22 Capacity Chart ........................................... 33, 34 Capacity Chart - with side shifter ............... 35, 36 Capacity/Nameplate ......................................... 10 Carriage Roller Extrusion - Adjust .................... 96 Causes of Fork Failure ..................................... 67 Center of Gravity (CG) ..................................... 23 Chain and Linkage Oils (DEO or EO) .............. 73 Chassis Pivot Eyebolts - Lubricate ................. 114 Check Electrolyte ........................................... 104 Check for Equal Tension ................................ 124 Check Inflation Pressure (If equipped with pneumatic tires) .................. 106 Cold Storage Applications ................................ 79 Control Panel - Clean, Inspect ....................... 117 Crosshead Rollers - Inspect ........................... 115 Crushing or Cutting Prevention ........................ 15 Cylinder Rod Extension - Adjust .................... 114 B Back-up Alarm (If Equipped) - Test ................. 106 Battery ......................................................... 77, 79 Battery Access ................................................ 103 Battery Charging ............................................. 105 With Battery Installed in Lift Truck ........... 105 Battery - Check, Exchange, Charge ............... 103 Battery Discharge Indicator ............................... 76 Battery Discharge Indicator with Interrupt ......... 41 Battery Disconnect Before Servicing Warning ........................................................................... 13 Battery Exchanging ......................................... 104 Battery Restraint Warning ................................. 11 Before Operating the Lift Truck ................... 18, 50 Before Storage .................................................. 63 Bent or Twisted Forks ....................................... 67 Better Battery Performance .............................. 52 Brake Fluid ..........................................................75 Brake Oil Level - Check .................................. 110 Brushes - Check, Replace ................................ 97 Brush Seating ................................................... 97 B13/15/18/20T-2 (48V), B15/18/20T-2 (36V) ............................................................ 74, 75, 107 Automatic Transmission Fluid (ATF) .......... 74 B13/15/18T-2 (48V), B15/18/20T-2 (36V) Only ......................................................................... 119 B13/15/18/20T-2 (48V) Only ........................... 116 Burn Prevention ................................................ 16 Oils ............................................................. 16 Batteries ..................................................... 16 D Daily Inspection ................................................ 68 Diagnostic tests ............................................... 91 Directional Control Lever .................................. 47 Directional Lever - Check ............................... 118 Drive Axle Oil ................................................... 74 Drive Axle Oil - Change .................. 107, 116, 119 Drive Axle Oil Level - Check .......................... 111 Drive Motor - Clean, Inspect .......................... 119 Drive Wheels .................................................. 100 During Storage ................................................. 63 E Electrical Braking (Plugging) ............................ 55 Emergency Switch (If Equipped) ...................... 45 Environment Protection ................................. 132 Error Codes Erasing ......................................... 92 Every 10 Service Hours or Daily .................... 101 Every 250 Service Hours or Monthly .............. 110 Every 500 Service Hours or 3 Months ........... 114 Every 1000 Service Hours or 6 Months ......... 119 Every 2000 Service Hours or Yearly .............. 126 Every 2500 Service Hours or 15 Months ....... 130 - 133 - Index Section F Falling Objects Protective Structure (FOPS) Overhead Guard ............................................... 16 Fatigue .............................................................. 67 Fault Detection Circuit ....................................... 42 Film for Function of Pedals (If Equipped) .......... 47 Fire or Explosion Prevention ............................. 17 First 50 - 100 Service Hours or a Week .......... 107 First 250 Service Hours or a Month ................ 109 First Installation ................................................. 68 Fluid Penetration ............................................... 15 Foreword ............................................................. 2 Fork Inspection ................................................. 68 Forks - Inspect ................................................ 127 Forks Warning ................................................... 12 Formal Training ................................................... 7 Front and Rear Floodlights Switch .................... 44 Fuses - Replace ................................................ 99 G General Displaying Codes ................................ 95 General Hazard Information................................14 General Warnings to Operator .......................... 10 H Hand Placement Warning ................................. 12 Head Capacitor - Discharge .............................. 96 Hook-on type Fork ............................................ 62 Horn Button ....................................................... 