A Discontinuous Cellular Automaton Method for Modeling Rock Fracture Propagation and Coalescence Under Fluid Pressurization Without Remeshing
详细信息 查看全文
- 作者:Peng-Zhi Pan (1) (2)
Jonny Rutqvist (2)
Xia-Ting Feng (1)
Fei Yan (1)
Quan Jiang (1) - 关键词:Crack propagation ; Fluid pressure ; Rock discontinuous cellular automaton ; Level set method ; Partition of unity ; Stress intensity factor
- 刊名:Rock Mechanics and Rock Engineering
- 出版年:2014
- 出版时间:November 2014
- 年:2014
- 卷:47
- 期:6
- 页码:2183-2198
- 全文大小:6,141 KB
- 参考文献:1. Adachi J, Siebrits E, Peirce A, Desroches J (2007) Computer simulation of hydraulic fractures. Int J Rock Mech Min Sci 44(5):739-57 CrossRef
2. Atkinson BK (1987) Fracture mechanics of rocks. Academic Press Inc., Orlando
3. Belytschko T, Black T (1999) Elastic crack growth in finite elements with minimal remeshing. Int J Numer Meth Eng 45(5):601-20 CrossRef
4. Bobet A, Einstein HH (1998) Numerical modeling of fracture coalescence in a model rock material. Int J Fract 92(3):221-52 CrossRef
5. Boone TJ, Ingraffea AR (1990) A numerical procedure for simulation of hydraulically-driven fracture propagation in poroelastic media. Int J Numer Anal Meth Geomech 14(1):27-7 CrossRef
6. Bredehoeft J, Wolff R, Keys W, Shuter E (1976) Hydraulic fracturing to determine the regional in situ stress field, Piceance Basin, Colorado. Geol Soc Am Bull 87(2):250-58 CrossRef
7. Broek D (1986) Elementary engineering fracture mechanics. Springer, The Hague CrossRef
8. Budyn E, Zi G, Moes N, Belytschko T (2004) A method for multiple crack growth in brittle materials without remeshing. Intern J Num Meth Eng 61(10):1741-770 CrossRef
9. Carrier B, Granet S (2012) Numerical modeling of hydraulic fracture problem in permeable medium using cohesive zone model. Eng Fract Mech 79:312-28 CrossRef
10. Carter BJ, Desroches J, Ingraffea AR, Wawrzynek PA (2000) Simulating fully 3D hydraulic fracturing. In: Zaman M, Gioda G, Booker J (eds) Modeling in geomechanics. Wiley, Hoboken, pp 525-57
11. Charlez P (1991) Rock mechanics (II: petroleum applications). Technip, Paris
12. Devloo PRB, Fernandes PD, Gomes SM, Bravo CMAA, Damas RG (2006) A finite element model for three dimensional hydraulic fracturing. Mathem Comp Simul 73(1-):142-55 CrossRef
13. Dolbow J, Moes N, Belytschko T (2000) Discontinuous enrichment in finite elements with a partition of unity method. Finite Elem Anal Des 36(3-):235-60 CrossRef
14. Dong CY, Pater CJD (2001) Numerical implementation of displacement discontinuity method and its application in hydraulic fracturing. Comp Meth Appl Mech Eng 191:745-60 CrossRef
15. Dusseault MB, Bilak R, Bruno M, Rothenburg L (1996) Disposal of granular solid wastes in the western Canadian sedimentary basin by slurry fracture injection. In: Apps J, Tsang CF (eds) Deep injection of disposal of hazardous industrial waste. Scientific and engineering aspects, San Diego, pp 725-42
16. Fareo AG, Mason D (2011) A group invariant solution for a pre-existing fluid-driven fracture in permeable rock. Nonlinear Anal 12(1):767-79 CrossRef
17. Haimson B, Fairhurst C (1969) In-situ stress determination at great depth by means of hydraulic fracturing. In: The 11th US Symposium on Rock Mechanics (USRMS), Berkeley, USA
18. Heuze F, Shaffer R, Ingraffea A, Nilson R (1990) Propagation of fluid-driven fractures in jointed rock. Part 1––development and validation of methods of analysis. Intern J Rock Mech Min Sci Geomech Abstr 27(4):243-54 CrossRef
19. Hillerborg A, Modeer M, Petersson PE (1976) Analysis of crack formation and crack growth in concrete by means of fracture mechanics and finite elements. Cem Concr Res 6(6):773-81- 作者单位:Peng-Zhi Pan (1) (2)
Jonny Rutqvist (2)
Xia-Ting Feng (1)
Fei Yan (1)
Quan Jiang (1)
1. State Key Laboratory of Geomechanics and Geotechnical Engineering, Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, Wuhan, 430071, China
2. Lawrence Berkeley National Laboratory, MS 90-1116, Berkeley, CA, 94720, USA- ISSN:1434-453X
- 作者单位:Peng-Zhi Pan (1) (2)
文摘
We present a formulation of a discontinuous cellular automaton method for modeling of rock fluid pressure induced fracture propagation and coalescence without the need for remeshing. Using this method, modelers discretize a discontinuous rock-mass domain into a system composed of cell elements in which the numerical grid and crack geometry are independent of each other. The level set method, which defines the relationship between cracks and the numerical grid, is used for tracking the crack location and its propagation path. As a result, no explicit meshing for crack surfaces and no remeshing for crack growth are needed. Discontinuous displacement functions, i.e., the Heaviside functions for crack surfaces and asymptotic crack-tip displacement fields, are introduced to represent complex discontinuities. When two cracks intersect, the tip enrichment of the approaching crack is annihilated and is replaced by a Heaviside enrichment. We use the “partition of unity-concept to improve the integral precision for elements, including crack surfaces and crack tips. From this, we develop a cellular automaton updating rule to calculate the stress field induced by fluid pressure. Then, the stress is substituted into a mixed-mode fracture criterion. The cracking direction is determined from the stress analysis around the crack tips, where fracture fluid is assumed to penetrate into the newly developed crack, leading to a continuous crack propagation. Finally, we performed verification against independent numerical models and analytic solutions and conducted a number of simulations with different crack geometries and crack arrangements to show the robustness and applicability of this method.