Rock and Soil Mechanics ›› 2021, Vol. 42 ›› Issue (11): 3041-3050.doi: 10.16285/j.rsm.2021.0275

• Fundamental Theroy and Experimental Research • Previous Articles     Next Articles

Time-lag uniaxial compression failure characteristics of sandstone under different stress levels

XU Peng-fei1, DENG Hua-feng1, ZHANG Heng-bin1, PENG Meng1, LI Guan-ye1, JIANG Qiao2, CHEN Xing-zhou3   

  1. 1. Key Laboratory of Geological Hazards on Three Gorges Reservoir Area, Ministry of Education, China Three Gorges University, Yichang, Hubei 443002, China; 2. Wudongde Engineering Construction Department of China Three Gorges Construction Management Co., Ltd., Chengdu, Sichuan 610000, China; 3. College of Architecture and Civil Engineering, Xi’an University of Science and Technology, Xi’an, Shaanxi 710054, China
  • Received:2021-02-22 Revised:2021-07-12 Online:2021-11-11 Published:2021-11-12
  • Supported by:
    This work was supported the National Nature Science foundation of China (U2034203, 51979218) and the Research Fund for Excellent Dissertation of China Three Gorges University 2019 Master's Degree Thesis(2021SSPY020).

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Abstract: Rockburst caused by underground engineering excavation has obvious time-lag effect. Previous research shows that the occurrence of hysteresis rockburst is closely related to the time-lag damage of the rock. Based on this, considering that the surrounding rock is at different stress levels after excavation, the time-delay uniaxial compression test is carried out to analyze the time-delay deformation and failure characteristics of rocks under different stress levels. The results show that the stress level has a significant impact on the time-delay deformation and failure of rocks. As the stress level increases, the failure incubation time decreases exponentially, but it is much longer than that of conventional uniaxial compression failure. In the case of delayed uniaxial compression failure, the hoop strain and volume strain of the rock sample are significantly greater than that of conventional uniaxial compression test, and when the stress level is lower than 90%, the hoop strain at failure rapidly increases and exceeds the axial strain, which is also the distinguishing feature of time-lag failure and conventional uniaxial compression failure. The total energy of delayed uniaxial compression failure is equivalent to that of conventional uniaxial compression, but the proportion of dissipated energy increases significantly in the process of delayed loading, indicating that the delayed loading stage will lead to the significant development of damage in the rock. The rapid growth of circumferential strain of rock samples in the stage of time-delay loading leads to the significant increase of near axial splitting tensile failure cracks, which also leads to the more serious fragmentation of rock samples. The relevant research results can provide a good reference for the analysis and interpretation of time-dependent and time-lag rockburst of rock damage and failure under high stress level.

Key words: time lag, stress level, deformation characteristics, dissipated energy, failure mode

CLC Number: 

  • TU 451
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[2] LIANG Gui-lan, XU Wei-ya, TAN Xiao-long. Application of extension theory based on entropy weight to rock quality evaluation[J]. , 2010, 31(2): 535 -540 .
[3] MA Wen-tao. Forecasting slope displacements based on grey least square support vector machines[J]. , 2010, 31(5): 1670 -1674 .
[4] YU Lin-lin,XU Xue-yan,QIU Ming-guo, LI Peng-fei,YAN Zi-li. Influnce of freeze-thaw on shear strength properties of saturated silty clay[J]. , 2010, 31(8): 2448 -2452 .
[5] WANG Wei, LIU Bi-deng, ZHOU Zheng-hua, WANG Yu-shi, ZHAO Ji-sheng. Equivalent linear method considering frequency dependent stiffness and damping[J]. , 2010, 31(12): 3928 -3933 .
[6] WANG Hai-bo,XU Ming,SONG Er-xiang. A small strain constitutive model based on hardening soil model[J]. , 2011, 32(1): 39 -43 .
[7] CAO Guang-xu, SONG Er-xiang, XU Ming. Simplified calculation methods of post-construction settlement of high-fill foundation in mountain airport[J]. , 2011, 32(S1): 1 -5 .
[8] LIU Hua-li , ZHU Da-yong , QIAN Qi-hu , LI Hong-wei. Analysis of three-dimensional end effects of slopes[J]. , 2011, 32(6): 1905 -1909 .
[9] LIU Nian-ping , WANG Hong-tu , YUAN Zhi-gang , LIU Jing-cheng. Fisher discriminant analysis model of sand liquefaction and its application[J]. , 2012, 33(2): 554 -557 .
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