Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element Model

Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element Model

Granite exhibits obvious meso-geometric heterogeneity. To study the influence of grain size and preferred grain orientation on the damage evolution and mechanical properties of granite, as well as to reveal the inner link between grain size‚ preferred orientation, uniaxial tensile strength (UTS) and...

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Main Authors: Shirui Zhang, Shili Qiu, Pengfei Kou, Shaojun Li, Ping Li, Siquan Yan
Format: Article
Language:English
Published: MDPI AG 2021-07-01
Series:Materials
Subjects:
combined finite-discrete element method
grain-based model
Beishan granite
grain scale effect
grain orientation effect
Online Access:https://www.mdpi.com/1996-1944/14/14/3969
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spelling doaj-5644e6738d9c4f17ba8ff6ad4f08d8952021-07-23T13:51:53ZengMDPI AGMaterials1996-19442021-07-01143969396910.3390/ma14143969Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element ModelShirui Zhang0Shili Qiu1Pengfei Kou2Shaojun Li3Ping Li4Siquan Yan5State Key Laboratory of Geomechanics and Geotechnical Engineering, Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, Wuhan 430071, ChinaState Key Laboratory of Geomechanics and Geotechnical Engineering, Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, Wuhan 430071, ChinaNo.2 Mining Area, Jinchuan Group Co., Ltd., Jinchang 737100, ChinaState Key Laboratory of Geomechanics and Geotechnical Engineering, Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, Wuhan 430071, ChinaCollege of Resources and Environmental Science, South-Central University for Nationalities, Wuhan 430074, ChinaYellow River Engineering Consulting Co., Ltd., Zhengzhou 450000, ChinaGranite exhibits obvious meso-geometric heterogeneity. To study the influence of grain size and preferred grain orientation on the damage evolution and mechanical properties of granite, as well as to reveal the inner link between grain size‚ preferred orientation, uniaxial tensile strength (UTS) and damage evolution, a series of Brazilian splitting tests were carried out based on the combined finite-discrete element method (FDEM), grain-based model (GBM) and inverse Monte Carlo (IMC) algorithm. The main conclusions are as follows: (1) Mineral grain significantly influences the crack propagation paths, and the GBM can capture the location of fracture section more accurately than the conventional model. (2) Shear cracks occur near the loading area, while tensile and tensile-shear mixed cracks occur far from the loading area. The applied stress must overcome the tensile strength of the grain interface contacts. (3) The UTS and the ratio of the number of intergrain tensile cracks to the number of intragrain tensile cracks are negatively related to the grain size. (4) With the increase of the preferred grain orientation, the UTS presents a “V-shaped” characteristic distribution. (5) During the whole process of splitting simulation, shear microcracks play the dominant role in energy release; particularly, they occur in later stage. This novel framework, which can reveal the control mechanism of brittle rock heterogeneity on continuous-discontinuous trans-scale fracture process and microscopic rock behaviour, provides an effective technology and numerical analysis method for characterizing rock meso-structure. Accordingly, the research results can provide a useful reference for the prediction of heterogeneous rock mechanical properties and the stability control of engineering rock masses.https://www.mdpi.com/1996-1944/14/14/3969combined finite-discrete element methodgrain-based modelBeishan granitegrain scale effectgrain orientation effect
collection DOAJ
language English
format Article
sources DOAJ
author Shirui Zhang
Shili Qiu
Pengfei Kou
Shaojun Li
Ping Li
Siquan Yan
spellingShingle Shirui Zhang
Shili Qiu
Pengfei Kou
Shaojun Li
Ping Li
Siquan Yan
Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element Model
Materials
combined finite-discrete element method
grain-based model
Beishan granite
grain scale effect
grain orientation effect
author_facet Shirui Zhang
Shili Qiu
Pengfei Kou
Shaojun Li
Ping Li
Siquan Yan
author_sort Shirui Zhang
title Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element Model
title_short Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element Model
title_full Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element Model
title_fullStr Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element Model
title_full_unstemmed Investigation of Damage Evolution in Heterogeneous Rock Based on the Grain-Based Finite-Discrete Element Model
title_sort investigation of damage evolution in heterogeneous rock based on the grain-based finite-discrete element model
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2021-07-01
description Granite exhibits obvious meso-geometric heterogeneity. To study the influence of grain size and preferred grain orientation on the damage evolution and mechanical properties of granite, as well as to reveal the inner link between grain size‚ preferred orientation, uniaxial tensile strength (UTS) and damage evolution, a series of Brazilian splitting tests were carried out based on the combined finite-discrete element method (FDEM), grain-based model (GBM) and inverse Monte Carlo (IMC) algorithm. The main conclusions are as follows: (1) Mineral grain significantly influences the crack propagation paths, and the GBM can capture the location of fracture section more accurately than the conventional model. (2) Shear cracks occur near the loading area, while tensile and tensile-shear mixed cracks occur far from the loading area. The applied stress must overcome the tensile strength of the grain interface contacts. (3) The UTS and the ratio of the number of intergrain tensile cracks to the number of intragrain tensile cracks are negatively related to the grain size. (4) With the increase of the preferred grain orientation, the UTS presents a “V-shaped” characteristic distribution. (5) During the whole process of splitting simulation, shear microcracks play the dominant role in energy release; particularly, they occur in later stage. This novel framework, which can reveal the control mechanism of brittle rock heterogeneity on continuous-discontinuous trans-scale fracture process and microscopic rock behaviour, provides an effective technology and numerical analysis method for characterizing rock meso-structure. Accordingly, the research results can provide a useful reference for the prediction of heterogeneous rock mechanical properties and the stability control of engineering rock masses.
topic combined finite-discrete element method
grain-based model
Beishan granite
grain scale effect
grain orientation effect
url https://www.mdpi.com/1996-1944/14/14/3969
work_keys_str_mv AT shiruizhang investigationofdamageevolutioninheterogeneousrockbasedonthegrainbasedfinitediscreteelementmodel
AT shiliqiu investigationofdamageevolutioninheterogeneousrockbasedonthegrainbasedfinitediscreteelementmodel
AT pengfeikou investigationofdamageevolutioninheterogeneousrockbasedonthegrainbasedfinitediscreteelementmodel
AT shaojunli investigationofdamageevolutioninheterogeneousrockbasedonthegrainbasedfinitediscreteelementmodel
AT pingli investigationofdamageevolutioninheterogeneousrockbasedonthegrainbasedfinitediscreteelementmodel
AT siquanyan investigationofdamageevolutioninheterogeneousrockbasedonthegrainbasedfinitediscreteelementmodel
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