Abstract
Hydraulic fracturing is a widely used production stimulation technology for conventional and unconventional reservoirs. The cohesive element is used to explain the tip fracture process. In this paper, the cohesive zone model was used to simulate hydraulic fracture initiation and propagation at the same time rock deformation and fluid exchange. A numerical model for fracture propagation in poro-viscoelastic formation is considered. In this numerical model, we incorporate the pore-pressure effect by coupling fluid diffusion with shale matrix viscoelasticity. The numerical procedure for hydraulically driven fracture propagation uses a poro-viscoelasticity theory to describe the fluid diffusion and matrix creep in the solid skeleton, in conjunction with pore-pressure cohesive zone model and ABAQUS was used as a platform for the numerical simulation. The simulation results are compared with the available solutions in the literature. The higher the approaching angle, the higher the differential stress, tensile stress difference, injection rate, and injection fluid viscosity, and it will be easier for hydraulic fracture crossing natural fracture. These results could provide theoretical guidance for predicting the generation of fracture network and gain a better understanding of deformational behavior of shale when fracturing.
Highlights
Unconventional reservoirs, such as shale, coal seam and tight-gas sand, are highly reliant on hydraulic fracturing to increase the production
We developed a fully coupled poro-viscoelastic fracture propagation model to
We developed a fully coupled poro-viscoelastic fracture propagation model to investigate the characteristics of hydraulic fracturing in shale formation
Summary
Unconventional reservoirs, such as shale, coal seam and tight-gas sand, are highly reliant on hydraulic fracturing to increase the production. Simakin and Ghassemi [10] put forward another poro-viscoelastic model by considering the relaxation of the deviatoric stress and the symmetric effective stress These constitutive models can be used to simulate the coupling process between fluid flow and creep deformation of matrix rocks, but they cannot be directly applied to simulate hydraulic fracturing, especially the interaction of hydraulic fracturing with natural fractures. Under formation temperature and pressure, the brittle rock in shale exhibits ductility after hydraulic fracturing treatments It may not be the best choice to use elastic theory to analyze the shale failure. CZM has great advantages in predicting crack propagation orientation in different kinds of materials (such as metals, concrete, and rocks [14]) It has been used for simulating hydraulic fracture interactions with natural fracture [15,16,17]. Pore-pressure CZM and ABAQUS was used as a platform for the numerical simulation
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