Abstract
To reveal the evolution law of coal skeleton deformation during the process of CO2 flooding and displacing CH4 in coal seam, a fluid-solid coupling mathematical model of CO2 injection enhanced CH4 drainage was established based on Fick’s law, Darcy’s law, ideal gas state equation, and Langmuir equation. Meanwhile, numerical simulations were carried out by implementing the mathematical model in the COMSOL Multiphysics. Results show that the CH4 content of both regular gas drainage and CO2 enhanced gas drainage gradually decreases with time, and the decreasing rate is high between 10 and 60 days. Compared with regular gas drainage, the efficiency of CO2 enhanced gas drainage is more obvious with greater amount of CH4 extracted out. When coal seam gas is extracted for 10, 60, 120, and 180 days, CH4 content in coal seam is reduced by 5.2, 17.2, 23.6, and 26.7%, respectively. For regular gas drainage, the deformation of coal skeleton is dominated by the shrink of coal matrix induced by gas desorption, and the strain curve shows a continuous downward trend. For CO2 enhanced gas drainage, the strain curve of coal skeleton showed a decrease—rapid increase—slow increase trend. The evolution of permeability is opposite to the evolution of coal skeleton strain. Higher gas injection pressure will lead to a greater coal skeleton strain. The pumping pressure affects the deformation of coal skeleton slightly compared with that of initial water saturation and initial temperature. Greater initial water saturation leads to larger deformation of coal skeleton in the early stage. The strain value of coal skeleton gradually tends to be consistent as gas injection prolongs. Higher initial temperature leads to greater reduction in coal skeleton strain when the gas injection continues. Research achievements provide a basis for the field application of CO2 injection enhanced CH4 drainage in underground coal mines.
Highlights
Coal seam gas is a by-product of coal mining, mainly composed of CH4 (Fan et al, 2017)
Zhou et al (2012) and Fang et al (2019b) used COMSOL Multiphysics software to analyze the evolution of permeability in the CO2-ECBM process, and the results show that the effective stress changes, matrix shrinkage, and swelling caused by pumping pressure of drainage and CO2 injection pressure are the key factors affecting permeability
2) The CH4 content of both regular and CO2 enhanced gas drainage gradually decreases with time, and the decreasing rate is high between 10 and 60 days
Summary
Coal seam gas is a by-product of coal mining, mainly composed of CH4 (Fan et al, 2017). N2 mainly displaces coal bed methane by changing the pressure gradient in the coal-rock fractures (Lin et al, 2018), and the competitive adsorption effect is small. The above experiments show that CO2 injection can flood or displace coal seam CH4 and improve the efficiency of CH4 drainage. Vishal et al (2015) studied the effect of adsorption time on CO2 enhanced coal bed methane recovery (CO2-ECBM). Zhou et al (2012) and Fang et al (2019b) used COMSOL Multiphysics software to analyze the evolution of permeability in the CO2-ECBM process, and the results show that the effective stress changes, matrix shrinkage, and swelling caused by pumping pressure of drainage and CO2 injection pressure are the key factors affecting permeability. The results will provide a reference for improving the CH4 drainage from coal seams during underground mining
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