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A platform for research: civil engineering, architecture and urbanism
Failure mechanism of rock masses with complex geological conditions in a large underground cavern: A case study
https://orcid.org/0000-0002-3391-5608
Abstract Reasonable and accurate identification of the failure mechanism of rock masses is of great significance for achieving a comprehensive and thorough understanding of the fracture process in underground caverns under high geostress. Sophisticated microseismic (MS) monitoring was established in underground cavern groups to capture the excavation-induced microfracture signals of intact rock masses and rock masses with weak interlayer zones (WIZs). To clarify the mechanical mechanisms controlling the surrounding rock failure modes, the moment tensor inversion method is adopted to fully reveal the fracture types and focal mechanism solutions (strike, dip and rake) of the rock masses. The spatial distribution of the MS events shows that the excavation-induced microfractures of intact rock masses are concentrated in the working face of underground intersecting chambers. The fracture mechanisms of intact rock masses are dominated by tensile fracturing. Compared with those in intact rock masses, the microfractures induced by excavation in rock masses with WIZ form a strip-like cluster area along the WIZ, and the proportion of shear fractures is significantly higher. The moment tensor method quantitatively reveals the failure mechanism of excavation-induced microseismicity of rock masses with complex geological conditions.
Highlights A microseismic monitoring system was established in the Baihetan Hydropower Station. The microfractures of intact rocks and rock masses with weak interlayer zones were studied using moment tensors. The fracture mechanisms of tensile, mixed and shear fracture were revealed by moment tensor inversion.
Failure mechanism of rock masses with complex geological conditions in a large underground cavern: A case study
https://orcid.org/0000-0002-3391-5608
Abstract Reasonable and accurate identification of the failure mechanism of rock masses is of great significance for achieving a comprehensive and thorough understanding of the fracture process in underground caverns under high geostress. Sophisticated microseismic (MS) monitoring was established in underground cavern groups to capture the excavation-induced microfracture signals of intact rock masses and rock masses with weak interlayer zones (WIZs). To clarify the mechanical mechanisms controlling the surrounding rock failure modes, the moment tensor inversion method is adopted to fully reveal the fracture types and focal mechanism solutions (strike, dip and rake) of the rock masses. The spatial distribution of the MS events shows that the excavation-induced microfractures of intact rock masses are concentrated in the working face of underground intersecting chambers. The fracture mechanisms of intact rock masses are dominated by tensile fracturing. Compared with those in intact rock masses, the microfractures induced by excavation in rock masses with WIZ form a strip-like cluster area along the WIZ, and the proportion of shear fractures is significantly higher. The moment tensor method quantitatively reveals the failure mechanism of excavation-induced microseismicity of rock masses with complex geological conditions.
Highlights A microseismic monitoring system was established in the Baihetan Hydropower Station. The microfractures of intact rocks and rock masses with weak interlayer zones were studied using moment tensors. The fracture mechanisms of tensile, mixed and shear fracture were revealed by moment tensor inversion.
Failure mechanism of rock masses with complex geological conditions in a large underground cavern: A case study
https://orcid.org/0000-0002-3391-5608
Abstract Reasonable and accurate identification of the failure mechanism of rock masses is of great significance for achieving a comprehensive and thorough understanding of the fracture process in underground caverns under high geostress. Sophisticated microseismic (MS) monitoring was established in underground cavern groups to capture the excavation-induced microfracture signals of intact rock masses and rock masses with weak interlayer zones (WIZs). To clarify the mechanical mechanisms controlling the surrounding rock failure modes, the moment tensor inversion method is adopted to fully reveal the fracture types and focal mechanism solutions (strike, dip and rake) of the rock masses. The spatial distribution of the MS events shows that the excavation-induced microfractures of intact rock masses are concentrated in the working face of underground intersecting chambers. The fracture mechanisms of intact rock masses are dominated by tensile fracturing. Compared with those in intact rock masses, the microfractures induced by excavation in rock masses with WIZ form a strip-like cluster area along the WIZ, and the proportion of shear fractures is significantly higher. The moment tensor method quantitatively reveals the failure mechanism of excavation-induced microseismicity of rock masses with complex geological conditions.
Highlights A microseismic monitoring system was established in the Baihetan Hydropower Station. The microfractures of intact rocks and rock masses with weak interlayer zones were studied using moment tensors. The fracture mechanisms of tensile, mixed and shear fracture were revealed by moment tensor inversion.
Failure mechanism of rock masses with complex geological conditions in a large underground cavern: A case study
Zhao, Jin-Shuai (author) / Duan, Shu-Qian (author) / Chen, Bing-Rui (author) / Li, Lei (author) / He, Ben-Guo (author) / Li, Peng-Xiang (author) / Liu, Guo-Feng (author)
2023-12-25
Article (Journal)
Electronic Resource
English
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