Investigation of thermal-hydraulic-mechanical coupling model for in-situ transformation of oil shale considering pore structure and anisotropy

IF 6.9 1区 工程技术 Q1 ENGINEERING, GEOLOGICAL Engineering Geology Pub Date : 2024-12-07 DOI:10.1016/j.enggeo.2024.107859
Zijian Chen, Shengyuan Song, Wen Zhang, Shidi Mei, Shuo Zhang
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Abstract

The in-situ transformation of oil shale is an intricately complex process involving multiple physical field coupling. Through a series of laboratory experiments, this study reveals the relationship between the anisotropy of pore structure and the anisotropy of physical and mechanical properties in oil shale during the heating process. Results reveal that during heating, pyrolysis-induced parallel bedding macroscopic cracks significantly diminish thermal conductivity in the vertical bedding direction, drastically elevate permeability in the parallel bedding direction, and markedly decrease compressive strength in the parallel bedding direction and elastic modulus in the vertical bedding direction. Subsequently, we firstly propose a thermal-hydraulic-mechanical coupling model for the in-situ transformation of oil shale, which integrates anisotropic thermodynamic damage with a transversely isotropic constitutive model, to investigate the variation patterns of the reservoir temperature field, seepage field, stress field and displacement field during the convective heating process for in-situ transformation. Research findings indicate that: (1) the temperature field expands elliptically from the heating well and disseminates outwardly, achieving the target temperature across the entire reservoir by the 585th day of heating. (2) Permeability changes exhibit pronounced anisotropy and are tightly correlated with temperature fluctuations. (3) The distribution of pore pressure undergoes alterations due to temperature increases, which in turn impacts the heating rate of water vapor. (4) The vertical displacement change of the reservoir cap progresses through four distinct stages: a rapid increase phase, a brief rapid decrease phase, a transitional phase and a continuous decrease phase. Notably, the maximum expansion displacement is 0.056 m, while the maximum compression displacement reaches −0.081 m. This research not only provides significant scientific theoretical support for advancing the development of in-situ transformation technology for oil shale, but also offers reliable scientific evidence for large-scale industrial exploitation of oil shale in the future.
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考虑孔隙结构和各向异性的油页岩原位转化热-水-机械耦合模型研究
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来源期刊
Engineering Geology
Engineering Geology 地学-地球科学综合
CiteScore
13.70
自引率
12.20%
发文量
327
审稿时长
5.6 months
期刊介绍: Engineering Geology, an international interdisciplinary journal, serves as a bridge between earth sciences and engineering, focusing on geological and geotechnical engineering. It welcomes studies with relevance to engineering, environmental concerns, and safety, catering to engineering geologists with backgrounds in geology or civil/mining engineering. Topics include applied geomorphology, structural geology, geophysics, geochemistry, environmental geology, hydrogeology, land use planning, natural hazards, remote sensing, soil and rock mechanics, and applied geotechnical engineering. The journal provides a platform for research at the intersection of geology and engineering disciplines.
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