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Rock Mechanics and Rock Engineering

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01-09-2012 | Original Paper

Numerical Simulation of 3D Hydraulic Fracturing Based on an Improved Flow-Stress-Damage Model and a Parallel FEM Technique

Authors: L. C. Li, C. A. Tang, G. Li, S. Y. Wang, Z. Z. Liang, Y. B. Zhang

Published in: Rock Mechanics and Rock Engineering | Issue 5/2012

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Abstract

The failure mechanism of hydraulic fractures in heterogeneous geological materials is an important topic in mining and petroleum engineering. A three-dimensional (3D) finite element model that considers the coupled effects of seepage, damage, and the stress field is introduced. This model is based on a previously developed two-dimensional (2D) version of the model (RFPA2D-Rock Failure Process Analysis). The RFPA3D-Parallel model is developed using a parallel finite element method with a message-passing interface library. The constitutive law of this model considers strength and stiffness degradation, stress-dependent permeability for the pre-peak stage, and deformation-dependent permeability for the post-peak stage. Using this model, 3D modelling of progressive failure and associated fluid flow in rock are conducted and used to investigate the hydro-mechanical response of rock samples at laboratory scale. The responses investigated are the axial stress–axial strain together with permeability evolution and fracture patterns at various stages of loading. Then, the hydraulic fracturing process inside a rock specimen is numerically simulated. Three coupled processes are considered: (1) mechanical deformation of the solid medium induced by the fluid pressure acting on the fracture surfaces and the rock skeleton, (2) fluid flow within the fracture, and (3) propagation of the fracture. The numerically simulated results show that the fractures from a vertical wellbore propagate in the maximum principal stress direction without branching, turning, and twisting in the case of a large difference in the magnitude of the far-field stresses. Otherwise, the fracture initiates in a non-preferred direction and plane then turns and twists during propagation to become aligned with the preferred direction and plane. This pattern of fracturing is common when the rock formation contains multiple layers with different material properties. In addition, local heterogeneity of the rock matrix and macro-scale stress fluctuations due to the variability of material properties can cause the branching, turning, and twisting of fractures.

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Abass HH, Saeed Hedayati, Meadows DL (1992) Halliburton services. Non-planar fracture propagation from a horizontal wellbore: experimental study. SPE 24823, pp 324–339

Adachi J, Siebrits E, Peirce A, Desroches J (2007) Computer simulation of hydraulic fractures. Int J Rock Mech Min Sci 44:739–757CrossRef

Aliabadi MH (1999) Fracture of rock. Computational Mechanics Publications, WIT Press, Boston

Barree RD (1983) A practical numerical simulator for three-dimensional fracture propagation in heterogeneous media. SPE Paper No 12273

Barrett R, Berry M, Chan TF, Demmel J, Donato J, Dongarra J, Eijkhout V, Pozo R, Romine C, Vander Vorst H (1994) Templates for the solution of linear systems: Building blocks for iterative methods. Society for Industrial Mathematics, PhiladelphiaCrossRef

Biot MA (1941) General theory of three-dimensional consolidation. J Appl Phys 12:155–164CrossRef

Blaheta R, Byczanski P, Jakl O, Kohut R, Kolcun A, Krecmer K, Stary J (2006) Large-scale parallel FEM computations of far/near stress field changes in rocks. Future Gener Comput Syst 22:449–459CrossRef

Carter BJ, Desroches J, Ingraffea AR, Wawrzynek PA (2000) Simulating fully 3D hydraulic fracturing. In: Zaman M, Booker J, Gioda G (eds) Modeling in geomechanics. Wiley Publishers, New York

Chen YF, Zhou CB, Sheng YQ (2007) Formulation of strain-dependent hydraulic conductivity for a fractured rock mass. Int J Rock Mech Min Sci 44:981–996CrossRef

Crosby DG, Yang Z, Rahman SS (1998) The successful use of transverse hydraulic fractures from horizontal wellbores. SPE 50423, pp 128–136

Deng GZ, Wang SB, Huang BX (2004) Research on behavior character of crack development induced by hydraulic fracturing in coal-rockmass. Chin J Rock Mech Rock Eng 23(20):3489–3493

Detournay E, Carbonell R. (1994) Fracture mechanics analysis of breakdown process in minifrac or leak-off tests. In: Proc, Eurock’94, Balkema, Rotterdam, pp 399–407

Dong CY, de Pater CJ (2001) Numerical implementation of displacement discontinuity method and its application in hydraulic fracturing. Comput Methods Appl Mech Eng 191:745–760CrossRef

Economides MJ, Nolte KG (2000) Reservoir stimulation. Wiley, Singapore

Erdogan F, Biricikoglu V (1973) Two bonded half planes with a fracture going through the interface. Int J Eng Sci 11:745–766CrossRef

