热流固耦合作用下注采参数对CO2驱替瓦斯影响规律研究

Influence of injection-production parameters on CO2 displacement of gas under thermal-hydraulic-mechanical coupling

  • 摘要: 注入CO2驱替瓦斯是提高深部低渗透煤层瓦斯抽采效率的关键手段,同时能实现CO2地质封存,兼具经济与环境效益。为了探究CO2注入煤层驱替瓦斯的规律,提出了一种考虑二元气体渗透、扩散、竞争吸附及煤体变形的热流固耦合模型,借助COMSOL数值模拟软件,系统研究了不同注气压力、注采间距下CO2浓度、煤体渗透率及温度的动态变化,分析了不同注采参数下的CH4采收率、CO2封存量,以评估驱替效果。研究结果表明:① 注气压力、注采间距的增大可显著提高CO2在煤体中的扩散能力,加剧煤体变形,使渗透率与温度波动更明显。② 注气压力从0.5 MPa增加至2.5 MPa,注气60 d后CH4采收率、CO2封存量分别提高了10.47%,387.00%,CO2封存量对注气压力的变化更敏感。③ 注采间距从3 m增大至7 m时,注气60 d后CH4采收率、CO2封存量分别提高了48.34%,9.19%,CH4采收率对注采间距的变化更敏感。④ 工程应结合实际目标优化注采参数,若以瓦斯增产为主,应优先增大注采间距;若以CO2封存为主,应优先增大注气压力。现场工艺试验进一步证实,增大注气压力与注采间距可有效提高瓦斯抽采速度和产量,验证了热流固耦合模型的可靠性。

     

    Abstract: Injection of CO2 to displace gas is a key method to improve gas extraction efficiency in deep low-permeability coal seams, and can also realize CO2 geological storage, delivering both economic and environmental benefits. To investigate the laws of CO2 injection into coal seams for gas displacement, a thermal-hydraulic-mechanical coupling model considering binary gas seepage, diffusion, competitive adsorption, and coal deformation was proposed. With COMSOL numerical simulation software, dynamic changes in CO2 concentration, coal permeability, and temperature under different gas injection pressures and injection-production spacings were systematically studied, and CH4 recovery rate and CO2 storage amount under different injection-production parameters were analyzed to evaluate the displacement effect. The results showed that: ① increases in gas injection pressure and injection-production spacing could significantly improve the diffusion capacity of CO2 in coal, intensify coal deformation, and make fluctuations in permeability and temperature more obvious. ② When gas injection pressure increased from 0.5 MPa to 2.5 MPa, CH4 recovery rate and CO2 storage amount after 60 d of injection increased by 10.47% and 387.00%, respectively, and CO2 storage amount was more sensitive to changes in gas injection pressure. ③ When injection-production spacing increased from 3 m to 7 m, CH4 recovery rate and CO2 storage amount after 60 d of injection increased by 48.34% and 9.19%, respectively, and CH4 recovery rate was more sensitive to changes in injection-production spacing. ④ Engineering applications should optimize injection-production parameters according to actual objectives. If gas production enhancement was the main goal, injection-production spacing should be increased preferentially. If CO2 storage was the main goal, gas injection pressure should be increased preferentially. Field process tests further confirmed that increasing gas injection pressure and injection-production spacing could effectively improve gas extraction rate and yield, verifying the reliability of the thermal-hydraulic-mechanical coupling model.

     

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