Study on permeability evolution and damage mechanism along the EGS fracture in heat mining stage under thermal stress/cracking

• Published in: Geothermal energy (Heidelberg) Vol. 11; no. 1; pp. 31 - 25
• Main Authors: Zhang, Wei, Wang, Dong, Wang, Zenglin, Guo, Tiankui, Wang, Chunguang, He, Jiayuan, Zhang, Le, Zheng, Peng, Qu, Zhanqing
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 08.11.2023; Springer Nature B.V; SpringerOpen
• Subjects: Cooling; Cracking (fracturing); Damage simulation; Earth and Environmental Science; Earth Sciences; Energy; Enhanced geothermal system; Geoecology/Natural Processes; Geotechnical Engineering & Applied Earth Sciences; Geothermal power; Heat recovery systems; High temperature; High temperature fracture permeability; Permeability; Renewable and Green Energy; Simulation; Stress measurement; Thermal cracking; Thermal stress; Thermal stress; High temperature fracture permeability; Thermal cracking; Enhanced geothermal system; Damage simulation
• ISSN: 2195-9706; 2195-9706
• DOI: 10.1186/s40517-023-00274-2

As main heat exchange channel in enhanced geothermal system, the evolution of hydraulic conductivity in fracture is significance for efficient heat mining. For the thermal stress or thermal cracking spontaneously induced by the temperature difference between low-temperature fluid and hot rock in heat mining stage, it is necessary to explore the damage mechanism along EGS fracture and the corresponding permeability evolution. Firstly, the long-term permeability tests under high temperature (50–200 ℃) were conducted by the self-developed high temperature seepage experimental device. Then, a coupled THM-D model was constructed to describe the damage distribution along fracture. Combined with experimental and simulation results, relationship between the thermal stress/cracking and the evolution of fracture permeability is revealed. The results indicate that during high-temperature (200 ℃) experiments, the fracture permeability first increases rapidly under the low-temperature induced thermal stress/cracking, then decreases due to the blockage effect induced by the debris particles generated in thermal cracking along fracture. The enhancement of injection velocity and heterogeneity are all conducive to the emergence of thermal cracking in matrix along fracture. Simultaneously, high confining pressure has a negative effect on the migration of debris particles of thermal cracking, which contribute to prevent the blockage of debris particles.