Fairhurst C (1964) On the validity of the Brazilian test for brittle materials. Int J Rock Mech Min Sci 1:535–546CrossRef

Fang Z, Harrison JP (2002) Development of a local degradation approach to the modelling of brittle fracture in heterogeneous rocks. Int J Rock Mech Min Sci 39:443–457CrossRef

Garcia JG, Teufel LW (2005) Numerical simulation of fully coupled fluid-flow/geomechanical deformation in hydraulically fractured reservoirs. SPE Paper 94062, 2005 SPE Production and Operations Symposium, Oklahoma, USA

Geertsma J, de Klerk F (1969) A rapid method of predicting width and extent of hydraulically induced fractures. J Pet Tech 21:1571–1581

Helgeson DE, Aydin A (1991) Characteristics of joint propagation across layer interfaces in sedimentary rocks. J Struct Geol 13:897–911CrossRef

Jaeger JC, Cook NGW, Zimmerman RW (2007) Fundamentals of rock mechanics, 4th edn. Blackwell, Oxford

Khristianovic SA, Zheltov YP (1955) Formation of vertical fractures by means of highly viscous liquid. In: Proceedings of the fourth world petroleum congress, Rome, pp 579–586

Lee SH, Ghassemi A (2011) Poroelastic rock failure analysis around multiple hydraulic fractures using a BEM/FEM model. In: 45th US rock mechanics/geomechanics symposium held in San Francisco, USA

Legarth B, Huenges E, Zimmermann G (2005) Hydraulic fracturing in a sedimentary geothermal reservoir: results and implications. Int J Rock Mech Min Sci 42:1028–1041CrossRef

Li SP, Wu DX (1997) Effect of confining pressure, pore pressure and specimen dimension on permeability of Yinzhuang sandstone. Int J Rock Mech Min Sci 34:435–441CrossRef

Li LC, Tang CA, Tham LG, Yang TH, Wang SH (2005) Simulation of multiple hydraulic fracturing in non-uniform pore pressure field. Adv Mater Res 9:163–172CrossRef

Li LC, Tang CA, Li CW, Zhu WC (2006) Slope stability analysis by SRM-based rock failure process analysis (RFPA). Geomech Geoeng Int J 1:51–62CrossRef

Li LC, Yang TH, Liang ZZ, Tang CA (2011a) Numerical investigation of groundwater outbursts near faults in underground coal mines. Int J Coal Geol 85(3):276–288CrossRef

Li LC, Tang CA, Wang SY (2011b) A numerical investigation of fracture infilling and spacing in layered rocks subjected to hydro-mechanical loading. Rock Mech Rock Eng. doi:10.1007/s00603-011-0194-x

Liang ZZ, Tang CA, Li HX, Xu T, Zhang YB (2004) Numerical simulation of 3-D failure process in heterogeneous rocks. Int J Rock Mech Min Sci 41:323–328CrossRef

Louis C (1974) Rock hydraulics. In: Muller L (ed) Rock mechanics. Springer, Vienna

Ma GW, Wang XJ, Ren F (2011) Numerical simulation of compressive failure of heterogeneous rock-like materials using SPH method. Int J Rock Mech Min Sci 48:353–363CrossRef

Mahrer KD (1999) A review and perspective on far-field hydraulic fracture geometry studies. J Pet Sci Eng 24:13–28CrossRef

Medlin WL, Fitch JL (1983) Abnormal treating pressures in MHF treatments. In: SPE 12108, 58th SPE annual technical conference and exhibition, San Francisco, CA, USA

Meng QM, Zhang SC, Guo XM, Chen XH, Zhang Y (2010) A primary investigation on propagation mechanism for hydraulic fracture in glutenite formation. J Oil Gas Tech 32(4):119–123

Mofazzal Hossain Md, Rahman MK (2008) Numerical simulation of complex fracture growth during tight reservoir stimulation by hydraulic fracturing. J Pet Sci Eng 60:86–104CrossRef

Nordren RP (1972) Propagation of a vertical hydraulic fracture. SPE J 12(8):306–314

Pearce CJ, Thavalingam A, Liao Z, Bicanic N (2000) Computational aspects of the discontinuous deformation analysis framework for modeling concrete fracture. Eng Fract Mech 65:283–298CrossRef

Perkins TK, Kern LR (1961) Widths of hydraulic fractures. J Pet Tech 13(9):937–949

Pietruszczak S, Xu G (1995) Brittle response of concrete as a localization problem. Int J Solid Struct 32:1517–1533CrossRef

Rungamornrat J, Wheeler MF, Mear ME (2005) A numerical technique for simulating nonplanar evolution of hydraulic fractures. In: SPE 96968, 2005 SPE annual technical conference and exhibition, Dallas, Texas, USA

