An XFEM Model for Hydraulic Fracturing in Partially Saturated Rocks

Abstract: Hydraulic fracturing is a complex multi-physics phenomenon. Numerous analytical and numerical models of hydraulic fracturing processes have been proposed. Analytical solutions commonly are able to model the growth of a single hydraulic fracture into an initially intact, homogeneous rock mass. Numerical models are able to analyse complex problems such as multiple hydraulic fractures and fracturing in heterogeneous media. However, majority of available models are restricted to single-phase flow through fracture … Show more

“…The XFEM has been applied to simulate fracture behavior in a variety of materials (Figure 2), ranging from rocks [40][41][42][43] to steel [44][45][46][47][48], cast iron [49,50], aluminum [51,52], silicon oxycarbide [53,54], and composites [55][56][57]. In the steel industry, the XFEM has been applied to better understand fatigue crack propagation on bridges [44], the impact properties of high-pressure gas transportation pipes [45], and the flexural response of coated steel used for yacht manufacturing [48].…”

“…Rezanezhad et al [78] also evaluated the XFEM on porous rocks, displaying the influence of pore size, orientation, and distance on crack propagation. Salimzadeh and Khalili [40] simulated fracking by a coupled hydro-poroelastic model, incorporating the injected fracturing fluid and the host fluids. The XFEM and the cohesive elements were able to model the fracture discontinuity and propagation path.…”

XFEM for Composites, Biological, and Bioinspired Materials: A Review

“…The XFEM has been applied to simulate fracture behavior in a variety of materials (Figure 2), ranging from rocks [40][41][42][43] to steel [44][45][46][47][48], cast iron [49,50], aluminum [51,52], silicon oxycarbide [53,54], and composites [55][56][57]. In the steel industry, the XFEM has been applied to better understand fatigue crack propagation on bridges [44], the impact properties of high-pressure gas transportation pipes [45], and the flexural response of coated steel used for yacht manufacturing [48].…”

“…Rezanezhad et al [78] also evaluated the XFEM on porous rocks, displaying the influence of pore size, orientation, and distance on crack propagation. Salimzadeh and Khalili [40] simulated fracking by a coupled hydro-poroelastic model, incorporating the injected fracturing fluid and the host fluids. The XFEM and the cohesive elements were able to model the fracture discontinuity and propagation path.…”

XFEM for Composites, Biological, and Bioinspired Materials: A Review