P ractical Well Control - The University of Texas at Austin
Transcription
P ractical Well Control - The University of Texas at Austin
Fourth Edition P ractical Well Control By Ron Baker published by The University of Texas at austin Division of Continuing & Innovative Education PETROLEUM EXTENSION SERVICE 1998 Library of Congress Cataloging-in-Publication Data Baker, Ron, 1940 Practical well control/by Ron Baker.—4th. ed. p. cm. ISBN 0-88698-183-2 1. Oil wells—blowouts. I. Baker, Ron. II. Title. TN871.2.F547 1989 622'.3382—dc20 89-39589 CIP © 1998 by The University of Texas at Austin All rights reserved First Edition published 1980. Fourth Edition 1998 Sixth Impression 2012 Printed in the United States of America This book or parts thereof may not be reproduced in any form without permission of Petroleum Extension Service, The University of Texas at Austin. Brand names, company names, trademarks, or other identifying symbols appearing in illustrations or text are used for educational purposes only and do not constitute an endorsement by the author or the publisher. Catalog No. 2.80040 ISBN 0-88698-183-2 The University of Texas at Austin is an equal opportunity institution. No state tax funds were used to publish this book. C ontents Figures..................................................................................................................................................... v Tables....................................................................................................................................................... vii Foreword................................................................................................................................................. ix 1. Pressure Concepts......................................................................................................................... 1-1 2. Causes and Warning Signs of Kicks........................................................................................... 2-1 3. Shut-in Procedures and Shut-in Pressure.................................................................................. 3-1 4. Circulation and Well Control....................................................................................................... 4-1 5. Formation Fracture Gradient....................................................................................................... 5-1 6. Well-Control Methods.................................................................................................................. 6-1 7. Unusual Well-Control Operations.............................................................................................. 7-1 8. Well Control for Completion and Workover............................................................................. 8-1 9. Well Control and Floating Drilling Rigs.................................................................................... 9-1 10. Blowout Prevention Equipment.................................................................................................. 10-1 11. Organizing and Directing Well-Control Operations................................................................ 11-1 Appendix A. Hydrogen Sulfide Considerations............................................................................. A-1 H2S Guidelines for Offshore Operations.................................................................. A-2 H2S Guidelines for Land Operations........................................................................ A-5 Corrosion and H2S....................................................................................................... A-6 Appendix B. Reference Tables........................................................................................................... B-1 Appendix C. Equations....................................................................................................................... C-1 Appendix D. Cross-Reference Index and 30 CFR........................................................................... D-1 Appendix E. Cross-Reference Relating Elements in Practical Well Control to IADC WellCAP Well-Control Accreditation Program................................................................................................... E-1 Glossary ................................................................................................................................................. G-1 Index........................................................................................................................................................ I-1 iii Chapter 1 Pressure Concepts practical well control P ressure Concepts I n well control, the two pressures of primary concern are formation pressure and hydrostatic pressure. Formation pressure is the force exerted by fluids in a formation. It is measured at the depth of the formation with the well shut in. It is also called reservoir pressure or, since it is usually measured at the bottom of the hole with the well shut in, shut-in bottomhole pressure. In drilling, hydrostatic pressure is the force exerted by drilling fluid in the wellbore. When formation pressure is greater than hydrostatic pressure, formation fluids may enter the wellbore. If formation fluids enter the wellbore because formation pressure is higher than hydrostatic pressure, a kick has occurred. If prompt action is not taken to control the kick, or kill the well, a blowout may occur. To control a well, a proper balance between pressure in the formation and pressure in the wellbore must be maintained; hydrostatic pressure should be equal to or slightly higher than formation pressure. pressure, as it increases, compaction occurs, and the porosity of the rock layer decreases. As compaction occurs, any fluids in the formation are squeezed into permeable layers, such as sandstone. If the permeable