Design, Supply, Installation, Testing, Commissioning, Operation and
Transcription
Design, Supply, Installation, Testing, Commissioning, Operation and
Invitation To Bid (ITB) Tender No. ( xx / 2015) Design, Supply, Installation, Testing, Commissioning, Operation and Maintenance of Grid Connected Building Integrated Photovoltaic (BIPV) and Stirling Dish Systems at the Al-Balqa Applied University (BAU) Campus in Al-Salt and Al-Huson University College (HUC) Campus in Irbid Al-Balqa Applied University Al-Salt, Jordan Tel: (+962-5) 3491111 Fax: (+962-5) 3491111 P.O. Box: Al-Salt 19117, Jordan Page 1 of 54 Contents 1 Overview ............................................................................................................................................................... 4 1.1 1.2 1.3 Background ..................................................................................................................................................4 Scope of Work .............................................................................................................................................4 Design of Solar Systems .............................................................................................................................. 6 1.3.1 1.3.2 1.3.3 1.3.4 1.3.5 1.3.6 1.3.7 1.4 2 3 Design of Solar System No. 1 ..................................................................................................................6 Design of Solar System No. 2 ................................................................................................................ 11 Design of Solar System No. 3 ................................................................................................................ 13 Design of Solar System No. 4 ................................................................................................................ 17 Design of Solar System No. 5 ................................................................................................................ 21 Design of Solar System No. 6 ................................................................................................................ 23 Design of Solar System No. 7 ................................................................................................................ 28 BAU electrical system description ............................................................................................................. 32 Qualifications of Bidders ..................................................................................................................................... 32 General Terms and Conditions ............................................................................................................................ 34 3.1 3.2 3.3 Terms of reference ..................................................................................................................................... 34 Tender time plan ........................................................................................ 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Tender Bond ............................................................................................................................................... 39 3.3.1 3.3.2 3.3.3 4 Bid bond ................................................................................................................................................ 39 Performance guarantee bond.................................................................................................................. 39 Maintenance and Operational guarantee bond ....................................................................................... 40 General Requirements ......................................................................................................................................... 40 4.1 4.2 5 Technical requirements .............................................................................................................................. 40 Financial Requirements .............................................................................................................................. 43 Offer format ......................................................................................................................................................... 44 5.1 5.2 6 Technical offer ........................................................................................................................................... 44 Financial offer ............................................................................................................................................ 46 Component specification ..................................................................................................................................... 46 6.1 6.2 6.3 6.4 6.5 6.6 6.7 7 8 9 BIPV Modules............................................................................................................................................ 46 BIPV Mounting Structures ......................................................................................................................... 47 On- Grid Inverters ...................................................................................................................................... 47 PV / AC Cables and Conduits .................................................................................................................... 48 AC Distribution Boxes ............................................................................................................................... 48 Data logging and monitoring...................................................................................................................... 48 Solar Radiation and Temperature Sensor ................................................................................................... 49 Spare parts ........................................................................................................................................................... 49 Maintenance......................................................................................................................................................... 49 Training ............................................................................................................................................................... 50 9.1 9.2 10 11 12 13 13.1 Training scope ............................................................................................................................................ 50 Training requirements ................................................................................................................................ 50 Pre-Commissioning ........................................................................................................................................ 50 Commissioning and Testing Plan ................................................................................................................... 51 Final Acceptance ............................................................................................................................................ 51 Evaluation Criteria.......................................................................................................................................... 52 Evaluation Step 1: Qualifications and general requirements (15 points): .................................................. 52 Page 2 of 54 13.2 13.3 14 15 16 Evaluation Step 2: Technical evaluation (70 points):................................................................................. 52 Evaluation step 3: Financial evaluation (30 points): .................................................................................. 53 Method of Payment (Term of Payment) ......................................................................................................... 53 Additional Special Conditions ........................................................................................................................ 53 Annexes .......................................................................................................................................................... 54 List of Figures Figure 1: General view for Science Faculty building at Al-Salt campus .......................................................................6 Figure 2: Outside view of skylight on Science Faculty building at Al-Salt campus...................................................... 7 Figure 3: Inside view of skylight on Science Faculty building at Al-Salt campus ........................................................ 7 Figure 4: Place of Solar System No.1 – Location of skylight on Science Faculty building (Al-Salt) ........................... 8 Figure 5: Module layout for Solar System No. 1 ......................................................................................................... 10 Figure 6: Single Line Diagram for Solar System No. 1 ............................................................................................... 