45 Housekeeping ................................................... 15 How to Survive in a Tipover .............................. 27 Hydraulic Brake Fluid ........................................ 75 Hydraulic Oil ...................................................... 73 Hydraulic Oil & Strainer - Check, Change........ 130 Hydraulic Oil Level - Check ............................. 112 Hydraulic Pump Motor - Clean, Inspect .......... 122 Hydraulic Return Filter - Change ............. 109, 121 Hydraulic System .............................................. 79 and Safety .......................................................... 8 Inspection, Maintenance and Repair of Lift Truck Forks ................................................................ 66 Inspection Training ............................................. 7 K Key Switch ....................................................... 40 L Lift Chain Adjustment ..................................... 124 Carriage Chain Adjustment ..................... 125 Mast Chain Adjustment - FF,FFT Mast .. 125 Lift Chains .................................................. 15, 79 Lift Chains - Test, Check, Adjust .................... 124 Lift Chain Wear Test ...................................... 124 Lift Control Lever ........................................ 48, 87 Tilt Control Lever ....................................... 88 Auxiliary Control Lever .............................. 88 Parking Brake Lever .................................. 88 Accelerator Pedal ...................................... 89 Contactor Test Switch ............................... 89 Lift Fork Adjustment ......................................... 62 Lifting Drums or Round Objects ....................... 59 Lifting the Load ................................................. 56 Lift Truck Capacity Rating ................................ 38 Lift Truck Controls ............................................ 46 Lift Truck Operation .......................................... 53 Lift Truck Parking ............................................. 18 Lift Truck Stability ............................................. 22 Lift Truck Stability Base .................................... 24 Capacity Load (Weight and Load Center) . 24 Lift Trucks Temporarily Out Of Service ............ 14 Lines, Tubes and Hoses .................................. 17 Load Backrest Must Be In Place Warning ........ 12 Lubricate one fitting ........................................ 116 Lubricate two fittings ...................................... 116 Lubricant Information ....................................... 73 Lubricant Specifications ................................... 73 Lubricant Viscosities ........................................ 80 Lubricant Viscosities and Refill Capacities ....... 80 Lubricating Grease ........................................... 74 I Identification, Lift Capacity and Attachment Plate ........................................................................... 38 If Optional Suspension Seat Equipped ............. 20 Improper Modification or Repair ........................ 67 Inching into Loads ............................................. 56 Index ............................................................... 133 Indicator - Check ............................................. 105 Information Resources for Operation, Maintenance M Machine Lifting and Tiedown Information .......................................................................... 64 Maintaining a Safe Workplace ........................... 5 Maintaining the Machine to the Job ................... 6 Maintenance ..................................................... 15 Maintenance and Repair .................................. 69 - 134 - Index Section Maintenance Intervals ...................................3, 81 Maintenance Practices ........................................ 6 Mast Abbreviations ........................................... 38 Mast, Carriage, Lift Chains & Attachmemts Inspect, Lubricate ............................................ 113 Mast Channels - Lubricate .............................. 103 Mast Hinge Pins - Lubricate ............................ 116 Mast Pivot Eyes - Check, Lubricate ................ 114 Modifications ....................................................... 6 Monitoring Systems Indicator ............................ 41 Motor Brushes Wear Indicator .......................... 43 Mounting and Dismounting ............................... 18 Prepare for the Self - Diagnostic Test .............. Pressure Air ..................................................... Programmable or Settable Feature .................. Protective Clothing/Gear .................................. Protective Guards and Covers ......................... 83 15 93 14 15 R Recognition ........................................................ 7 Refill Capacities ............................................... 80 Reverse Direction Contactor (Right Side) ........ 89 Run Time Diagnostic ........................................ 41 N S Noise ................................................................. 32 Noise and Vibration ........................................... 32 No LCD Display ................................................. 42 Non Stored Error ............................................... 94 No Riders Warning ............................................ 12 No Standing On Forks Warning, No Standing Under Forks Warning.................................................... 14 O Operating Safety ............................................... 