layer into which the fluids are squeezed is continuous to the surface—that is, if the layer eventually outcrops on the surface— pressure higher than normal cannot form (fig. 1.1). If, however, a layer’s fluid is trapped because of faulting or some other anomaly, pressure higher than normal can form; the formation can become overpressured. Origin of Formation Pressure One generally accepted theory of how pressures originate in subsurface formations relates to how sedimentary basins are formed. As layer upon layer of sediments are deposited, overburden pressure on the layers increases, and compaction occurs. Overburden pressure is the pressure exerted at any given depth by the weight of the sediments, or rocks, and the weight of the fluids that fill pore spaces in the rock. Overburden pressure is generally considered to be 1 pound (lb) per square inch per foot (psi/ ft). Overburden pressure can vary in different areas because the amount of pore space and the density of rocks vary from place to place. In deepwater formations just below the seafloor, the overburden is almost entirely seawater. Overburden pressure is therefore about the same as the pressure caused by the weight of seawater—about 0.45 psi/ft depending on its salinity. Regardless of the actual value of overburden surface outcrop permeable layer Figure 1.1Pressure higher than normal cannot form if the layer outcrops on the surface. 1-1 11-1 1-1 Pressure Concepts Higher-than-normal formation pressure can result from several geological conditions. In some cases, the same conditions that trap hydrocarbons can also cause higher-than-normal pressure. Examples of such geological conditions are faults, large structures, massive shale beds, massive salt beds, and charged sands. Faults Formation pressure normally increases with depth, but deep rocks that have been faulted may have higher-than-normal pressures. The fault may trap fluids in the formation and allow abnormally high pressure to develop. Since a fault is a sudden break in a formation, when a faulted formation is drilled, the bit may encounter abnormally high pressure within a short interval; that is, it is possible to go from normal pressure to abnormally high pressure within a short time. Therefore, when faulted zones are being drilled, the crew must be alert to the possibility of encountering abnormally high pressures with very little warning. The high pressures that appear at different depths in the Lake Arthur field in South Louisiana are the result of a highly faulted structure. High pressures encountered in drilling next to salt domes are often the result of local faulting around the dome. High pressures related to faulting can also be found in mountainous country. Large Structures Any structure such as an anticline or dome may have abnormally high pressures above the oil-water or gas-water contact in the oil or gas zone because hydrocarbons are less dense than water. If the anticline or dome is large, abnormal pressures may be quite high. Since anticlines and domes sometimes serve as traps for hydrocarbons, drilling often takes place on such structures. Thus, drilling crews should be alert to the possibility of abnormally high pressures in such situations. High pressures may be expected when drilling into the reservoir beds—usually sandstone, limestone, or dolomite—of any structure. The high pressures that were experienced in the early days of the East Texas field came from an anticlinal structure. Since large structures are often first drilled by the crew on a wildcat well, the crew should be aware of the possibility of high pressure. 1-2 practical well control Massive Shale Beds Transition zones—formations in which pressures begin to depart from normal—and abnormally high pressure may develop within massive shale beds because thick, impermeable shale restricts the movement of fluid. As sediments are laid down on the surface and then sink deeper, they support the considerable weight of the overburden. Fluids trapped within the shale cannot escape fast enough, and they also support the weight of the overburden. Confined liquids supporting such massive weight are under higher-than-normal pressure for the depth. When thick shales are encountered, therefore, pressure should be expected to increase abnormally with depth. Shale-related pressures can occur at any depth, from near the surface to very deep. High pressures in the U.S. Gulf Coast, the North Sea, the South China Sea, and in other deep basins of the world are often related to massive shale beds. Massive Salt Beds Since salt beds are plastic, they transmit all overburden weight to the rock below. Therefore, high pressures should be expected in and below thick salt beds. High pressures usually are not found in thin and erratic salt beds, however. Thick, plastic salt beds cause high pressures in the Middle East in formations below the Farrs salt, and in the United States in beds below the Louann salt. Pressures in the Zechstein salt in the North Sea and in northern Germany are also related to the fact that salt transmits the rock weight above it to the formation below it. Drilling mud with densities from 16 pounds per gallon (ppg) to 19 ppg may be necessary to control the pressures within and just below massive salt beds. Charged Sands Abnormally high formation pressure can be found in relatively shallow sands that have become charged from an underground blowout. A shallow sand can become charged when a well is shut in on a kick originating in a zone deeper than the sand. Pressure from the lower zone then enters the wellbore and escapes to the upper sand. As a result, the upper sand becomes overpressured by the fluids from the lower zone. Later, when another well is drilled into the charged sand, the drilling crew may be caught off guard when the charged sand kicks. Pressure Concepts practical well control depth (tvd) Figure 