11 Figure 7: Place of Solar System No. 2 – Stirling Dish in front of Science Faculty building ....................................... 12 Figure 8: Stirling Dish System .................................................................................................................................... 13 Figure 9: General view for the southern facade of Finance building ........................................................................... 14 Figure 10: Place of Solar System No.3 – Location of southern facade of Finance building (Al-Salt) ........................ 14 Figure 11: General view for the southern façade of Finance building with BIPV modules ........................................ 15 Figure 12: Module Layout for Solar System No. 3 ..................................................................................................... 16 Figure 13: Single Line Diagram for Solar System No. 3 ............................................................................................. 16 Figure 14: General view for Carport Shield at Engineering Workshops Building at Al-Huson .................................. 17 Figure 15: Location map for Carport at Engineering Workshops Building at Al-Huson ............................................ 18 Figure 16: Module Layout for Solar System No. 4 ..................................................................................................... 20 Figure 17: Single Line Diagram for Solar System No. 4 ............................................................................................. 20 Figure 18: Place of Solar System No. 5 – Stirling Dish near the Engineering Workshops Building at Al-Huson ...... 21 Figure 19: Stirling Dish System .................................................................................................................................. 22 Figure 20: Location of Solar System No. 6 ................................................................................................................. 23 Figure 21: Place of 4 small solar pergolas located to the west of Bairooni building ................................................... 24 Figure 22: Module layout for Solar System No. 6 (Small Pergola) ............................................................................. 24 Figure 23: Single line diagram for Solar System No. 6 (Small Pergola) ..................................................................... 25 Figure 24: Place of the single Large Solar Pergola located to the south of Bairooni building .................................... 26 Figure 25: Module layout for Solar System No. 6 (Large Pergola) ............................................................................. 27 Figure 26: Single line diagram for Solar System No. 6 (Large Pergola) ..................................................................... 27 Figure 27: General view of Main building at Al-Huson Campus ................................................................................ 28 Figure 28: Place of Solar System No.7 – Location of southern facade of Main building (Al-Huson) ........................ 29 Figure 29: General view for the southern façade of Main building with BIPV modules ............................................ 30 Figure 30: Module Layout for Solar System No. 7 ..................................................................................................... 31 Figure 31: Single Line Diagram for Solar System No. 7 ............................................................................................. 31 List of Tables Table 1: Place, type and nominal capacity for all solar systems ....................................................................................4 Table 2: Tender time plan .......................................................................................................................................... 39 Table 3: Technical evaluation criteria ....................................................................................................................... 52 Page 3 of 54 1 Overview 1.1 Background This ITB is launched as a deliverable for DIDSOLIT-PB project www.didsolit.eu which is funded by the European Union through ENPI-CBCMED’s Program. The project focuses on the development and implementation of decentralized solar energy-related innovative technologies for public buildings in the Mediterranean Basin countries. Al-Balqa Applied University (BAU) is a partner in the DIDSOLIT project out of the belief in the importance of the solar power for Jordan in terms of reducing energy bills and the growing demand for the technology in the country. 1.2 Scope of Work BAU is launching this bid in order to contract a qualified company to develop, permit, engineer, design, procure, construct, interconnect, deliver, start-up, test, commission, operate and maintain (5) five turnkey Building Integrated Photovoltaic (BIPV) systems and (2) two ground-mounted Stirling Dish systems which are divided as illustrated in Table 1 shown below between BAU campus at Al-Salt city (25 km to the west of Amman city) and Al-Huson University College (HUC) campus at Al-Huson town (10 km to the south of Irbid city). All the PV modules that will be purchased through this ITB are non-traditional modules; they are called Building Integrated PV (BIPV) modules as they are integrated within the building, so they serve a dual function as building materials and power generators. Table 1: Place, type and nominal capacity for all solar systems System Campus No. 1 BAU 2 BAU Place of Installation Science Faculty Building The hill located in front of the Science Faculty Building Type of Installation Building Integrated PV (BIPV) modules will be utilized to cover the main skylight of the building Ground-mounted Stirling dish will be utilized to generate both Nominal Power Capacity 18.18 kWp1 4 kWp (3 kWth + 1 kWe) Page 4 of 54 electricity & thermal energy 1 2 3 BAU Finance Building 4 HUC Engineering Workshops Building 5 HUC Land area located west of Engineering Workshops Building 6 HUC Bairooni Building 7 HUC Main Building BIPV modules will be utilized as sunshields for windows located at the southern façade of the building BIPV modules are used to cover the top surface of a metallic corrugated sheet carport shield. Ground-mounted Stirling dish will be utilized to generate both electricity & thermal energy BIPV modules will be utilized to construct the roofs of 5 pergolas (4 west small pergolas and 1 south large pergola) BIPV modules will be utilized as sunshields for windows located at the southern façade of the building 24.24 kWp1 3.264 kWp2 4 kWp (3 kWth + 1 kWe) 20.2 kWp1 8.08 kWp1 based on a BIPV module rated at STC of 202 Wp semi-transparent crystalline silicon based on a BIPV module rated at STC of 136 Wp flexible amorphous silicon The designs of the solar systems are based on standard BIPV modules as shown in Table 1, but it is technically possible to achieve the same characteristic of the PV generator with smaller or larger modules and different layouts. The bidders can propose other module capacities for approval as long as the total PV generator capacities listed in Table 1 are met and each string has not more than the modules in series so that the Voc of the Page 5 of 54 generator is within the specifications and fit with the selected grid-dependent inverter operating voltage range. Bidders for this tender shall propose Engineering, Procurement & Construction (EPC) offer with separate technical and financial offers and the proposed systems shall comply with the relevant laws and regulations issued by the Ministry of Energy & Mineral Resources (MEMR), Energy & Minerals Regulatory Commission (EMRC) and should be in line with the requirements of the distribution companies in Jordan. 1.3 Design of Solar Systems Three solar systems out of seven will be installed within the campus of BAU at Al-Salt while the remaining four solar systems will be installed within the campus of BAU at AlHuson. 1.3.1 Design of Solar System No. 1 Solar System No. 1 will be installed on the Science Faculty building shown in Figure 1 which is located within the campus of BAU at Al-Salt city. The building has a curvilinear skylight as illustrated in Figures 2 & 3 with approximate base dimensions of 17 x 13 meters. This skylight will be integrated with BIPV modules. Figure 1: General view for Science Faculty building at Al-Salt campus Page 6 of 54 Skylight Figure 2: Outside view of skylight on Science Faculty building at Al-Salt campus Figure 3: Inside view of skylight on Science Faculty building at Al-Salt campus The Google Earth Map shown below in Figure 4 illustrates the location of the Science Faculty building within Al-Salt campus. The site coordinates are: 32°01'24.57" N & 35°43'08.38" E. Page 7 of 54 Skylight Science Faculty Building South Figure 4: Place of Solar System No.1 – Location of skylight on Science Faculty building (Al-Salt) For this BIPV installation, it is the responsibility of the bidder to remove of the PVC roofing sheets mounted on the existing steel structure as well as to reengineer the existing steel structure to convert it from its current curvilinear shape to a tilted shape (Tilt angle = 10° south facing) in order to accommodate BIPV modules and their corresponding mounting devices. The bidder should guarantee that this BIPV installation will protect the building against water leakages in case of raining or cleaning using water. Daylight utilization should be guaranteed, too. Semi-transparent glass-laminated crystalline silicon BIPV modules should be utilized in this solar system. Solar System No. 1 is designed as illustrated in the module layout shown in Figure 5 and the electrical single line diagram shown in Figure 6 based on the following BIPV module: Semi-transparent glass-laminated 200-220Wp at Standard Test Conditions Nominal power: (STC) which are: solar irradiance = 1000 W/m2, cell temperature = 25 ºC and solar spectrum or air mass = 1.5. +/- 5% Power tolerance Nominal Open Circuit Voltage, Approx. 