Abstract
CO2 flooding of coalbed methane (CO2-ECBM) not only stores CO2 underground and reduces greenhouse gas emissions but also enhances the gas production ratio. This coupled process involves multi-phase fluid flow and coal-rock deformation, as well as processes such as competitive gas adsorption and diffusion from the coal matrix into fractures. A dual-porosity medium that consists of a matrix and fractures was built to simulate the flooding process, and a mathematical model was used to consider the competitive adsorption, diffusion and seepage processes and the interaction between flow and deformation. Due to the effects of the initial pressure and the differences in pressure variation during the production process, permeability changes caused by matrix shrinkage were spatially variable in the reservoir. The maximum value of permeability appeared near the production well, and the degree of rebound decreased with increasing distance from the production well.
Highlights
The porosity and permeability of fracture systems in coalbed methane reservoirs are influenced by effective stress and gas adsorption-desorption
Deformations induced by adsorption were studied by the researchers [11,12,13,14]. Those studies of CO2 flooding of coalbed methane mostly focus on competitive adsorption between CO2 and CH4, gas-water two-phase flow and the effect caused by coal or rock deformation on permeability
Using the simulation software to solve the coupling model, our study emphasized the influence of coal matrix shrinkage on permeability during CO2 flooding
Summary
The porosity and permeability of fracture systems in coalbed methane reservoirs are influenced by effective stress and gas adsorption-desorption. Those studies of CO2 flooding of coalbed methane mostly focus on competitive adsorption between CO2 and CH4, gas-water two-phase flow and the effect caused by coal or rock deformation on permeability.
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