WANG Xin, YANG Xinquan, LIANG Bing, SUN Weiji, XU Jun, WANG Fang, YANG Xinle, LI Weizhong, SONG Yongchen
Journal of Engineering Thermophysics. 2025, 46(9): 2942-2957.
CO2-ECBM engineering has the dual benefits of energy development and carbon emission reduction, and the coupled numerical simulation of heat-fluid-force multiphysics is an effective way to explore the replacement of CH4 by CO2. In this paper, by improving the apparent permeability model, the thermal-fluid-force fully coupled model is improved, and the dynamic apparent permeability, gas-water two-phase seepage, non-isothermal competitive adsorption, and coal seam strain are proposed and verified, and the main control parameters are further studied. The results show that the apparent permeability is affected by the size of capillary pores and microfractures, viscous flow, Kundsen diffusion, and surface diffusion of adsorbed gas. The change of pore fracture size is determined by the seepage process and volume strain in the reservoir. The flow process in the reservoir is affected by the coupling of gas pressure and volumetric strain, and the higher the pressure, the greater the influence of viscous flow on the apparent permeability. The effects on volumetric strain from low to high are reservoir temperature, gas mixture pressure, reservoir geological conditions, and gas adsorption/desorption. Higher CO2 injection pressure has a positive effect on H4 production and CO2 sequestration. The higher initial temperature of the coal seam increases the difficulty of CO2 gas adsorption, the displacement effect decreases, and the CO2 storage decreases.