1.2 Hole geometry has no effect on hydrostatic pressure. Pressure exerted at bottom is the static pressure. Pressure exerted at bottom is the same for all containers because fluid density and depth are the same. Hydrostatic Pressure The term “hydrostatic” is derived from hydro, meaning water or liquid, and static, meaning at rest. Both fluid in the formation and fluid in the wellbore are under hydrostatic pressure, but in most well-control discussions, formation pressure refers to fluid pressure in the formation; hydrostatic pressure refers to the pressure of drilling fluid in the wellbore. Hydrostatic pressure increases directly with the density and depth of the fluid in the wellbore. Hole geometry—the diameter and shape of the fluid column—has no effect on hydrostatic pressure (fig. 1.2). In the wellbore, hydrostatic pressure is the result of the weight, or density, of the drilling fluid and the true vertical depth of the column of fluid. True vertical depth is the length of a straight vertical line from the surface to the bottom of the hole. Measured, or total, depth is the length of the well as measured along the actual course of the hole. Thus, true vertical depth and measured depth can differ, especially in directionally drilled holes (fig. 1.3). In determining hydrostatic pressure, true vertical depth is the measurement used. measured depth 10,500 ft tvd 10,000 ft Figure 1.3In this case, true vertical depth is different from measured depth, because the hole is directionally drilled. 1-3 Pressure Concepts practical well control Mud weight can be expressed in ppg, pounds per cubic foot (pcf), specific gravity, or other units. In the United States, mud weight is usually expressed in ppg, except on the Pacific Coast, where it is usually expressed in pcf. If mud weight is measured in ppg, the value of C in equation 1 is 0.052. If mud weight is measured in pcf, the value of C in equation 1 is 0.00694. As an example of using the equation, find the hydrostatic pressure in a wellbore if the mud weight is 12 ppg and the true vertical depth (TVD) is 11,325 ft. HP = 0.052 × 12 × 11,325 = 7,066.8 HP = 7,067 psi. Figure 1.4 Simple mud balance Hydrostatic pressure can be calculated mathematically as— HP = C × MW × TVD (Eq. 1) where HP = hydrostatic pressure, psi C = a constant (value depends on unit used to express mud weight) MW = mud weight, ppg or other units TVD = true vertical depth, ft. To find hydrostatic pressure if the mud weight is 90 pcf and TVD is 11,325 ft, the calculation is— HP = 0.00694 × 90 × 11,325 = 7,073.6 HP = 7,074 psi. Measuring Mud Weight Mud weight is usually measured with a simple mud balance (fig. 1.4). It can also be measured, however, with a special pressurized mud balance (fig. 1.5A pressurization port (check valve is under Port) pressure lid Rider balance arm spirit level cylinder cup housing (balance cup inside) knob pump nose pressurization pump Figure 1.5A Pressurized mud balance (Courtesy Fann Instrument Company) 1-4 Pressure Concepts practical well control mud to be tested. Put the perforated cap on the cup and rotate it until it is firmly seated. Be sure that some of the mud comes out through the hole in the cap to free any trapped air or gas. Hold the cap firmly on the cup and, while keeping the hole covered, wash or wipe the outside of the cup until it is clean and dry. Place the balance arm (beam) on the fulcrum or base support and balance it by sliding the weight along the beam’s graduated scale. If the mud balance has a bubble, the bubble will be directly under a center line etched on the metal around the bubble when balance occurs. Read the mud weight at the edge of the sliding weight. Using a pressurized mud balance is very much like using a regular mud balance except that the mud sample is put under pressure to approximate downhole conditions. Depending on the manufacturer of the balance, some type of pressure device is secured to the sample cup to pressure up the sample. A procedure from a manufacturer of a pressurized mud balance follows. (Refer to Figure 1.5.) PRESSURING PUMP SEALING LID CHECK VALVE lbs/gal lbs/cu. ft. 7 50 SAMPLE CUP ENTRAINED AIR SLURRY SAMPLE Figure 1.5B Pressurized mud balance cutaway and 1.5 B). Crewmembers may be instructed to use a pressurized balance to obtain mud weight when air or gas is entrained in the mud. Pressurizing the balance’s sample cup decreases the volume of any entrained air or gas in the mud to a negligible amount. As a result, the mud density measurement will more accurately reflect downhole conditions. To use a regular mud balance, place the instrument on a flat, level surface. Fill the clean, dry cup with the 1. Collect a fluid sample. 2. Place the balance’s stand or carrying case on a flat, level surface. 3. Measure and record the temperature of the sample, then transfer the sample to the balance cup, filling to between ¼ and ⅛ in. of the top. Tap the side of the cup several times to break up any entrained air or gases. 4. Place the lid on the cup with the check valve in the down or open position. (Some of the test sample may be expelled through the valve.) After fitting the lid onto the cup, pull the check valve up into the closed position. 5. Rinse the pressurization port and balance with water, base oil, or solvent; then dry it off. 6. Slide the cup housing over the balance cup from the bottom, aligning the slot with the balance arm. Screw the closure over the pressure lid and tighten as tight as possible by hand to insure that the pressure lid is completely seated. 7. Fill the pressurization pump with the test sample. 8. Push the nose of the pump onto the pressure port of the lid. 9. Pressure the sample cup by maintaining a downward force on the pump cylinder housing. At the same time, force the pump knob down with about 50 to 70 lb of force and release the cylinder housing. Remove the pump. (The check valve 1-5