Effects of hole shape on mechanical behavior and fracturing mechanism of rock: Implications for instability of underground openings

Cai, Xin; Yuan, Jifeng; Zhou, Zilong; Pi, Zizi; Tan, Lihai; Wang, Peiyu; Wang, Shanyong; Wang, Shaofeng

Title: Effects of hole shape on mechanical behavior and fracturing mechanism of rock: Implications for instability of underground openings
Creator: Cai, Xin; Yuan, Jifeng; Zhou, Zilong; Pi, Zizi; Tan, Lihai; Wang, Peiyu; Wang, Shanyong; Wang, Shaofeng
Relation: Tunnelling and Underground Space Technology Vol. 141, no. 105361
Publisher Link: http://dx.doi.org/10.1016/j.tust.2023.105361
Publisher: Elsevier
Resource Type: journal article
Date: 2023
Description: Rock failure commonly initiates near the wall of openings with various geometries in underground excavation. In this study, to elucidate the hole-shape influences on the mechanical response and fracturing behavior on rock sample subjected to uniaxial compression, a thorough experimental–numerical-theoretical investigation is conducted on the intact and pre-holed rock samples with different hole shapes, including circular, elliptical, rectangular, and inverted-U shapes. Digital image correlation technology is employed to monitor the crack initiation and development around the hole during the loading process. The results show that the presence of different hole shapes leads to varying degrees of mechanical property deterioration in rock samples. The load capacity and stiffness of the tested samples follow the same order: intact sample > circular-holed sample > elliptical-holed sample > inverted-U holed sample > square-holed sample. Irrespective of the hole shape, the primary tensile crack initiates at the top and bottom of the hole, but its development is trapped. The growth and coalescence of shear cracks near the sidewalls eventually give rise to the sample failure. Stress analysis around the holes reveals a positive dependence of the reduction in load capacity on the maximum compressive stress concentration which is controlled by the shape of the hole. This indicates that the amplification of compressive stress induced by the hole governs the rock collapse. These findings offer valuable insights for the design and construction of underground engineering projects.
Subject: rock failure; uniaxial compression; hole shape effect; fracture evolution; digital image correlation; underground excavation
Identifier: http://hdl.handle.net/1959.13/1497561
Identifier: uon:54390
Identifier: ISSN:0886-7798
Language: eng
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