32.0-35.0 V @ STC Voc Page 8 of 54 Nominal Short Circuit Current, Isc Nominal Voltage at Maximum Power Point, Vmp Nominal Current at Maximum Power Point, Imp Maximum system voltage: Electrical protection class Type of PV cells Technology: Size in mm Total thickness Weight approx. Transparency approx. Power/m2 Module Structure Approx.8.0-8.3 A @ STC Approx. 26.5-28.5 V @ STC Approx. 7.0-8.0 A @ STC 1000 V Class II poly-crystalline, 156x156 mm Semi-transparent glass-laminated L (1800-1835) x W (1190-1200) 11-12 mm 60 kg not less than 25-38% 100-110 Wp Should stand wind speeds up to 160km/hr, atmospheric pressure up to 106.7 K Pa, and maximum temperature of 75 degree Celsius, and humidity 100%with rain fall up to 5 mm/minute and any other forces may exist. : Around 90 BIPV modules (202 Wp/module) will be utilized and divided into 5 strings with 18 modules connected in series per string (Required total peal power should be around 18 kWp). The five strings are connected in parallel inside a grid-connected inverter with a nominal rated power of 20 kW. Regarding the AC connection point, it is the responsibility of the bidder to select the proper MDB/SMDB within the building to connect with according to the requirements of the utility operator. Page 9 of 54 Figure 5: Module layout for Solar System No. 1 Page 10 of 54 Figure 6: Single Line Diagram for Solar System No. 1 1.3.2 Design of Solar System No. 2 Solar System No. 2 will be a ground-mounted Stirling Dish system able to generate both electrical and thermal energies. The Stirling Dish will be placed on the hill which is located in front of the Science Faculty building in the campus of BAU at Al-Salt city as shown in Figure 7. Page 11 of 54 Science Faculty Building South Stirling Dish Figure 7: Place of Solar System No. 2 – Stirling Dish in front of Science Faculty building The Stirling Dish is a solar concentration system which is able to cogenerate electricity and thermal energy. It is a concentrator having a parabolic shape that uses the solar thermal heat to warm up the hot focus of a Stirling engine, which is integrated in the same structure, to pump a piston and generate electricity. The thermal energy extracted from the cold focus, cooled down with a mixture of water and propylene glycol, is the useful thermal energy produced. This installation should be capable of producing 1 kWe and 3 kWt. The global efficiency of solar energy conversion in thermal and electric energy should be between 53-56%, composed of a 13-14%% electric and 40-42% thermal. As can be seen in Figure 8, the system is composed of the structure with the solar concentrator and the Stirling engine and the auxiliary systems. These auxiliary systems are the electric and electronic control of the Stirling Dish, the hydraulic control, the safety cooling system, the expansion tank, a pump, the solar tank and the control board to connect to the electrical grid. Note that the parts marked in red are not included in the commercial product, so they must be dimensioned. Most, of the parts of system are to be installed outdoor, except the solar tank and control board. An extra pump will be needed if the considered pipe is longer than 20 m. Page 12 of 54 Figure 8: Stirling Dish System To be able to install this cogeneration system, the land must have an area of free space of around 7x7m. It also needs a metallic net to secure the area and a small room, to install the hydraulic and electric auxiliary systems. A hot water consumption rate above 3 kWt should be available at site, which is about 86 Liters of 30 ºC warmed water each hour of nominal use of the system. It will also need to have a single phase connection of 4 mm2 of section, which has the capacity to accept 1 kW of power. The bidder should provide all the technical datasheets about the Stirling Dish system, in addition the installation guide of the system starting from the construction and building of the concrete foundation and ending with the thermal and electrical connection points. 1.3.3 Design of Solar System No. 3 Solar System No. 3 will be installed as sun-shields for the windows located on the southern façade of the Finance building shown in Figure 7 which is located within the campus of BAU at Al-Salt city. Page 13 of 54 Figure 9: General view for the southern facade of Finance building The Google Earth Map shown below in Figure 8 illustrates the location of the Finance building within located Al-Salt campus. The site coordinates are: 32°01'24.57" N & 35°43'08.38" E. Finance Building South-East Facade s Figure 10: Place of Solar System No.3 – Location of southern facade of Finance building (Al-Salt) Semi-transparent glass-laminated crystalline silicon BIPV modules will be utilized as sun-shields for façade windows as illustrated in Figure 9 shown below. A BIPV semitransparent crystalline silicon module rated at STC of 202 Wp (same module Page 14 of 54 characteristics utilized in Solar System No. 1) is selected to design this solar system as illustrated in the module layout shown in Figure 10 and the electrical single line diagram shown in Figure 11. Figure 11: General view for the southern façade of Finance building with BIPV modules Page 15 of 54 Figure 12: Module Layout for Solar System No. 3 Figure 13: Single Line Diagram for Solar System No. 3 120 BIPV modules (202 Wp/module) are being utilized and divided into 5 strings with 24 modules connected in series per string (Required total peal power should be not less than 24.24 kWp). The five strings are connected in parallel inside a grid-connected inverter with a nominal rated power of 25 kW. Page 16 of 54 Regarding the AC connection point, it is the responsibility of the bidder to select the proper MDB/SMDB within the building to connect with. 1.3.4 Design of Solar System No. 4 Solar System No. 4 will be installed to cover the top surface of a metallic corrugated sheet carport shield located in front of the Engineering Workshops building as shown in Figure 12 which is located within the campus of BAU at Al-Huson town. Figure 14: General view for Carport Shield at Engineering Workshops Building at Al-Huson The Google Earth Map shown below located at coordinates (32°29'11.86" N & 35°53'30.76" E) illustrates the location of the Engineering Workshop Building at the campus of BAU at Huson town near Irbid city) where our aimed solar installations will be placed. Page 17 of 54 Engineering Workshops Carport s Figure 15: Location map for Carport at Engineering Workshops Building at Al-Huson Flexible amorphous silicon BIPV modules will be utilized. A BIPV flexible amorphous silicon module rated at STC of 136 is selected to design this solar system as illustrated in the module layout shown in Figure 10 and the electrical single line diagram shown in Figure 11. The solar system is designed as illustrated in the module layout shown in Figure 16 and the electrical single line diagram shown in Figure 17 based on the following BIPV module: Flexible sheet with polymer laminate Approx. 133-137 Wp at Standard Test Nominal power: Conditions (STC) which are: solar irradiance = 1000 W/m2, cell temperature = 25 ºC and solar spectrum or air mass = 1.5. +/- 5% Power tolerance Nominal Open Circuit Voltage, Approx. 45.5-46.5 V @ STC Voc Nominal Short Circuit Approx. 5.0-5.3 A @ STC Current, Isc Nominal Voltage at Maximum Approx. 32.0-33.0 V @ STC Power Point, Vmp Nominal Current at Maximum Approx. 