Experimental study on stress and permeability response with gas depletion in coal seams

IF 4.9 2区工程技术 Q2 ENERGY & FUELS Journal of Natural Gas Science and Engineering Pub Date : 2022-12-01 DOI:10.1016/j.jngse.2022.104824

Beichen Yu , Dongming Zhang , Kui Zhao , Bin Xu , Jiabo Geng , Chongyang Wang , Yu Chen

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引用次数: 0

Abstract

The gas extraction environment in coal seam exhibits uniaxial strain condition with constant overlying strata stress and horizontal strain. Simulating this environment in laboratory often ignores true triaxial stress state, so the difference in horizontal stresses reduction and the accompanying permeability evolution remain ambiguous. Therefore, this study conducted the true triaxial stress and permeability response tests simulating gas extraction environment under shallow and deep in-situ stress conditions. To quantify gas adsorption effect, the adsorbed (CO₂) and non-adsorbed (He) gases were also used. The results indicated that the intermediate and minimum principal stresses, i.e., σ₂ and σ₃, exhibited a linear decreasing trend during gas depletion, but showed more decreases in stress when the intermediate and minimum principal strains, i.e., ε₂ and ε₃, recover under high gas pressure depletion. High true triaxial stress enhanced the compressibility of pores and fractures in coal, resulting in low horizontal deformation and stress reduction gradient during gas depletion. Similarly, the reduction gradient of σ₂, m_σ2, was less than that of σ₃. This suggested that the difference between horizontal stresses also increased during coalbed methane (CBM) extraction, which exacerbated the risk of coal body damage. For different gas depletion, the stress reduction gradient exhibited m_He < 1 and m_CO2 > 1, which was related to the relative affinity of different gas species for the adsorption medium. A significant matrix shrinkage effect resulted in a more pronounced stress reduction. For permeability, the permeability increased exponentially during CO₂ depletion, while the permeability of helium exhibited a decreasing followed by an increase with decreasing gas pressure. This is related to the competing mechanism and synergistic effect of the adsorptive gas desorption, effective stress effect, and slippage effect. We quantified the contribution and mechanism of the three to the permeability separately. The permeability anisotropy ratio (A_r) decreased exponentially during gas depletion.

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煤层瓦斯枯竭时应力和渗透率响应的实验研究

煤层瓦斯开采环境表现为上覆地层应力和水平应变恒定的单轴应变状态。在实验室模拟这种环境时往往忽略了真实的三轴应力状态，因此水平应力减小的差异和伴随的渗透率演化仍然是模糊的。因此，本研究进行了浅、深地应力条件下模拟采气环境的真三轴应力及渗透率响应试验。为了量化气体的吸附效果，还使用了吸附(CO2)和未吸附(He)气体。结果表明:在气蚀过程中，中间主应力和最小主应力σ2和σ3呈线性下降趋势，而在高压气蚀过程中，中间主应力和最小主应力ε2和ε3恢复后，应力下降幅度更大;高真三轴应力增强了煤中孔隙和裂缝的可压缩性，导致煤层在瓦斯枯竭过程中水平变形和应力消减梯度较低。同样，σ2的还原梯度小于σ3的还原梯度。这说明在煤层气开采过程中，水平应力差增大，加剧了煤体破坏的风险。对于不同的气体枯竭，应力减小梯度表现为mHe <1和mCO2 >1，这与不同气体种类对吸附介质的相对亲和力有关。显著的基体收缩效应导致更明显的应力降低。渗透率方面，CO2耗尽过程中渗透率呈指数增长，而氦气渗透率随气体压力的降低呈现先下降后上升的趋势。这与吸附气体脱附、有效应力效应和滑移效应的竞争机制和协同作用有关。分别量化了三者对渗透率的贡献和作用机理。渗透率各向异性比(Ar)在气藏衰竭过程中呈指数下降。

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来源期刊

Journal of Natural Gas Science and Engineering ENERGY & FUELS-ENGINEERING, CHEMICAL

CiteScore

8.90

自引率

0.00%

发文量

388

审稿时长

3.6 months

期刊介绍： The objective of the Journal of Natural Gas Science & Engineering is to bridge the gap between the engineering and the science of natural gas by publishing explicitly written articles intelligible to scientists and engineers working in any field of natural gas science and engineering from the reservoir to the market. An attempt is made in all issues to balance the subject matter and to appeal to a broad readership. The Journal of Natural Gas Science & Engineering covers the fields of natural gas exploration, production, processing and transmission in its broadest possible sense. Topics include: origin and accumulation of natural gas; natural gas geochemistry; gas-reservoir engineering; well logging, testing and evaluation; mathematical modelling; enhanced gas recovery; thermodynamics and phase behaviour, gas-reservoir modelling and simulation; natural gas production engineering; primary and enhanced production from unconventional gas resources, subsurface issues related to coalbed methane, tight gas, shale gas, and hydrate production, formation evaluation; exploration methods, multiphase flow and flow assurance issues, novel processing (e.g., subsea) techniques, raw gas transmission methods, gas processing/LNG technologies, sales gas transmission and storage. The Journal of Natural Gas Science & Engineering will also focus on economical, environmental, management and safety issues related to natural gas production, processing and transportation.