深部煤层注气强化开采的流-固-热耦合数值模拟研究OA北大核心CSTPCD
Numerical simulation of fluid-solid-thermal coupling for CO2 injection enhanced mining in deep coal seams
为研究温度效应对深部煤层注CO2 增抽瓦斯的影响规律,根据煤体变形特征和瓦斯渗流特性基本理论,建立了同时考虑非等温吸附、二元气体竞争吸附、气体渗流和扩散、热传递和热对流的注CO2 强化煤层抽采的流-固-热耦合模型,探究了温度效应对煤储层参数和产气演化规律的影响.结果表明:煤层温度降低引起的煤基质收缩促进了CH4 解吸,忽略温度效应的流-固耦合模型会低估瓦斯产气量;在初始渗透率为 3.95×10-17 m2,CO2 注气压力为 8 MPa时,对于韩城矿区 3#煤层埋深 1 400 m的深部煤体而言,考虑温度效应(319.5 K)的流-固-热耦合模型相比流-固耦合模型,瓦斯抽采 3 650 d,煤层平均瓦斯压力下降 0.69%,A点渗透率增幅 11.02%,产气速率增幅 13.51%,累计产气量增幅 13.76%.
In order to study the effect of temperature effect on CO2 injection and gas extraction in deep coal seams,a fluid-solid-thermal coupling model for CO2-injection enhanced coal seam extraction was established based on the basic theory of coal deforma-tion characteristics and gas seepage characteristics,which also considered non-isothermal adsorption,binary gas competitive adsorp-tion,gas seepage and diffusion,heat transfer and heat convection.The influence of temperature effect on coal reservoir parameters and gas production evolution law is investigated.The results show that the shrinkage of coal matrix caused by coal bed temperature decrease promotes CH4 desorption,and the fluid-solid coupling model ignoring temperature effect will underestimate gas production.When the initial permeability is 3.95×10-17 m2 and the CO2 injection pressure is 8 MPa,for the deep coal body buried 1 400 m in the No.3 coal seam in Hancheng Mining area,compared with the fluid-solid-thermal coupling model considering the temperature effect(319.5 K),the gas extraction time of 3 650 days is higher than that of the fluid-solid coupling model.The average gas pressure of coal seam decreased by 0.69%,the permeability of A point increased by 11.02%,the gas production rate increased by 13.51%,and the cumulative gas production increased by 13.76%.
姚文军;邓存宝;范楠;申文迈;张林峰;张鹏莉
太原理工大学 安全与应急管理工程学院,山西 太原 030024
矿山工程
瓦斯抽采流-固-热耦合煤层注CO2气体煤层气绝对渗透率
gas drainagefluid-solid-thermal couplingCO2 injection into coal seamcoal-bed methaneabsolute permeability
《煤矿安全》 2024 (007)
31-38 / 8
山西省基础研究计划青年资助项目(202203021212291);山西省高等学校科技创新资助项目(2021L058)
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