Modeling of mixed-mechanism stimulation for the enhancement of geothermal reservoirs
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Hydraulic stimulation is a critical process for increasing the permeability of fractured geothermal reservoirs. This technique relies on coupled hydromechanical processes induced by reservoir stimulation through pressurized fluid injection into the rock formation. The injection of fluids causes poromechanical stress changes that can lead to the dilation of fractures due to fracture slip and to tensile fracture opening and propagation, so-called mixed-mechanism stimulation. The effective permeability of the rock is particularly enhanced when new fractures connect with pre-existing fractures. Mixed-mechanism stimulation can significantly improve the productivity of geothermal reservoirs, and the technique is especially important in reservoirs where the natural permeability of the rock is insufficient to allow for commercial flow rates. This paper presents a modeling approach for simulating the deformation and expansion of fracture networks in porous media under the influence of anisotropic stress and fluid injection. It utilizes a coupled hydromechanical model for poroelastic, fractured media. Fractures are governed by contact mechanics and allowed to grow and connect through a fracture propagation model. To conduct numerical simulations, we employ a twolevel approach, combining a finite volume method for poroelasticity with a finite element method for fracture propagation. The study investigates the impact of injection rate, matrix permeability, and stress anisotropy on stimulation outcomes. By analyzing these factors, we can better understand the behavior of fractured geothermal reservoirs under mixedmechanism stimulation.
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