18 Operating Techniques ....................................... 56 Operator Responsibility ....................................... 5 Operator Restraint System (If Equipped) ...... 2, 19 Operator Safety Training ..................................... 7 Operator’s Station and Monitoring Systems ..... 40 Operator’s Warning and Identification Plate ..... 38 Operator’s Warning Plate .................................. 38 Overhead Guard - Inspect .............................. 116 Overhead Guard Must Be In Place Warning ..... 13 Overloading ....................................................... 67 Over Temperature ............................................. 43 Owner/Employer Responsibility .......................... 4 P Parking Brake Indicator ..................................... 44 Parking Brake Lever ......................................... 46 Parking Brake - Test ....................................... 111 Parking the Lift Truck ........................................ 60 Perform the self - Diagnostic Tests ................... 86 Logic Module Circuitry ............................... 86 Seat Switch ................................................ 86 Directional Control Lever ........................... 87 Possible Stored Error ........................................ 94 Power On Indicator ........................................... 42 Practical Training ................................................ 7 Safe Driving Practices ...................................... 24 Safe Operating Practices ................................... 9 Safety Information .............................................. 9 Safety Message for Owner and Operators ......... 4 Seat Adjustment ......................................... 20, 45 Seat Belt ........................................................... 21 Inspection .................................................. 21 Fasten the Seat Belt .................................. 22 Release the Seat Belt ............................... 22 Seat - Lubricate .............................................. 100 Seat Switch ...................................................... 40 Self-Diagnostics Indicator ................................ 43 Self Diagnostics - Test ..................................... 83 Serial Number .................................................. 37 Serial Numbers Locations ................................ 37 Service Brake Pedal ......................................... 46 Service Hour Meter .......................................... 44 Service Records Saving ................................... 92 Shipping ........................................................... 64 Sideshift Attachment Control (If Equipped) ...... 49 Specifications ................................................... 29 Stability and Center of Gravity ......................... 23 Static Return to Off ........................................... 42 Steering Mechanism - Lubricate .................... 116 Steer Wheel Bearings - Reassemble ............. 126 Steer Wheels .................................................. 100 Storage Information .......................................... 63 Stored error Codes ........................................... 92 T Table of Contents ............................................... 1 Tilt Control Lever .............................................. 48 Tilt Cylinders - Check, Adjust, Lubricate ........ 114 Tilt Steering Column ......................................... 45 Tire Inflation ..................................................... 70 Tire Inflation Information .................................. 70 - 135 - Index Section Tire Inflation Information ................................... 70 Tire Inflation Pressures Adjustment .................. 70 Tires and Wheels - Inspect ............................. 106 Tires and Wheels - Inspect, Check ................. 121 Tire Shipping Pressure ..................................... 70 Torque for Metric Fasteners .............................. 72 Torque for Standard Bolts, Nuts and Taperlock Studs ................................................................. 71 Torque for Standard Hose Clamps - Worm Drive Band Type ......................................................... 71 Torques for Bolts and Nuts With Standard Threads ........................................................................... 71 Torques for Taperlock Studs ............................. 72 Torque Specifications ....................................... 71 Towing Information ........................................... 65 Training Program Development .......................... 7 Training Required To Operate Or Service Warning ........................................................................... 11 Transportation Hints .......................................... 64 Traveling ........................................................... 57 Turning .............................................................. 57 12 Months Inspection ........................................ 69 U Unloading .......................................................... 58 V Vibration (weighted overall value) ..................... 32 W Walk-Around Inspection .................................... 50 Walk-Around Inspection - Inspect ................... 101 Warning Signal Options ...................................... 6 Warning Signs and Labels .......................... 10, 19 Wheel Bolts - Check ....................................... 112 When Required ................................................. 83 While Operating the Lift Truck .......................... 18 - 136 -