4.0-4.2 A @ STC Power Point, Imp Maximum system voltage: 600 V Page 18 of 54 Electrical protection class Type of PV cells Technology: Class II triple junction amorphous silicon flexible sheet with polymer laminate Size in mm Total thickness Weight approx. Power/m2 Module Structure L(5400-5500) x W (375-400) 4-5 mm 7.5-8.0 kg 60-65 W/m2 Should stand wind speeds up to 160km/hr, atmospheric pressure up to 106.7 K Pa, and maximum temperature of 75 degree Celsius, and humidity 100%with rain fall up to 5 mm/minute and any other forces may exist : 24 BIPV modules (136 Wp/module) are being utilized and divided into 3 strings with 8 modules connected in series per string (Required total peal power should be not less than 3.264 kWp). The five strings are connected in parallel inside a grid-connected inverter with a nominal rated power of 3 kW. Regarding the AC connection point, it is the responsibility of the bidder to select the proper MDB/SMDB within the building to connect with. Page 19 of 54 Figure 16: Module Layout for Solar System No. 4 Figure 17: Single Line Diagram for Solar System No. 4 Page 20 of 54 1.3.5 Design of Solar System No. 5 Solar System No. 5 (similar to Solar System No. 2) will be a ground-mounted Stirling Dish system able to generate both electrical and thermal energies. The Stirling Dish will be placed in the garden of the Engineering Workshops building in the campus of AlHuson as shown in Figure 18. Stirling Dish Engineering Workshops s Figure 18: Place of Solar System No. 5 – Stirling Dish near the Engineering Workshops Building at Al-Huson The Stirling Dish is a solar concentration system which is able to cogenerate electricity and thermal energy. It is a concentrator having a parabolic shape that uses the solar thermal heat to warm up the hot focus of a Stirling engine, which is integrated in the same structure, to pump a piston and generate electricity. The thermal energy extracted from the cold focus, cooled down with a mixture of water and propylene glycol, is the useful thermal energy produced. This installation should be capable of producing 1 kWe and 3 kWt. The global efficiency of solar energy conversion in thermal and electric energy should be between 53-56%, composed of a 13-14%% electric and 40-42% thermal. As can be seen in Figure 8, the system is composed of the structure with the solar concentrator and the Stirling engine and the auxiliary systems. These auxiliary systems are the electric and electronic control of the Stirling Dish, the hydraulic control, the safety cooling system, the expansion tank, a pump, the solar tank and the control board to connect to the electrical grid. Note that the parts marked in red are not included in the commercial product, so they must be dimensioned. Most, of the parts of system are to be Page 21 of 54 installed outdoor, except the solar tank and control board. An extra pump will be needed if the considered pipe is longer than 20 m. Figure 19: Stirling Dish System To be able to install this cogeneration system, the land must have an area of free space of around 7x7m. It also needs a metallic net to secure the area and a small room, to install the hydraulic and electric auxiliary systems. A hot water consumption rate above 3 kWt should be available at site, which is about 86 Liters of 30 ºC warmed water each hour of nominal use of the system. It will also need to have a single phase connection of 4 mm2 of section, which has the capacity to accept 1 kW of power. The bidder should provide all the technical datasheets about the Stirling Dish system, in addition the installation guide of the system starting from the construction and building of the concrete foundation and ending with the thermal and electrical connection points. Page 22 of 54 1.3.6 Design of Solar System No. 6 Solar System No. 6 will be installed to construct the roofs of 5 pergolas (4 west small pergolas +1 south large pergola) located at the west and south sides of Bairooni building located as shown in Figure 16 which is located within the campus of BAU at Al-Huson town. Small Pergola 0 Bairooni Building s Large Pergola Figure 20: Location of Solar System No. 6 Semi-transparent glass-laminated crystalline silicon BIPV modules will be utilized to construct the roofs of the four small pergolas as illustrated in Figure 17 shown below. A BIPV semi-transparent crystalline silicon module rated at STC of 202 Wp (same module characteristics utilized in Solar System No. 1 and No. 3) is selected to design this solar system as illustrated in the module layout shown in Figure 18 and the electrical single line diagram shown in Figure 19. Page 23 of 54 Figure 21: Place of 4 small solar pergolas located to the west of Bairooni building Figure 22: Module layout for Solar System No. 6 (Small Pergola) Page 24 of 54 Figure 23: Single line diagram for Solar System No. 6 (Small Pergola) 10 BIPV modules (202 Wp/module) are being utilized for each small pergola and connected in series (Required total peal power should be not less than 2.02 kWp). The single string is connected with a grid-connected inverter with a nominal rated power of 2 kW. Regarding the AC connection point, it is the responsibility of the bidder to select the proper MDB/SMDB within the building to connect with. For the single large pergola, the same kind of BIPV modules of the small pergolas will be utilized to construct the roof of the single large pergola as illustrated in Figure 20 shown below. The module layout is shown in Figure 21 and the electrical single line diagram is shown in Figure 22. Page 25 of 54 Figure 24: Place of the single Large Solar Pergola located to the south of Bairooni building Page 26 of 54 Figure 25: Module layout for Solar System No. 6 (Large Pergola) Figure 26: Single line diagram for Solar System No. 6 (Large Pergola) Page 27 of 54 60 BIPV modules (202 Wp/module) are being utilized and divided into 3 strings with 20 modules connected in series per string (Required total peal power should be not less than 12.12 kWp). The three strings are connected in parallel inside a grid-connected inverter with a nominal rated power of 12.5 kW. Regarding the AC connection point, it is the responsibility of the bidder to select the proper MDB/SMDB within the building to connect with. The total number of BIPV modules utilized for the five pergolas is 100 with a total peak power size of 20.2 kWp which should be met by the bidders. 1.3.7 Design of Solar System No. 7 Solar System No. 7 will be installed as sun-shields for the windows located on the southern façade of the Main building shown in Figure 7 which is located within the campus of BAU at Al-Huson town. Figure 27: General view of Main building at Al-Huson Campus Page 28 of 54 The Google Earth Map shown below in Figure 24 illustrates the location of the Main Faculty building within located Al-Huson campus. The site coordinates are: 32°29'15.24" N & 35°53'24.87" E. Main Building s South Façade Figure 28: Place of Solar System No.7 – Location of southern facade of Main building (Al-Huson) Semi-transparent glass-laminated crystalline silicon BIPV modules will be utilized as sun-shields for façade windows as illustrated in Figure 25 shown below. A BIPV semitransparent crystalline silicon module rated at STC of 202 Wp (same module characteristics utilized in Solar Systems No. 1, No. 3 & No. 6) is selected to design this solar system as illustrated in the module layout shown in Figure 26 and the electrical single line diagram shown in Figure 27. Page 29 of 54 Figure 29: General view for the southern façade of Main building with BIPV modules Page 30 of 54 Figure 30: Module Layout for Solar System No. 7 Figure 31: Single Line Diagram for Solar System No. 7 120 BIPV modules (202 Wp/module) are being utilized and divided into 5 strings with 24 modules connected in series per string (Required total peal power should be not less than 24.24 kWp). The five strings are connected in parallel inside a grid-connected inverter with a nominal rated power of 25 kW. Page 31 of 54 Regarding the AC connection point, it is the responsibility of the bidder to select the proper MDB/SMDB within the building to connect with. 1.4 BAU electrical system description BAU campus in Al-Salt is served by JEPCO electricity distributor while HUC campus in Al-Huson is served by IDECO electricity distributor. The annual electricity consumption in Al-Salt’s site is around 1,500,000 kWh/year, while the consumption at Al-Huson’s site is around 500,000 kWh/year. It is the bidder’s responsibility to study well the existing electrical systems in each site and select the proper electrical connection point(s) taking into account the MDB/SMDB compatibility and distributor’s requirements. 