Nonlinear Seepage Mechanism and Evolution Law of CO 2 Enhancing Coalbed Methane Recovery

China’s coal seam permeability is low, and the original coal seam gas extraction is difficult. CO 2 displacement of coal seam CH 4 technology is an effective gas extraction technology. CO 2 is injected into the coal seam under pressure, and competitive adsorption occurs with CH 4 in the pores. The g...

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Veröffentlicht in:	International journal of energy research 2024-01, Vol.2024 (1)
Hauptverfasser:	Xu, Yanhui, Cheng, Xiaojiao, Fan, Shixing, Wen, Hu, Liu, Yin, Mi, Wansheng
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Sprache:	eng
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container_title	International journal of energy research
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creator	Xu, Yanhui Cheng, Xiaojiao Fan, Shixing Wen, Hu Liu, Yin Mi, Wansheng
description	China’s coal seam permeability is low, and the original coal seam gas extraction is difficult. CO 2 displacement of coal seam CH 4 technology is an effective gas extraction technology. CO 2 is injected into the coal seam under pressure, and competitive adsorption occurs with CH 4 in the pores. The gas composition is nonuniformly distributed, and its viscosity μ is the dynamic parameter. As the gas is compressible, the pressure drops, and migration distance does not satisfy a linear relationship. Therefore, the gas transport does not conform to Darcy’s law. The mass transfer process and a multicomponent gas competitive adsorption were investigated theoretically and experimentally. The adsorption characteristics and gas compressibility determine the distribution of the gas components in pores and change the gas dynamic viscosity in different regions. The change in the gas dynamic viscosity in the channel is the direct reason for the nonlinear pressure gradient and gas flow curve. The permeability and gas component affect the degree of nonlinear deviation of the gas flow and pressure gradient curve. This affects the nonlinear deviation degree of the curve by changing the gas dynamic viscosity in the pore channel during displacement. The reasonable displacement pressure is the critical pressure ( P O ) through experimental and theoretical analysis.
doi_str_mv	10.1155/2024/2524506
format	Article
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CO 2 displacement of coal seam CH 4 technology is an effective gas extraction technology. CO 2 is injected into the coal seam under pressure, and competitive adsorption occurs with CH 4 in the pores. The gas composition is nonuniformly distributed, and its viscosity μ is the dynamic parameter. As the gas is compressible, the pressure drops, and migration distance does not satisfy a linear relationship. Therefore, the gas transport does not conform to Darcy’s law. The mass transfer process and a multicomponent gas competitive adsorption were investigated theoretically and experimentally. The adsorption characteristics and gas compressibility determine the distribution of the gas components in pores and change the gas dynamic viscosity in different regions. The change in the gas dynamic viscosity in the channel is the direct reason for the nonlinear pressure gradient and gas flow curve. The permeability and gas component affect the degree of nonlinear deviation of the gas flow and pressure gradient curve. This affects the nonlinear deviation degree of the curve by changing the gas dynamic viscosity in the pore channel during displacement. 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CO 2 displacement of coal seam CH 4 technology is an effective gas extraction technology. CO 2 is injected into the coal seam under pressure, and competitive adsorption occurs with CH 4 in the pores. The gas composition is nonuniformly distributed, and its viscosity μ is the dynamic parameter. As the gas is compressible, the pressure drops, and migration distance does not satisfy a linear relationship. Therefore, the gas transport does not conform to Darcy’s law. The mass transfer process and a multicomponent gas competitive adsorption were investigated theoretically and experimentally. The adsorption characteristics and gas compressibility determine the distribution of the gas components in pores and change the gas dynamic viscosity in different regions. The change in the gas dynamic viscosity in the channel is the direct reason for the nonlinear pressure gradient and gas flow curve. The permeability and gas component affect the degree of nonlinear deviation of the gas flow and pressure gradient curve. This affects the nonlinear deviation degree of the curve by changing the gas dynamic viscosity in the pore channel during displacement. The reasonable displacement pressure is the critical pressure ( P O ) through experimental and theoretical analysis.</abstract><doi>10.1155/2024/2524506</doi><orcidid>https://orcid.org/0000-0001-9694-8637</orcidid></addata></record>
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title	Nonlinear Seepage Mechanism and Evolution Law of CO 2 Enhancing Coalbed Methane Recovery
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