期刊
ROCK MECHANICS AND ROCK ENGINEERING
卷 54, 期 3, 页码 1109-1128出版社
SPRINGER WIEN
DOI: 10.1007/s00603-020-02311-z
关键词
Rock brittleness index; Characteristic stress; Confining pressure effects; Parameter sensitivity analysis; Deeply buried tunnel
资金
- National Science Foundation of China [U1765206, 41877256]
- Natural Science Basic Research Program of Shaanxi [2020JQ-999]
- Key Research Program of the Chinese Academy of Sciences [KFZD-SW-423]
A new brittleness index (BICSS) based on complete stress-strain curves of rocks was proposed in this study, which considers characteristic stresses and strains at different stages of rock failure. The BICSS not only quantifies and classifies brittleness characteristics of different rock types, but also comprehensively expresses the influences of various factors on rock brittleness. The stability and reliability of the BICSS were successfully verified through parameter sensitivity analysis and testing on metamorphic rocks.
Rock brittleness is an essential mechanical property, which plays a significant role in rock classifications and rockburst risk evaluations. To overcome the problems associated with the traditional brittleness indexes not comprehensively charaterizing the rock strength and deformation behaviors, this study systematically summarized the existing rock brittleness indexes. Then, a novel brittleness index (BICSS) based on the complete stress-strain curves of rock under different confining pressures was proposed. Its advantages included innovatively considering the characteristic stresses and strains at the stage of crack initiation, the peak points, and residual points. The index also described the stress growth rates from the pre-peak crack-initiation stress to the peak stress points, as well as the stress drop rates from the peak stress to the residual stress points. This study conducted uniaxial and triaxial compression tests of metamorphic sandstone, granite, and gneiss obtained from a deeply buried long-line tunnel group. The aforementioned tests were combined with wave velocity tests and thin-section identification tests using polarizing microscopy techniques. The reliability and applicability of the index were then successfully verified. The results showed that the BICSS could not only quantify and classify the brittleness characteristics of different rock types and characterize the confining pressure inhibition behaviors of rock brittleness, but could also comprehensively express the influences of homogeneity, mineral compositions, and particle sizes on the rock brittleness. Finally, through the parameter sensitivity analysis of the BICSS, the influences of subjective errors in the results of the cracking initiation stress and strain values caused by the different selections during the linear elastic phase could be successfully excluded, resulting in the further verification of the stability of the BICSS.
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