Savitski AA, Detournay E (2002) Propagation of a penny-shaped fluid-driven fracture in an impermeable rock: asymptotic solutions. Int J Solids Struct 39:6311–6337CrossRef

Schulze O, Popp T, Kern H (2001) Development of damage and permeability in deforming rock salt. Eng Geol 61:163–180

Shah KR, Carter BJ, Ingraffea AR (1997) Hydraulic fracturing simulation in parallel computing environments. Int J Rock Mech Min Sci 34:474–484CrossRef

Shao JF, Zhou H, Chau KT (2005) Coupling between anisotropic damage and permeability variation in brittle rocks. Int J Numer Anal Meth Geomech 29:1231–1247CrossRef

Siebrits E, Peirce AP (2002) An efficient multi-layer planar 3D fracture growth algorithm using a fixed mesh approach. Int J Numer Meth Eng 53:691–717CrossRef

Simonson ER, Abou-Sayed AS, Clifton RJ (1978) Containment of massive hydraulic fractures. SPE J 18(1):27–32

Sousa JLS, Carter BJ, Ingraffea AR (1993) Numerical simulation of 3D hydraulic fracture using Newtonian and power-law fluids. Int J Rock Mech Min Sci Geomech Abstr 30:1265–1271CrossRef

Stormont JC, Daemen JJK (1992) Laboratory study of gas permeability changes in rock salt during deformation. Int J Rock Mech Min Sci Geomech Abstr 29:325–342

Susan E, Minkoff C, Stone M, Bryant S (2003) Coupled fluid flow and geomechanical deformation modeling. J Pet Sci Eng 38:37–56CrossRef

Tang CA (1997) Numerical simulation on progressive failure leading to collapse and associated seismicity. Int J Rock Mech Min Sci 34(2):249–261CrossRef

Tang CA, Tham LG, Lee PKK, Yang TH, Li LC (2002) Coupled analysis of flow, stress and damage (FSD) in rock failure. Int J Rock Mech Min Sci 39(4):477–489CrossRef

Vandamme L, Curran JH (1989) A three-dimensional hydraulic fracturing simulator. Int J Numer Meth Eng 28:909–927CrossRef

Wang SY, Sun L, Au ASK, Yang TH, Tang CA (2009) 2D-numerical analysis of hydraulic fracturing in heterogeneous geo-materials. Constr Build Mater 23(6):2196–2206CrossRef

Warpinski NR, Moschovidis ZA, Parker CD, Abou-Sajed IS (1993) Comparison study of hydraulic fracturing models: test case GRI-staged field experiment. SPE, pp 469–478

Yale DP, Lyons SL, Qin G (2000) Coupled geomechanics-fluid flow modeling in petroleum reservoirs: coupled versus uncoupled response. In: Girard J, Liebman M, Breed C, Doe T (eds) Pacific rocks 2000. Balkema, Rotterdam, pp 137–144

Yang TH, Tham LG, Tang CA, Liang ZZ, Tsui Y (2004) Influence of heterogeneity of mechanical properties on hydraulic fracturing in permeable rocks. Rock Mech Rock Eng 37(4):251–275CrossRef

Yuan SC, Harrison JP (2005) Development of a hydro-mechanical local degradation approach and its application to modelling fluid flow during progressive fracturing of heterogeneous rocks. Int J Rock Mech Min Sci 42:961–984CrossRef

Zhang X, Jeffrey RG (2006) The roles of secondary flaws and friction on deflection and reinitiation of hydraulic fractures at orthogonal preexisting fractures. Geophys J Int 166:1454–1465CrossRef

Zhang X, Jeffrey RG, Thiercelin M (2007) Deflection and propagation of fluid-driven fractures at frictional bedding interfaces: a numerical investigation. J Struct Geol 29:396–410CrossRef

Zhang X, Jeffrey RG, Thiercelin M (2008) Escape of fluid-driven fractures from frictional bedding interfaces: a numerical study. J Struct Geol 30:478–490CrossRef

Zhu WC, Tang CA (2004) Micromechanical model for simulating the fracture process of rock. Rock Mech Rock Eng 37:25–56CrossRef

Zhu WL, Wong TF (1997) The transition from brittle faulting to cataclastic flow: permeability evolution. J Geophys Res 102(B2):3027–3041CrossRef

Title: Numerical Simulation of 3D Hydraulic Fracturing Based on an Improved Flow-Stress-Damage Model and a Parallel FEM Technique
Authors: L. C. Li
C. A. Tang
G. Li
S. Y. Wang
Z. Z. Liang
Y. B. Zhang
Publication date: 01-09-2012
Publisher: Springer Vienna
Published in: Rock Mechanics and Rock Engineering / Issue 5/2012
Print ISSN: 0723-2632
Electronic ISSN: 1434-453X
DOI: https://doi.org/10.1007/s00603-012-0252-z

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