Research on meso-scale deformation and failure mechanism of fractured rock mass subject to biaxial compression

Fractured rock masses possess defects that are extensively developed in nature. Studying the deformation and instability process of fractured rock masses is of great significance for an in-depth understanding of the deformation process and instability modes of slopes with fractured rock masses. In t...

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Published in	Arabian journal of geosciences Vol. 14; no. 14
Main Authors	Xiaoming, Wang, Yuanjie, Xiao, Wenbing, Shi, Juanjuan, Ren, Zhengxing, Chang, Hua, Li
Format	Journal Article
Language	English
Published	Cham Springer International Publishing 01.07.2021 Springer Nature B.V
Subjects	Adhesion Bonding Coalescence Coalescing Compression Confining Crack propagation Defects Deformation Design parameters Discrete element method Distribution Ductility Earth and Environmental Science Earth science Earth Sciences Failure mechanisms Failure modes Fracture surfaces Instability Mechanical properties Mesoscale phenomena Original Paper Parameters Public transportation Rock masses Rocks Slope stability Statistical methods Statistical tests Strain Stress-strain curves Stress-strain relations Stress-strain relationships Surveying Triaxial compression tests Weights & measures Fractured rock mass Deformation failure mechanism Random fracture Discrete element method Bonded fracture surface
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Abstract	Fractured rock masses possess defects that are extensively developed in nature. Studying the deformation and instability process of fractured rock masses is of great significance for an in-depth understanding of the deformation process and instability modes of slopes with fractured rock masses. In this paper, through field survey of fracture distribution statistics and laboratory triaxial compression tests on field-cored rock specimens, the fracture distribution parameters and the basic physical and mechanical parameters of the rock mass were obtained, and a discrete element model of the fractured rock mass based on the representative element volume (REV) size was developed. The meso-scale deformation and failure characteristics of fractured rock masses under different levels of confining pressure were studied. The results show that the deformation process of fractured rock can be divided into fracture closure stage, quasi-elastic stage, unstable stage of new crack initiations, new crack propagation stage, and fracture crack coalescence stage. As the confining pressure increases, the lateral deformation of the fractured rock mass was impeded, and the overall ductility and strength were improved. Further, the failure mode of the fractured rock mass transitioned from overall tensile failure to shear failure, while new cracks were mainly initiated during the quasi-elastic stage of the stress-strain curve due to the bonding failure of the original fracture surface. In essence, the deformation and failure of fractured rock mass are attributable to the initial bonding failure of the original fracture surface, followed by the failure of the rock mass and the subsequent overall instability of the fractured rock mass. From a mesoscopic perspective, the stress-strain response of a fractured rock mass is the macroscopic manifestation of the evolving interaction between internal normal and tangential stress components. The fabric evolution of the fractured rock mass during the deformation process corresponds to distinct deformation stages. The deformation and failure characteristics of the fractured rock mass resemble and indicate those of the slope, and the design parameters of the slope can be calibrated from those of the fractured rock mass. The findings of this paper are of theoretical and practical significance to better understand the deformation and instability process of slopes with fractured rock masses and obtain design parameters of slope stability.
AbstractList	Fractured rock masses possess defects that are extensively developed in nature. Studying the deformation and instability process of fractured rock masses is of great significance for an in-depth understanding of the deformation process and instability modes of slopes with fractured rock masses. In this paper, through field survey of fracture distribution statistics and laboratory triaxial compression tests on field-cored rock specimens, the fracture distribution parameters and the basic physical and mechanical parameters of the rock mass were obtained, and a discrete element model of the fractured rock mass based on the representative element volume (REV) size was developed. The meso-scale deformation and failure characteristics of fractured rock masses under different levels of confining pressure were studied. The results show that the deformation process of fractured rock can be divided into fracture closure stage, quasi-elastic stage, unstable stage of new crack initiations, new crack propagation stage, and fracture crack coalescence stage. As the confining pressure increases, the lateral deformation of the fractured rock mass was impeded, and the overall ductility and strength were improved. Further, the failure mode of the fractured rock mass transitioned from overall tensile failure to shear failure, while new cracks were mainly initiated during the quasi-elastic stage of the stress-strain curve due to the bonding failure of the original fracture surface. In essence, the deformation and failure of fractured rock mass are attributable to the initial bonding failure of the original fracture surface, followed by the failure of the rock mass and the subsequent overall instability of the fractured rock mass. From a mesoscopic perspective, the stress-strain response of a fractured rock mass is the macroscopic manifestation of the evolving interaction between internal normal and tangential stress components. The fabric evolution of the fractured rock mass during the deformation process corresponds to distinct deformation stages. The deformation and failure characteristics of the fractured rock mass resemble and indicate those of the slope, and the design parameters of the slope can be calibrated from those of the fractured rock mass. The findings of this paper are of theoretical and practical significance to better understand the deformation and instability process of slopes with fractured rock masses and obtain design parameters of slope stability.
ArticleNumber	1390
Author	Wenbing, Shi Zhengxing, Chang Xiaoming, Wang Juanjuan, Ren Yuanjie, Xiao Hua, Li
Author_xml	– sequence: 1 givenname: Wang surname: Xiaoming fullname: Xiaoming, Wang organization: School of Civil Engineering, Central South University, Key Laboratory of Karst Geological Resources and Environment, Ministry of Education, Guizhou University – sequence: 2 givenname: Xiao surname: Yuanjie fullname: Yuanjie, Xiao organization: School of Civil Engineering, Central South University, Key Laboratory of Engineering Structure of Heavy Railway, Central South University – sequence: 3 givenname: Shi surname: Wenbing fullname: Wenbing, Shi email: wbshi@gzu.edu.cn organization: Key Laboratory of Karst Geological Resources and Environment, Ministry of Education, Guizhou University, School of Resources and Environmental Engineering, Guizhou University – sequence: 4 givenname: Ren surname: Juanjuan fullname: Juanjuan, Ren organization: School of Civil Engineering, Southwest Jiaotong University – sequence: 5 givenname: Chang surname: Zhengxing fullname: Zhengxing, Chang organization: School of Civil Engineering, Central South University – sequence: 6 givenname: Li surname: Hua fullname: Hua, Li organization: School of Resources and Environmental Engineering, Guizhou University
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Snippet	Fractured rock masses possess defects that are extensively developed in nature. Studying the deformation and instability process of fractured rock masses is of...
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SubjectTerms	Adhesion Bonding Coalescence Coalescing Compression Confining Crack propagation Defects Deformation Design parameters Discrete element method Distribution Ductility Earth and Environmental Science Earth science Earth Sciences Failure mechanisms Failure modes Fracture surfaces Instability Mechanical properties Mesoscale phenomena Original Paper Parameters Public transportation Rock masses Rocks Slope stability Statistical methods Statistical tests Strain Stress-strain curves Stress-strain relations Stress-strain relationships Surveying Triaxial compression tests Weights & measures
Title	Research on meso-scale deformation and failure mechanism of fractured rock mass subject to biaxial compression
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