2 Qualifications of Bidders Companies wishing to propose shall ensure that they satisfy the following criteria and provide all of the below mentioned documents: The Jordanian company must be a registered manufacturing company, firm or corporation in Jordan Ministry of Industry and Trade in the field of renewable energy project, solar system integration, solar system electronics or any PV related technologies. Offers submitted by companies that have a joint venture agreement shall fulfil the following requirements. o The Jordanian partner must be appointed as the Lead partner, and this appointment confirmed by submission of powers of attorney signed by legally empowered signatories representing all the individual partners. o The offer must include a sealed and stamped joint venture agreement registered at the Ministry of Industry and Trade (MIT) and several liability for the execution of the contract, the lead partner is authorized to bind, and receive instructions for and on behalf of, all partners, individually and collectively. o All partners in the joint venture are bound to remain in the joint venture. The joint venture winning this contract must include the Page 32 of 54 same partners for the whole performance period of the contract other than as may be permitted or required by law. o In case of termination of the joint venture agreement during the project implementation period, the lead partner will incur the penalties of liquidating the timely available bond in addition to the loss value estimated by BAU legal parties. The bidder shall nominate a technical team to perform the design, installation and all supporting tasks. The team shall include at least: o A qualified project manager and a site engineer, who should have at least a B.Sc. in electrical engineering, mechanical engineering, or any related specialty with a minimum experience of 3 years in PV system projects. o A civil engineer held responsible for managing all structural and civil works on-site with at least a B.Sc. in civil engineering. o An experienced trainer. The bidder shall provide a description of the capabilities and experience of the proposed team and resumes of all key project personnel. Resumes shall include years with the firm, years in the solar industry, project experience similar to that proposed. The bidder shall provide a list of similar executed PV projects (design, installation and maintenance) including brief descriptions. The bidder must inform BAU of any subcontractor in advance, and BAU has the right to accept or reject the subcontractor. A bidder who has been convicted of legal misconduct may be excluded from the awarding of contracts. A bidder who is found guilty of making false declarations will be subject to financial penalties representing 10% of the total value of the contract being awarded. Page 33 of 54 3 General Terms and Conditions 3.1 Terms of reference All proposed documents are considered confidential and can only be shared with the BAU. The bid is open on equal terms to all local and international companies. Local bidders are allowed to coordinate with international companies and subcontractors upon Joint venture agreements (consortiums specifically for this project are allowed), knowing that the local company must be the project leader. The Bidder shall submit two Original hard and soft copies (CDs) with two separate envelopes one envelope for the technical offer sealed and stamped, and the other for the financial offer sealed and stamped, and inserted both envelops in one envelope as one document sealed and stamped. Any bidder who submits the technical and financial offers separately will be directly disqualified. The offers shall be delivered to the BAU physical address by hand. The bidder shall then submit both reports financial and technical offers in one envelop The bidder must fill the technical compliance sheet and submit it in the technical offer, knowing that not completing and submitting the technical compliance sheet will directly disqualify the offer. [Annex 1: Technical compliance sheet] This project is exempted from VAT and their exemption letter will be available upon request for the winning bidder. The bidder shall propose an EPC offer for the seven solar systems described above. The bidder shall respect the BAU safety, security and general regulations and to be highly cooperative with the BAU staff. All bidders must provide design simulations for the solar systems using PVSyst or similar. The bidder shall apply Jordanian “labour law” that includes the use of underage labour, non-resident or unlicensed labourers. Page 34 of 54 The validity of the offer shall be 90 days. All prices shall be clear and in Jordanian Dinar (JOD) currency, excluding any additional VAT. The bidder is open for any requested clarifications during the offers evaluation phase, considering that the offer price shall not be changed. The bidder is responsible to pay the tender award fees according to BAU regulations. BAU is not committed to award to the lowest price. The proposed solar systems shall comply with the laws and regulations of the Ministry of Energy and Mineral resources (MEMR), Energy and Minerals Regulatory Commission (EMRC), Jordan Electricity Power Company (JEPCO) in BAU campus and Irbid Electricity (IDECO) in HUC campus as well as the National building and National electrical wiring codes. The bidders shall consider in their electrical design the Industry Standards, the National Electric Code, IEEE 1547-2003 “IEEE Standard for Interconnecting Distributed Resources with Electric Power Systems.” and other applicable codes and standards. It is the bidder’s responsibility to understand the site conditions, environment and all requirements related to the tender that may affect the offer price. The bidder will be fully responsible for verifying any information, drawings and measurements provided in the tender offer. A site visit will be performed for all Bidders and assigned in the time plan (Table 2). The site visit will include an explanatory presentation that aims to provide the bidder with a full picture of the site characteristics, and in order to identify the AC connection points for the building and estimate accurately the cabling and conduits requirements. All questions regarding the tender by the bidder shall be submitted by email to the following address: (didsolit@bau.edu.jo) for international bidders only and by fax no. 00962-5-3530037 for local bidders. Once answered, will be circulated among all contractors who have already purchased the tender. The deadline of the questions and the answers is shown in (Table 2). No question will be considered after the mentioned date. Page 35 of 54 The tender will be awarded as one lot or more for the most suitable technical and financial offer/offers to BAU and based on the evaluation criteria explained in (Section 13). Knowing that one full system can be considered as a lot. For equipment and vehicles with a unit cost on purchase of more than €5,000, the contractors providing the supplies must present proof of origin no later than when they present their first invoice. The certificate of origin must be made out by the competent authorities in the country of origin for the supplies (e.g. Chamber of Commerce, Government Ministry etc.). Remember to request this certificate from your supplier and clearly insert it as a requirement in the tender dossier. For supplies with a unit cost on purchase of less than €5,000, a statement from your supplier specifying the origin of the equipment is enough. Still, remember that the rule of origin applies to all supplies so in the absence of this statement, the cost of the supplies is considered ineligible. Note, the origin is also often inscribed on the equipment itself (e.g. ‘made in’ or ‘assembled in’ or can be demonstrated via the annexed instruction. It is the Bidder’s responsibility to provide at no additional costs all additional items required during the installation period that were not previously stated in the offer. However, any omission of any part of the bill of quantity (BOQ) shall be deducted from the price. The origin of equipment should be clearly defined taking in account that it must be EU origin any offer failed to submit certification of EU origin will be illegible All permits required to execute the work are the responsibility of the contractor (winning bidder). The contractor shall identify known permit requirements. The cost of preparing, filing and obtaining the permits shall be included in the contract price. The contractor shall provide BAU copies of all approved permits and applications for permits still in process on the effective date of the contract. The financial offer shall not include the cost of the grid impact study. However, it is the responsibility of the bidder to submit all the data required from JEPCO and IDECO. The contractor shall provide a free maintenance period for three (3) years from the date of the installed system final acceptance including parts, maintenance costs, replacement cost and all other costs. Page 36 of 54 An inspection report of the system performance and check-up shall be provided every six months during the free maintenance period of 3 years. The bidder shall include a site plan indicating all civil requirements and permits required by the applicable national laws and regulations. The electrical design shall include the appropriate sizing of all cabling works and all protection equipment (above and below ground) that will connect the modules, arrays, inverters, and to the point of interconnection. All monitoring and communication equipment and cabling shall be designed and specified clearly. It is the contractor’s responsibility to execute the work and identify the required permits at his own expenses. The expenses shall be included in the contract Price. All permits shall be provided as hard and soft copies to BAU. The contractor shall provide a bi-weekly report covering the progress achieved in the previous two weeks and the planned activities for the upcoming weeks. The report shall cover Engineering, Permitting, Procurement, Safety and Implementation activities. The contractor shall also provide a progress versus planned report, the reports shall outline areas of concern and plans for corrective action (if needed) to maintain the project schedule. It is the contractor’s responsibility to procure all equipment