Fracture Process of Rock Containing a Hole Before and After Reinforcement: Experimental Test and Numerical Simulation

被引:0
|
作者
Zeng, Linhai [1 ,2 ]
Zhang, Futian [3 ]
Zhang, Daobing [1 ]
Zhang, Jiahua [4 ]
Yin, Huadong [2 ]
机构
[1] Sanya Institute, Hunan University of Science and Technology, Sanya,572024, China
[2] School of Resource Environment and Safety Engineering, Hunan University of Science and Technology, Xiangtan,411201, China
[3] China First Highway Engineering Co., Ltd., Ninth Engineering Co., Ltd., Guangzhou,511300, China
[4] Work Safety Key Lab on Prevention and Control of Gas and Roof Disasters for Southern Coal Mines, Hunan Provincial Key Laboratory of Safe Mining Techniques of Coal Mines, Hunan University of Science and Technology, Xiangtan,411201, China
来源
Buildings | 2024年 / 14卷 / 12期
关键词
A deeper understanding of the fracture evolution of hole-containing rocks is helpful for predicting the fracture of engineering rock mass. Based on this; uniaxial compression tests and two-dimensional numerical tests were conducted on red sandstone containing three different shapes of holes before and after reinforcement. The mechanical properties; stress field evolution; and AE energy and AE events during the sample fracture process were studied. The conclusions are that: (1) The reinforced specimens exhibited a significant increase in Young’s modulus and strength compared to the unreinforced specimens (containing a semicircular arch hole). (2) The sample always cracks from the loaded axial direction of the hole; presenting as tensile cracks. Subsequently; stress concentration at the corners of the hole results in shear cracks. Finally; the cracks gradually expand and merge with the holes; there are obvious macroscopic cracks and fracture surfaces on the sample surface; which proves that the sample has been fractured. (3) The reinforcement of the hole-containing sandstone can effectively inhibit the expansion of cracks in the rock. (4) When the stress on the specimen is less than its peak stress; the accumulation of the AE energy and AE events in the reinforced sample are greater than those in the unreinforced sample. The specimen experiences more intense compression-induced fracturing and has a stronger load-bearing capacity. © 2024 by the authors;
D O I
10.3390/buildings14123864
中图分类号
学科分类号
摘要
引用
收藏
相关论文
共 50 条
  • [41] Numerical Simulation on Creep Process of Surrounding Rock in Soft Rock Tunnel
    Fan, Qiu-yan
    Liang, Xin
    Tang, Feng
    INTERNATIONAL CONFERENCE ON MATERIAL SCIENCE AND CIVIL ENGINEERING, MSCE 2016, 2016, : 501 - 512
  • [42] Experimental and numerical analysis of fracture process in concrete
    Schalangen, E.
    Heron, 1993, 38 (02): : 1 - 17
  • [43] Numerical simulation of grouting process in rock mass with rough fracture network based on corrected cubic law
    Cui Wei
    Wang Li-xin
    Jiang Zhi-an
    Wang Chao
    Wang Xiao-hua
    Zhang She-rong
    ROCK AND SOIL MECHANICS, 2021, 42 (08) : 2250 - 2258
  • [44] Development and Application of Rock Fracture Propagation Numerical Simulation System
    Wang, Hui
    Zhou, Hang
    Shang, Shichang
    Jiang, Cheng
    GEOTECHNICAL AND GEOLOGICAL ENGINEERING, 2022, 40 (06) : 3075 - 3090
  • [45] Numerical simulation for the development of rock fracture area in dynamic indentation
    Duan, Lezhen
    Xu, Guoyuan
    Zhu, Chengzhong
    Zhongnan Gongye Daxue Xuebao/Journal of Central South University of Technology, 29 (05): : 425 - 428
  • [46] Numerical simulation of the rock fracture process induced by multi-disc-cutters and cutter spacing design
    Li, Z. (lizhen@dlut.edu.cn), 1600, Editorial Board of Journal of Harbin Engineering (33):
  • [47] Numerical simulation of fracture propagation of rock under uniaxial tension
    Zhang, De-Hai
    Zhu, Fu-Sheng
    Xing, Ji-Bo
    Yantu Gongcheng Xuebao/Chinese Journal of Geotechnical Engineering, 2005, 27 (09): : 1008 - 1011
  • [48] Development and Application of Rock Fracture Propagation Numerical Simulation System
    Hui Wang
    Hang Zhou
    Shichang Shang
    Cheng Jiang
    Geotechnical and Geological Engineering, 2022, 40 : 3075 - 3090
  • [49] Numerical simulation of creep fracture evolution in fractured rock masses
    Na, Zhao
    Lixin, Meng
    Laigui, Wang
    Yibin, Zhang
    FRONTIERS IN EARTH SCIENCE, 2022, 10
  • [50] Numerical simulation of dynamic fracture and damage of rock during impact
    Rossmanith, HP
    Mishnaevsky, L
    Knasmillner, RE
    Uenishi, K
    NUMERICAL METHODS IN ENGINEERING SIMULATION, 1996, : 147 - 154
12345