Gas Fracturing Simulation of Shale-Gas Reservoirs Considering Damage Effects and Fluid–Solid Coupling

With the increasing demand for energy and the depletion of traditional resources, the development of alternative energy sources has become a critical issue. Shale gas, as an abundant and widely distributed resource, has great potential as a substitute for conventional natural gas. However, due to th...

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Bibliographic Details
Published inWater (Basel) Vol. 16; no. 9; p. 1278
Main Authors Qi, Enze, Xiong, Fei, Zhang, Yun, Wang, Linchao, Xue, Yi, Fu, Yingpeng
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.05.2024
Subjects
Acoustic emission testing
Alternative energy
Analysis
Coal
Deformation
Fluid dynamics
fluid–solid interaction
Fractures (Geology)
Hydraulic fracturing
Influence
Investigations
Natural gas
Natural gas reserves
Nitrogen
Numerical analysis
Oil reserves
Oil wells
Permeability
Rock mechanics
Rocks
shale gas
Shale oils
Simulation methods
Technology application
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Summary:With the increasing demand for energy and the depletion of traditional resources, the development of alternative energy sources has become a critical issue. Shale gas, as an abundant and widely distributed resource, has great potential as a substitute for conventional natural gas. However, due to the low permeability of shale-gas reservoirs, efficient extraction poses significant challenges. The application of hydraulic fracturing technology has been proven to effectively enhance rock permeability, but the influence of environmental factors on its efficiency remains unclear. In this study, we investigate the impact of gas fracturing on shale-gas extraction efficiency under varying environmental conditions using numerical simulations. Our simulations provide a comprehensive analysis of the physical changes that occur during the fracturing process, allowing us to evaluate the effects of gas fracturing on rock mechanics and permeability. We find that gas fracturing can effectively induce internal fractures within the rock, and the magnitude of tensile stress decreases gradually during the process. The boundary pressure of the rock mass is an important factor affecting the effectiveness of gas fracturing, as it exhibits an inverse relationship with the gas content present within the rock specimen. Furthermore, the VL constant demonstrates a direct correlation with gas content, while the permeability and PL constant exhibit an inverse relationship with it. Our simulation results provide insights into the optimization of gas fracturing technology under different geological parameter conditions, offering significant guidance for its practical applications.
ISSN:2073-4441
2073-4441
DOI:10.3390/w16091278