and materials and it shall be known that the cost of the equipment and materials, including the risk of any variation in the price, is included in the final contract price. The contractor or its hired subcontractor shall provide all temporary equipment and materials needed for project execution and shall respect the national labour law. The contractor shall provide a Quality Assurance/Quality Control (QA/QC) plan for the implementation activities to be applied. The contractor shall respect implementation guidelines in addition to work ethics and noise levels. The QA/QC plan must be approved by BAU. The contractor shall provide and confirm a complete Health and Safety Plan (HASP) and must be approved by BAU. Page 37 of 54 The contractor shall keep the site clean; all trash and rubbish shall be disposed of off-site by a licensed waste disposal company in accordance with the applicable laws. Any location of works shall be returned to its original state after work is done. The contractor shall be responsible for storing all system equipment. The contractor shall provide permanent equipment marking, labelling and signage for the project. Warning signs shall be placed at key areas near equipment, at project entrances and any other relevant place selected by BAU. The contractor shall provide all as-built drawings prior the final acceptance of the system. The contractor shall submit two original hardcopies and two softcopies of the final project report including but not limited to all permits, as-built engineering and 3D drawings, certification, Instruction Manual as well as Installation, Operation and Maintenance Manuals, safety plan and monitoring and software system. The report shall be provided after JEPCO (Al-Salt) and IDECO (Al-Huson) commissioning, and shall be approved by BAU. If the contractor fails on the implementation of the tender, which was transmitted by partially or totally that violates any provision of the contract entitled, BAU is to take action against the bidder according to the effective rules and regulations in BAU for tenders. All bidders shall bear that final date for the project will 6 months after signing the contract A full response to this TOR is required by bidder. The following timescales are anticipated: Page 38 of 54 Table 2: Tender time plan Milestone Release of tender Purchase Deadline Site Visit Deadline for questions Release of answers to questions Deadline for offers Date 22 March 2015 22 April, 2015 One week after announcement first day for Salt and second day for AlHuson 7 Days after Al-Huson visit Three days after deadline for questions 22 April 2015 Time Salt 9:00-12:00 Al-Huson 11:00-14:00 3.2 Tender Bond 3.2.1 Bid bond An irrevocable bid bond of 5% of the total amount of the bid shall be enclosed in the financial offer envelope. The bid bond shall be issued by a local bank and approved by the BAU. The winning bidder shall consider that this amount will be paid on first demand if it becomes evident that information given contains false statements. The validity of the bid bond is 90 days from date of offers submission with the ability to be automatically renewed unless released by BAU. The bid bond will be returned after signing the agreement, and the performance bond has been duly entered into execution. If the winning bidder fails to provide a performance bond within 14 days of being requested to do so by the BAU; the full amount of tender bond shall become payable and may be liquidated by BAU as compensation for such failure. 3.2.2 Performance guarantee bond Page 39 of 54 Performance guarantee bond of 10% of the contract price shall be delivered by the awarded Contractor within 14 days of being notified by a registered letter that he has been awarded the contract and in any case prior to signing the contract agreement and the awarding decision. The performances guarantee bond shall be issued from a local bank and approved by the BAU in respect of performance of the contract and will be released upon receiving the maintenance bond. If the bidder fails to complete any requested works or/and any deficit in the signed contract the penalty according to the effective tender and financial regulations in BAU will be applied without any need for noticed or legal action. 3.2.3 Maintenance and Operational guarantee bond A maintenance and operational guarantee bond of 10% of the contract shall be submitted by the contractor to BAU prior the final commissioning and system acceptance; it shall be issued from a local bank and accepted by BAU. The bond guarantees the three (3) years of free maintenance and will be released after submitting the final inspection report of the solar systems and after the successful achievement of the proposed energy yield and performance ratio values during the bond period. The contractor shall, at his own expense, repair or modify any of the installed solar systems upon failure of achieving the proposed values within the bond period. In case of not repairing the failure, the maintenance and operational bond will be liquidated in addition to the loss value incurred by BAU. 4 General Requirements 4.1 Technical requirements The bidder must fill the technical compliance sheet and submit it in the technical offer, knowing that not completing and submitting the technical compliance sheet will directly disqualify the offer. [Annex 1: Technical compliance sheet] Page 40 of 54 All bidders must use a solar simulation software like PVSyst or similar to provide all design simulations for the solar systems. The proposal documents shall include at minimum the followings: o General specifications. o Special specifications. o Bill of quantities. o Drawings including BIPV modules layout and single line diagram. o Design calculations. o List of codes and standards concerning the equipment. o Equipment manufacturers and country of origin. The bidder shall include at minimum but not limited to the specifications of the following equipment and materials: o BIPV modules o Inverters o PV cable o AC cable o Circuit breakers, Residual Current Devices (RCD) and Surging devices. o IP65 Junction Boxes (if applicable) o Mounting Structure o Solar Radiation and Temperature measurement Devices o Data logging and monitoring system o Stirling Dish Components The Bidder shall consider in the BIPV system layout service passages to enable the ease of maintenance and system cleaning. The bidder shall submit a detailed design for the solar systems. The proposed PV system components shall have manufacturer warranties as follows: o 10 years for metallic part of PV module o 10 years at least for the inverters o 10 Years for the DC and AC cables o 10 years for mounting structure o 5 years for data loggers and sensors. The Contractor's design shall be in full compliance with the requirements of Ministry of Public Work and Housing, Civil Defence Directorate and Energy and Minerals Regulatory Commission (EMRC). Page 41 of 54 The Bidder shall provide an estimate of the yearly generated electricity and the expected performance ratio (PR) for the first, second and third years. The PV system design shall guarantee that the proposed Performance Ratio (PR) shall not be less than the proposed values for the first, second and third years of system operation. The inverter(s) shall comply with the EMRC, JEPCO & IDECO regulations and standards. The mounting structure of PV shall withstand a wind speed of 160km/hour as well as other weather conditions. The engineering and design shall include the appropriate sizing of all cabling (above and below ground), that will connect the modules, arrays and inverters to the point of interconnection. The above ground portion of the electrical systems shall be neatly routed to facilitate access, troubleshooting, maintenance …etc. The electrical design shall include the appropriate sizing of all cabling works and all protection equipment (above and below ground) that will connect the modules, arrays, inverters, and to the point of interconnection. All protection equipment throughout the system shall be sized and specified to reduce damage on all components and the interconnection point in case of an electrical failure (e.g. Surge current, over voltage and intermittency protections). The location of the BIPV modules, inverters and cable routes as well as Stirling dish components should be included in the site layout drawing provided in the offer by the bidder for each system. The bidder shall provide a data logging and monitoring system for each solar system with the ability to generate a monthly report. The contractor shall provide as built and site layout drawings before commissioning. The bidder shall submit a spare part list including 2% of all proposed material. Page 42 of 54 All works carried-out by the contractor shall be maintained for free for three years starting from the date of final acceptance, the maintenance cost shall be included in the offer price. The contractor shall provide set of installation manual/user manual for the plant. The manual includes complete system details such as array layout, schematic of the system, inverters details, working principles, etc. step by step maintenance and troubleshooting. The awarded bidder must develop reports for all serial numbers, manufacturer, and country of origin in addition to technical data including but not limited to SN, Voc, Ipmax, Vpmax,…etc, of all awarded and delivered equipment, materials, … etc. These reports must be submitted before the installation process and before the final acceptance of the project. The Bidder shall include in the offer all the required sizing, cross-sectional areas and lengths of the DC and AC cables along with required conduits. The Bidder shall provide voltage drop calculations for all PV and AC circuits to meet the allowed voltage drop percentages from the nominal voltages as follows: o For PV circuits: 2% voltage drop from the nominal voltages for all DC circuits. o For AC circuits: 2% voltage drop from the nominal voltages for all AC circuits. All excavation works required for laying the cables shall comply with all applicable codes and approved by the BAU third party consultant. 