Numerical analysis of rock fracturing by gas pressure using the extended finite element method

Chao Z, Baiquan L, Yan Z, et al. Study of fracturing-sealing integration technology based on high-energy gas fracturing in single seam with high gas and low air permeability. Int J Min Sci Technol. 2013;23:841–6.

Cho SH, Risei K, Kato M, et al. Development of numerical simulation method for dynamic fracture propagation due to gas pressurization and stress wave. In: Proceedings of 2002 ISRM regional symposium (3rd Korea-Japan joint symposium) on rock engineering problem and approaches in underground construction, Jul 22–24, Seoul; 2002. p. 755–62.

Cho SH, Ogata Y, Kaneko K. Strain-rate dependency of the dynamic tensile strength of rock. Int J Min Sci Technol. 2004a;40:763–77.

Cho SH, Nakamura Y, Kaneko K. Dynamic fracture process analysis of rock subjected to stress wave and gas pressurization. Int J Min Sci Technol. 2004b;41:433–40.

Cho SH, Kaneko K. Influence of the applied pressure waveform on the dynamic fracture processes in rock. Int J Min Sci Technol. 2004;41:771–84.

Cho SH, Nakamura Y, Mohanty B, et al. Numerical study of fracture plane control in laboratory-scale blasting. Eng Fract Mech. 2008;75:3966–84.

Chu TY, Jacobson RD, Warpiniski N. Geothermal well stimulation using high energy gas fracturing. In: Proceedings of 12th workshop on geothermal reservoir engineering, Jan 20–22, Stanford, CA; 1987.

Daehnke A, Rossmanith HP, Napier AL. Gas pressurization of blast-induced conical cracks. Int J Rock Mech Min Sci. 1997;34(3–4):263.e1–17.

Garnsworthy RK. The mathematical modeling of rock fragmentation by high pressure arc discharges. In: 3rd international symposium on rock fragmentation blasting, Aug 26–31, Brisbane; 1990. p. 143–7.

Gholami A, Rahman SS, Natarajan S. Simulation of hydraulic fracture propagation using XFEM. In: EAGE symposium, sustainable earth sciences, Sept 30–Oct 4, Pau; 2013.

Goodarzi M, Mohammadi S, Jafari A. Analysis of gas-driven crack propagation around a blasthole with the extended finite element method. In: Proceedings of the 2nd international symposium on computational geomechanics (COMGEO II), April 27–29, Croatia; 2011. p. 425–33.

Goodarzi M, Salmi EF, Mohammadi S, et al. Numerical modeling of gas fracturing with the extended finite element method. In: Proceedings of the 3rd international symposium on computational geomechanics (COMGEO III). August, 21–23, Poland; 2013. p. 706–16.

Gordeliy E, Peirce A. Coupling schemes for modeling hydraulic fracture propagation using the XFEM. Comput Methods Appl Mech Eng. 2013;253:305–22.

Jaimes MG, Castillo RD, Mendoza SA. High energy gas fracturing: a technique of hydraulic prefracturing to reduce the pressure losses by friction in the near wellbore—a Colombian field application. In: The SPE Latin American and Caribbean petroleum engineering conference, April 16–18, Mexico City (SPE 152886); 2012.

Krilove Z, Kavedzija B, Bukovac T. Advanced well stimulation method applying a propellant technology. Wiertnictwo Nafta Gaz. 2008;25(2):405–16.

Kutter HK, Fairhurst C. On the fracture process in blasting. Int J Rock Mech Min Sci. 1971;8:181–202.

Ma GW, An XM. Numerical simulation of blasting-induced rock fractures. Int J Rock Mech Min Sci. 2008;75:966–75.

McHugh S. Crack extension caused by internal gas pressure compared with extension caused by tensile stress. Int J Fract. 1983;21:163–76.

Mohammadi S, Bebamzadeh A. A coupled gas-solid interaction model for FE/DE simulation of explosion. Finite Elem Anal Des. 2005;41:1289–308.

Mohammadi S, Pooladi A. Non-uniform isentropic gas flow analysis of explosion in fractured solid media. Finite Elem Anal Des. 2007;43:478–93.

Mohammadi S. Extended finite element method for fracture analysis of structure. London: Blackwell Publishing; 2008.

Mohammadi S. XFEM fracture analysis of composites. London: Wiley; 2012.

Mohammadi S, Pooladi A. A two-mesh coupled gas flow–solid interaction model for 2D blast analysis in fractured media. Finite Elem Anal Des. 2012;50:48–69.

Mohammadnejad T, Khoei AR. An extended finite element method for hydraulic fracture propagation in deformable porous media with the cohesive crack model. Finite Elem Anal Des. 2013;73:77–95.

Mortazavi A, Katsabanis PD. Modeling burden size and strata dip effects on the surface blasting process. Int J Rock Mech Min Sci. 2001;38:481–98.

Munjiza A, Latham JP, Andrews KRF. Detonation gas model for combined finite-discrete element simulation of fracture and fragmentation. Int J Numer Method Eng. 2000;49:1495–520.

Nilson RH, Griffiths SK. Numerical analysis of hydraulically-driven fractures. Comput Method Appl Mech Eng. 1983;36:359–70.

Nilson RH, Proffer WJ, Duff RE. Modeling of gas-driven fracture induced by propellant combustion within a borehole. Int J Rock Mech Min Sci Geomech Abstr. 1985;22(1):3–19.

Paine AS, Please CP. An improved model of fracture propagation by gas during rock blasting—some analytical results. Int J Rock Mech Min Sci Geomech Abstr. 1995;31(6):699–706.

Ren QW, Dong YW, Yu TT. Numerical modeling of concrete hydraulic fracturing with extended finite element method. Sci China Ser E. 2009;52(3):559–65.

Ruest M, Cundall P, Guest A, et al. Developments using the particle flow code to simulate rock fragmentation by condensed phase explosives. In: FRAGBLAST—8 (8th international symposium on rock fragmentation by blasting), May 8–11, Santiago; 2006. p. 140–51.

Salazar A, Almanza E, Folse K. Application of propellant high-energy gas fracturing in gas-injector wells at El Furrial field in Northern Monagas State–Venezuela. In: The SPE international symposium and exhibition on formation damage control, Feb 20–21, Lafayette (SPE 73756); 2002.

Saouma VE. Lecture notes in fracture mechanics (Chapter 7). Department of Civil Environmental and Architectural Engineering, University of Colorado; 2000.

Wu J, Liu L, Zhao G, et al. Research and exploration of high energy gas fracturing stimulation integrated technology in Chinese shale gas reservoir. Adv Mater Res. 2012;524–527:1532–6.

Yang W, Zhou C, Qin F, et al. High-energy gas fracturing (HEGF) technology: research and application. In: European petroleum conference, Nov 16–18, Cannes (SPE 24990); 1992.

Zhu Z, Mohanty B, Xie H. Numerical investigation of blasting-induced crack initiation and propagation in rocks. Int J Rock Mech Min Sci. 2007;44:412–24.

Zhu WC, Tang CA, Huang ZP, et al. A numerical study of the effect of loading conditions on the dynamic failure of rock. Int J Rock Mech Min Sci. 2004;41(3):424.