reservoir geomecanics

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4 Reservoir geomechanics its frictional strength (Chapters 4, 11 and 12). Depletion causes changes in the stress state of the reservoir that can be beneficial, or detrimental, to production in a number of ways (Chapter 12). As emphasized throughout this book, determination of the state of stress at depth in oil and gas fields is a tractable problem that can be addressed with data that are routinely obtained (or are straightforwardly obtainable) when wells are drilled. In this chapter, I start with the basic definition of a stress tensor and the physical meaning of principal stresses. These concepts are important to establish a common vocabulary among readers with diverse backgrounds and are essential for understanding how stress fields change around wellbores (Chapters 6 and 8) and in the vicinity of complex structures such as salt domes (as discussed at the end of the chapter). I also introduce a number of fundamental principles about the tectonic stress field at a regional scale in this chapter. These principles are revisited at scales ranging from individual wellbores to lithospheric plates in Chapter 9. While many of these principles were established with data from regions not associated with oil and gas development, they have proven to have broad relevance to problems encountered in the petroleum industry. Forexample, issues related to global and regional stress patterns are quite useful when working in areas with little pre-existing well control or when attempting to extrapolate knowledge of stress orientation and relative stress magnitudes from one area to another. Stress in the earth’s crust Compressive stress exists everywhere at depth in the earth. Stress magnitudes depend on depth, pore pressure and active geologic processes that act at a variety of different spatial and temporal scales. There are three fundamental characteristics about the stress field that are of first-order importance throughout this book: Knowledge of stress at depth is of fundamental importance for addressing a wide range of practical problems in geomechanics within oil, gas and geothermal reservoirs and in the overlaying formations. The in situ stress field at depth is remarkably coherent over a variety of scales. These scales become self-evident as data from various sources are analyzed and synthesized. It is relatively straightforward to measure, estimate or constrain stress magnitudes at depth using techniques that are practical to implement in oil, gas and geothermal reservoirs. Hence, the state of stress is directly determinable using techniques that will be discussed in the chapters that follow. In short, the in situ stress field in practice is determinable, comprehensible and needed to address a wide range of problems in reservoir geomechanics. In this chapter I review a number of key points about the state of stress in the upper part of the earth’s crust. First, we establish the mathematical terminology that will be used throughout this book and some of the fundamental physical concepts and definitions that make it possible to address many practical problems in subsequent
Page 2: Reservoir Geomechanics This interdi
Page 8: cambridge university press Cambridg
Page 14: Contents Preface page xi PART I: BA
Page 18: ix Contents More on drilling-induce
Page 22: Preface This book has its origin in
Page 26: xiii Preface done with Pavel Peska
Page 34: 1 The tectonic stress field My goal
Page 40: 6 Reservoir geomechanics Definition
Page 44: 8 Reservoir geomechanics also gener
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Page 56: 14 Reservoir geomechanics condition
Page 60: 16 Reservoir geomechanics Indicator
Page 64: 18 Reservoir geomechanics S hmin an
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Page 76: 24 Reservoir geomechanics −85 o
Page 80: 26 Reservoir geomechanics materials
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30 Reservoir geomechanics 0 2000 40
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32 Reservoir geomechanics 0 LATE PL
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34 Reservoir geomechanics A Field b
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36 Reservoir geomechanics a. b. Pre
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38 Reservoir geomechanics productio
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40 Reservoir geomechanics Mechanism
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42 Reservoir geomechanics 2600 2800
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44 Reservoir geomechanics is a comp
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46 Reservoir geomechanics 0.4 j 0 =
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48 Reservoir geomechanics a. b. Pre
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50 Reservoir geomechanics where f i
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a. W Shot Number E 1300 1400 1500 1
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a. f BURIAL AT HYDROSTATIC Porosity
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3 Basic constitutive laws 56 In thi
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Stress (MPa) 58 Reservoir geomechan
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60 Reservoir geomechanics Figure 3.
