Journal
JOURNAL OF ROCK MECHANICS AND GEOTECHNICAL ENGINEERING
Volume 15, Issue 7, Pages 1636-1650Publisher
SCIENCE PRESS
DOI: 10.1016/j.jrmge.2022.10.009
Keywords
True triaxial compression; Cementation; Failure evolution; Acoustic emission (AE); High-speed camera
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The study investigates the effect of cementation and intermediate principal stress on the failure mechanism of clastic rock under true triaxial stress. The results show that the deformation and failure characteristics of clastic rock are closely related to the cementation type and intermediate principal stress. This study confirms the feasibility of high-speed camera technology in true triaxial testing and has important implications for understanding the disaster mechanism of deep tunnels in weak rocks.
The study of clastic rock failure evolution under true triaxial stress is an important research topic; however, it is rarely studied systematically due to the limitation of monitoring technology. In this study, true triaxial compression tests were conducted on clastic rock specimens to investigate the effect of cementation and intermediate principal stress (sigma(2)) on the failure mechanism. The complete stress-strain curves were obtained, while the acoustic emission (AE) was monitored to indirectly evaluate the evolution of tensile and shear cracks, and crack evolution under true triaxial compression was imaged in real time by a high-speed camera. The results showed that the deformation and failure characteristics of clastic rock were closely related to the cementation type and intermediate principal stress. On the basis of the distribution characteristics of the ratio of rise time to amplitude (RA) and the average frequency (AF) of AE signals, tensile cracks of the contact cementation specimen propagated preferentially. Meanwhile, the enhancement of specimen cementation promoted the evolution of shear cracks, and the increase in sigma(2) promoted the evolution of tensile cracks. Moreover, the mesoscale cracking mechanism of clastic rock caused by cementation and sigma(2) under true triaxial compression was analyzed. The failure patterns of clastic rock under true triaxial compression were divided into three modes: structur-induced, structure-stress-induced and stress-induced failures. This study confirms the feasibility of high-speed camera technology in true triaxial testing, and has important implications for elucidating the disaster mechanism of deep tunnels in weak rocks. (C) 2023 Institute of Rock and Soil Mechanics, Chinese Academy of Sciences. Production and hosting by Elsevier B.V. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
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