4.2 Financial Requirements The Bidder shall submit their financial proposal as an EPC offer along with their solution. The Bidder must fill a detailed bill of quantities with the cost of each item separately. The bidder shall price all proposed items and if any key item is not priced; then it will be implicitly considered. Page 43 of 54 The offer shall be in Jordanian Dinar (JOD). The financial offer shall include the training cost. The bidder shall take into account that BAU committed to pay 20% of the tender amount soon after equipment supply, and the rest 80% will be paid after the completion of the tender supported by the technical committee report assigned by BAU. The bidder shall include in line with the financial offer the prices of any spare parts. 5 Offer format 5.1 Technical offer The response to this TOR must be in the English language, structured (and presented in the same sequence) as follows: Cover letter The cover letter must be signed by the person(s) authorized to submit the proposal and must delineate the company’s ability to fulfil the project. Chapter 1: Company Profile The company profile must include registration certificates, JV if applicable, reference projects and CVs of the employees. Chapter 2: Technical description: Including: 2.1 Technical site description: This section includes the solar radiation on the site, site and installation criteria, boundaries, shade analysis, structural, civil and electrical assessment, and any relevant information. 2.2 Technical design description: This section shall include but is not limited to the following: The software design and results using PVsyst or similar software, detailed site layout, including the utilized space area and design drawings. For the Stirling dish system, all design calculations should be included in the offer. Page 44 of 54 Electrical calculations including voltage drop calculations for all DC and AC circuits in addition to mechanical mounting system calculations. The design description shall also include all the required sizing, crosssectional areas and lengths of the DC and AC cables along with required conduits. 2.3 Components and equipment selection: This section shall include all selected materials and components with their data sheets attached in the Annex section, in addition to a list of manufacturers and country of origin for all equipment and materials. 2.4 Bill of quantity: This section includes a bill of quantity for all materials and equipment proposed in the offer, including the spare parts. Chapter 3: Approach and Methodology (Scope of work) The Bidder shall explain the proposed PV system work plan, including: 3.1 Procurement, installation and operation 3.2 Testing and commissioning Includes a commissioning and testing plan according to IEC 62446 standard, listing all equipment and instruments that will be used in the commissioning. 3.3 Maintenance and cleaning Includes: A detailed maintenance plan including a maintenance checklist and technical support. A cleaning schedule, an approximation of the amount of water that will be consumed in the cleaning process, and a list of the tools that will be used. Chapter 4: Time plan The chapter shall include a time plan of the project implementation phases excluding the time needed for JEPCO and IDECO approvals. Chapter 5: Training plan The bidder shall propose a training plan in line with section 9. Chapter 6: QA/QC The bidder shall propose a quality assurance as well as a quality control plans. Chapter 7: Safety plan Chapter 8: Spare part list Page 45 of 54 Annexes: The bidder shall attach the following items in the annex section. Annex: Technical Compliance Sheet Annex: Bid bond Annex: Data sheets, Warrantees and Guarantees of the equipment Annex: other 5.2 Financial offer Chapter 1: Terms of Payment As specified before BAU is committed to pay 20% of the tender amount soon after equipment supply, and the rest 80% will be paid after the completion of the tender supported by the technical committee report assigned by BAU.. Chapter 2: PV system cost break down The Bidder shall submit the cost break down of the proposed PV system presented above The Bidder must fill a detailed bill of quantities with the cost of each item separately. 6 Component specification The bidder must fill the technical compliance sheets [Annex 1] for all offered BIPV modules, inverters, cables, and PV mounting structures, etc. It should be known that not filling the technical compliance sheet will directly disqualify the offer. 6.1 BIPV Modules The bidder shall select the suitable inclination and orientation angles of the BIPV system at each area in the site of installation, so as to achieve the ultimate electricity production taking into consideration the aesthetic aspects. The desired technical specifications for each BIPV module in each system are already mentioned in the design of each system before. The modules should be frameless with polished edges. All BIPV module’s type approval and safety certificates should be mentioned in the offer. For the Stirling dish, all test certificates should be included in the offer, too. Page 46 of 54 6.2 BIPV Mounting Structures The PV mounting structures specifications shall be made of aluminium taking into consideration that the manufacture warranty shall be 10 years. Minimum specifications of the mounting structure are: The minimum wind speed of 160 km/h shall be considered. Made of aluminium or hot-dip galvanized steel. The nuts, washers and screws should be made from stainless steel (noncorrosive). All screws, nuts, washers and fittings must be galvanized with a minimum coating of 70 micro and according to (ASTMA-123). Manufacturer's warranty should be at least 10 years. 6.3 On- Grid Inverters The on-grid inverters should meet the following specifications: The AC power of the inverter must synchronize automatically with the AC voltage and frequency of the grid (3-phase or 1-phase depending on each PV system requirements) within the tolerance range specified according to the British Energy Networks Association (ENA) engineering recommendations (G59/3 or G83/1) depending on inverter’s maximum rated current (less or greater than 16A per line at AC side). The Inverter should be designed to operate the PV array near its Maximum Power Point (MPP). The Inverter should be transformer less-based for 3-phase PV systems to be offered with efficiency at max power no less than 97%. The Inverter shall be provided with integrated fuses and AC & DC switches. The Inverter shall be provided with an LCD display to provide instantaneous information about the system performance. The Inverter shall have the following protections: reverse current, input over voltage & over current via fuses. Temperature operating range: -20 ºC to 60 ºC Harmonic distortion is less than 3%. Protection degree is IP65 or higher (outdoor). TUV and CE compliant. One unit for each subsystem can be installed. Warranty after installation should be at least 10 years. Page 47 of 54 6.4 PV / AC Cables and Conduits The minimum specifications of the PV and AC cables are: PV cables shall comply with TUV and UL 4703 standards. Operation temperature for PV cables should be up to +80oC PV cables shall be UV resistant, flame retardant, and with low smoke characteristics. PV and AC cables shall comply with local and international standards and JEPCO and IDECO requirements. AC cables shall be insulated, armoured (is a plus), sheathed copper cables drawn from the PV yard up to the connection points and shall be rated at minimum of 600Vac. All external cables must be installed inside an external use, PVC pipe with UV resistance or galvanized cable tray. All cables shall be marked properly by means of good quality labels or by other means so that cable can be easily identified. Factory warranty shall be not less than 10 years. 