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62 Reservoir geomechanics 10 SANDST
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64 Reservoir geomechanics Table 3.1
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66 Reservoir geomechanics Biot (196
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68 Reservoir geomechanics for very
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a. 10 8 DYNAMIC MODULI (ULTRASONIC)
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72 Reservoir geomechanics in veloci
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74 Reservoir geomechanics a. b. Ins
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76 Reservoir geomechanics such that
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78 Reservoir geomechanics Mechanica
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80 Reservoir geomechanics of the hi
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82 Reservoir geomechanics The total
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4 Rock failure in compression, tens
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S 3 S 1 86 Reservoir geomechanics S
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a. s 1 b s n t s 3 b. t Mohr envelo
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90 Reservoir geomechanics a. Shear
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92 Reservoir geomechanics STRONG RO
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94 Reservoir geomechanics 150 s 3 1
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96 Reservoir geomechanics a. b. 125
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98 Reservoir geomechanics a. 300 25
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100 Reservoir geomechanics p a is a
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102 Reservoir geomechanics Drucker-
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104 Reservoir geomechanics wellbore
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106 Reservoir geomechanics b. t m 0
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108 Reservoir geomechanics a. 300 M
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a. 300 6000 4000 3000 V p (m/s) 200
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a. 300 250 5000 21 4000 V p (m/s) 3
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114 Reservoir geomechanics Table 4.
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118 Reservoir geomechanics velocity
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120 Reservoir geomechanics 300 S v
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124 Reservoir geomechanics Because
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126 Reservoir geomechanics Maximum
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128 Reservoir geomechanics S 1 - S
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130 Reservoir geomechanics Healy (1
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132 Reservoir geomechanics fault (t
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a. Stress or pressure 0 20 40 60 80
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136 Reservoir geomechanics m i Shea
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138 Reservoir geomechanics a. SHmax
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5 Faults and fractures at depth 140
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142 Reservoir geomechanics S Hmax
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a. JOINT SHEARED JOINT ONSET OF DAM
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146 Reservoir geomechanics Wellbore
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Depth (feet) 148 Reservoir geomecha
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150 Reservoir geomechanics UP (DIP
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152 Reservoir geomechanics a. 6500
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154 Reservoir geomechanics in Figur
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156 Reservoir geomechanics Alternat
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158 Reservoir geomechanics a. N b.
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160 Reservoir geomechanics a. Doubl
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162 Reservoir geomechanics A D B C
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Part II Measuring stress orientatio
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168 Reservoir geomechanics stress c
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170 Reservoir geomechanics trajecto
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172 Reservoir geomechanics strongly
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174 Reservoir geomechanics boundary
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a. b. N E S W N N E S W N c. 0 W BO
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178 Reservoir geomechanics In Figur
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180 Reservoir geomechanics a. A S H
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184 Reservoir geomechanics X-STRUCT
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188 Reservoir geomechanics stress-i
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190 Reservoir geomechanics and then
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194 Reservoir geomechanics a. 150 s
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196 Reservoir geomechanics More on
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198 Reservoir geomechanics with tim
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200 Reservoir geomechanics a. b. Fi
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202 Reservoir geomechanics virtual
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7 Determination of S 3 from mini-fr
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208 Reservoir geomechanics stress o
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210 Reservoir geomechanics The othe
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212 Reservoir geomechanics supplies
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214 Reservoir geomechanics 0 0 Stre
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216 Reservoir geomechanics a. 8 7 P
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218 Reservoir geomechanics a. -400
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220 Reservoir geomechanics Can hydr
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222 Reservoir geomechanics the hydr
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228 Reservoir geomechanics used var
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232 Reservoir geomechanics 5390 Bre
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234 Reservoir geomechanics and Zoba
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236 Reservoir geomechanics the prin
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238 Reservoir geomechanics are give
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240 Reservoir geomechanics a. b. c.
