Strength, deformation and failure behavior of bolted rock-like specimen with multiple cracks under uniaxial compression by particle flow simulation

Strength, deformation and failure behavior of bolted rock-like specimen with multiple cracks under uniaxial compression by particle flow simulation

Most of the rock mass in nature contains a large number of joints, faults and other defects, which make the rock mass have the characteristics of discontinuity and anisotropy, and easily lead to instability and failure of rock engineering. A great quantity of engineering practices show that the bolt...

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Bibliographic Details
Published in:Geosciences journal (Seoul, Korea) Vol. 27; no. 6; pp. 781 - 799
Main Authors: Yang, Wendong, Li, Yiwei, Wang, Ling, Zhang, Kaicheng, Gong, Zhicheng
Format: Journal Article
Language:English
Published: Seoul The Geological Society of Korea 01-12-2023
Springer Nature B.V
Subjects:
Anisotropy
Bolted joints
Compression
Crack arrest
Crack initiation
Cracks
Defects
Deformation
Earth and Environmental Science
Earth Sciences
Failure modes
Flow simulation
Jointed rock
Laboratory tests
Mathematical models
Mechanical properties
Microcracks
Numerical models
Rock
Rock masses
Rocks
Safety engineering
Sediment samples
Three dimensional flow
crack arrest effect of bolt
non-persistent joints
bolt
micro-crack evolution process
mechanical properties
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Summary:Most of the rock mass in nature contains a large number of joints, faults and other defects, which make the rock mass have the characteristics of discontinuity and anisotropy, and easily lead to instability and failure of rock engineering. A great quantity of engineering practices show that the bolt has a significant supporting effect on jointed rock mass. Therefore, it is of great significance to study the deformation and failure characteristics of jointed rock mass and the crack arrest effect of bolt for the safety and stability of engineering. A reasonable numerical model of bolted rock samples with non-persistent joints is established by using a three-dimensional Particle Flow Code (PFC) based on the laboratory rock specimens, and the uniaxial compression numerical test is carried out. The results indicate that (1) the numerical simulation results are in good agreement with the laboratory test results, and the variation trend of strength is basically consistent; (2) the different joint angles and anchorage angles result in variations in the mechanical properties of bolted specimens with non-persistent joints; (3) the joint angle has a significant effect on the failure mode of the specimen; (4) the existence of bolts can effectively limit the initiation and propagation process of micro-cracks, and greatly improve the mechanical properties of the specimen containing non-persistent joints.
ISSN:1226-4806
1598-7477
DOI:10.1007/s12303-023-0026-5