6.5 AC Distribution Boxes The Distribution Boxes shall be made of hot coated or galvanized steel; dust and vermin proof with a protection degree IP65 at least. The terminals and bus bars shall be appropriately size; the boxes shall have suitable cable entry with suitable glands arrangement for both input and output cables. Suitable markings on the bus bars shall be provided to identify the bus bars. The distribution box shall be grounded and for this purpose a suitable ground terminal is to be arranged. The distribution box shall be wall-mounted and of the front door opening type. 6.6 Data logging and monitoring The Bidder shall provide with the proposed system a data logging and monitoring system with the following specifications: Data logging and essential hardware and software supported with bluetooth and internet connection. Page 48 of 54 Ability to be connected with temperature and solar irradiation sensors. 6.7 Solar Radiation and Temperature Sensor Solar Irradiance Sensor Measuring range 0- 1500W/m2 Sensor: is a thermo element or photo cell Solar spectrum : 250 – 2800 nm Non linearity: < 0.2% at 0 -1000W/m2 Ambient and BIPV module temperature sensors Measuring range -20 to+90 oC Accuracy: <0.1oC through the whole range Resolution: at least 0.1 oC 7 Spare parts The bidder shall submit a spare part list including 2% of all proposed material. The Spare part list will be requested from the contractor prior the end of the third year of free maintenance period. 8 Maintenance The bidder shall include clear trouble shooting methodology and contact information that BAU technical team can use in case of emergencies. The bidder shall include a detailed maintenance plan including a maintenance checklist and technical support. The bidder shall include a detailed cleaning mechanism for each BIPV system and each Stirling dish system The contractor must show his commitment to the following times response periods that shall be pre-assigned by the contractor: o Response time for problem solving. o Response time for support. Page 49 of 54 o Response time for (hardware/software) failure of the system components or any other related components. o Response time for failed equipment or any other component replacements. 9 Training 9.1 Training scope The offer should include o n - site and off-site training for selected BAU employees and technical staff. Training must focus on but not limited to the following: Photovoltaic theory BIPV system operation Stirling dish system Trouble shooting System configuration Data acquisition and monitoring system management Relevant software Preventive and routine maintenance Performing the washing and cleaning tasks of the PV modules and structures 9.2 Training requirements Training shall be conducted theoretically and practically. Training shall be offered by an experienced instructor. Training dates must be listed in the offer. Training must be completed before the final acceptance of the project. 10 Pre-Commissioning The contractor shall develop, permit, construct and commission the project such that it achieves pre-commissioning and performs at or above the agreed upon Performance Guarantee. Page 50 of 54 11 Commissioning and Testing Plan All commissioning procedures will be carried out according to the standard protocol mentioned in IEC 62446 standard. The Contractor shall clean up the project site and remove any temporary structures, equipment or dirt, and construction debris before the final system acceptance. The contractor shall submit two original hard copies and two soft copies including but not limited to permits, as built engineering and 3D drawings, certification, instruction manual, installation, operation and maintenance manuals and checklists, QA/QC, safety plan and monitoring and software system. The Contractor shall prepare the “commissioning and testing plan” according to IEC 62446 including all equipment and instruments that will be used in the commissioning and provide it to BAU prior to the final commissioning. The final commissioning will be performed after the following: o Completion of all the above mentioned work. o Completion of all project documentation. The final commissioning will be performed by the contractor on his own expenses and will be witnessed and approved by the BAU project consultant, IDECO & IDECO approvals. If there is a need of any additional tests or testing equipment asked by the BAU, third party consultant or/and JEPCO & IDECO approvals, the Contractor must accept and provide the inquiries on his own expenses 12 Final Acceptance Final Acceptance will be issued once all of the above works and required items have been completed. Final Acceptance will be issued by the contractor to BAU at that time in accordance with the contract. Once the Final Acceptance is approved. BAU will release the 10% Performance Guarantee bond. Page 51 of 54 13 Evaluation Criteria The evaluation for the offers will go through the following three steps: 13.1 Evaluation Step 1: Qualifications and general requirements (15 points): Compliance with ITB documents will be evaluated. The key criteria, which will be used to evaluate responses to the ITB include: - Experience in designing similar Solar Photovoltaic roof systems; 5 points - Available resources to undertake the project; 3 points - Team qualification/ project manager experience; 3 points - Quality of proposal documentation received and perceived understanding by the firm of project’s requirements; 2 points - Availability of support for the systems. 2 points Only offers with the required key qualifications that will get 10 points or higher out of 15 points will go through the technical and financial evaluation. 13.2 Evaluation Step 2: Technical evaluation (70 points): All offers that will pass the evaluation step 1 (Qualifications and general requirements) will be technically evaluated according to the technical evaluation step described below: - Company qualification requirements): 15 points (according to Company qualifications and - Design compliance: 20 points - Quality of proposed products: 15 points, distributed as the following: 5 points for PV module. 5 points for inverters that comply with the technical specifications. 5 points for mounting structures that comply with the technical specifications. - Warranties, maintenance and technical support: 5 points - Methodology, time plan, installation and testing plan: 10 points - Training experience: 5 points Table 3: Technical evaluation criteria Criterion Points Page 52 of 54 Company qualification Design compliance Quality of proposed products Warranties, maintenance and technical support Methodology, time plan installation and testing plan Training Total 15 20 15 5 10 5 70 Only technically qualified offers, which get 50 points or higher out of 70 points in the technical evaluation, will go through the financial evaluation. 13.3 Evaluation step 3: Financial evaluation (30 points): All technically qualified offers will be financially evaluated. If the bidder passed the technical and financial evaluation steps, the final evaluation mark will be determined according to the following equation: Final Evaluation Mark (100 points) = Technical Evaluation Mark (70 points) + Financial Evaluation Mark (30 points) BAU and its will go into negotiation with the best three offers. BAU is free to choose the best option from the three best offers. 14 Method of Payment (Term of Payment) 20% of the total tender amount will be paid soon after equipment supply for both project locations, at Al-Salt and Al-Husun. 80% of the rest will be paid after the project completion supported by the technical committee report assigned by BAU for both locations. 15 Additional Special Conditions BAU has the right to terminate this tender upon its perspective without declaring and without any legal consequences, and the bidders have no right to object. The bidder has no right to object to the technical and financial evaluation criteria mentioned in the tender. Page 53 of 54 The JV parties must submit their JV agreement with the tender documents showing the leader party, the JV agreement signed and sealed by both parties and duly legalized by a notary public prior to the award of the contract. The Evaluation criteria provided in this tender is only for the purposes of this tender. The technical offer should not contain any hint to the financial offer. In the case of showing any hint the offer will be directly disqualified. The proposed PV system design shall be in full compliance with the regulations of the following Jordanian authorities: o Ministry of Public Work and Housing. o Energy and Minerals Regulatory Commission. o Jordan Electricity Power Company. o Civil Defence Directorate. The winning Bidder shall submit within 14 days of official awarding date a performance guarantee bond and working program showing the planned duration for project implementation phases. No offer will be accepted after closing date and time of offer submission and no email submissions will be accepted. The bidder or contractor who attempts to illegally get any information from BAU or/and misconduct ethical behaviour, will be immediately disqualified without any notice, and BAU has the right to proceed with further legal actions. 16 Annexes Annex 1: Technical Compliance Sheet Annex 2: Useful Architectural and Electrical AutoCAD Drawings (Softcopy) Annex 3: BAU Instructions in English Annex 4: BAU Instructions in Arabic Page 54 of 54