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242 Reservoir geomechanics discusse
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244 Reservoir geomechanics a. b. Te
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246 Reservoir geomechanics a. s min
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248 Reservoir geomechanics b. Botto
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250 Reservoir geomechanics 80 25 MP
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252 Reservoir geomechanics a. 180 b
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256 Reservoir geomechanics ∼1-5 k
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258 Reservoir geomechanics a. b. S
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260 Reservoir geomechanics a. Boreh
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262 Reservoir geomechanics True fas
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264 Reservoir geomechanics Figure 8
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9 Stress fields - from tectonic pla
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180˚ 270˚ 0˚ 90˚ 180˚ 70˚ 70
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270 Reservoir geomechanics subjecte
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1 1 9 o E 8 o E 7 o E 6 o E 5 o E 4
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276 Reservoir geomechanics 7000 Nor
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a. 8000 Normal faulting Measured S
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280 Reservoir geomechanics Methods
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282 Reservoir geomechanics from 0.4
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284 Reservoir geomechanics the meas
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286 Reservoir geomechanics 0 Equiva
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290 Reservoir geomechanics a. b. S
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292 Reservoir geomechanics A few mo
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294 Reservoir geomechanics Pressure
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Part III Applications
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302 Reservoir geomechanics The next
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304 Reservoir geomechanics a. Stabl
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306 Reservoir geomechanics to remed
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Depth (feet) 310 Reservoir geomecha
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312 Reservoir geomechanics The pred
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314 Reservoir geomechanics a. 13.22
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318 Reservoir geomechanics a. N b.
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320 Reservoir geomechanics S Hmax A
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322 Reservoir geomechanics to the a
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324 Reservoir geomechanics and S hm
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326 Reservoir geomechanics 4 P grow
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328 Reservoir geomechanics p w = s
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11 Critically stressed faults and f
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342 Reservoir geomechanics a. 0.4 m
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346 Reservoir geomechanics with fau
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348 Reservoir geomechanics a. 3000
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Table 11.1. Detection of permeable
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352 Reservoir geomechanics All Plan
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a. ALL FRACTURES FROM SIT FRACTURES
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356 Reservoir geomechanics exploita
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358 Reservoir geomechanics expected
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360 Reservoir geomechanics hole, Sh
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362 Reservoir geomechanics rock wit
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364 Reservoir geomechanics a. A S H
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366 Reservoir geomechanics N EXTENT
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368 Reservoir geomechanics a. A b.
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370 Reservoir geomechanics FILL TO
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372 Reservoir geomechanics Schemati
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376 Reservoir geomechanics HIGH a.
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12 Effects of reservoir depletion A
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384 Reservoir geomechanics There ar
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386 Reservoir geomechanics
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390 Reservoir geomechanics Zoback a
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396 Reservoir geomechanics can also
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398 Reservoir geomechanics and ther
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400 Reservoir geomechanics curve is
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404 Reservoir geomechanics
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406 Reservoir geomechanics To deter
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412 Reservoir geomechanics Hagin an
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Figure 12.18. (a) Map of southern L
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418 Reservoir geomechanics along a
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References Aadnoy, B. S. (1990a).
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425 References Bourbie, T., Coussy,
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427 References Coulomb, C. A. (1773
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429 References Flemings, P. B., Stu
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431 References Hayashi, K. and Haim
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433 References Lade, P. (1977). “
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435 References Moos, D. and Zoback,
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437 References Raaen, A. M. and Bru
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439 References Tang, X. M. and Chen
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441 References Wiprut, D. and Zobac
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443 References Zoback, M. L. and a.
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446 Index critically stressed fault
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448 Index ridge push 270 RMS (root
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180˚ 216˚ 252˚ 288˚ 324˚ 64˚
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a. 70 Pressure history - Lapeyrouse
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. 140 a. 120 100 S hmin S Hmax R S
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Figure 6.4. (a) Wellbore breakouts
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a. A S Hmax A-CENTRAL FAULT HIGH RE
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a. b. Figure 6.17. The area in whic
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160 155 150 145 S Hmax (MPa) 140 13
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a. b. Tendency for breakouts Orient
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180˚ 270˚ 0˚ 90˚ 180˚ 70˚ 70
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Depth (feet) S Hmax N S hmin W S v
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Figure 10.9. (a) Probability densit
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S Hmax ABOVE THE FAULT 9 10 11 12 R
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-9 200' - 9200 ' - 9 600 ' a. LESS
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a. 0.4 m = 1.0 m = 0.6 t/S v 0.2 0
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a. 3000 S Hmax = 10N 3100 3200 Dept
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a. ALL FRACTURES FROM SIT FRACTURES
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a. A S Hmax A-CENTRAL FAULT HIGH RE
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a. A b. N N A B C B C D D E E 0 1 2
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N Vertical Displacement cm 2 N East
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