Gold Science and Technology
img

Wechat

Adv. Search
Online Submission Peer Review Office Work

Gold Science and Technology ›› 2022, Vol. 30 ›› Issue (4): 559-573.doi: 10.11872/j.issn.1005-2518.2022.04.181

• Mining Technology and Mine Management • Previous Articles     Next Articles

Study on Thermal Sensitivity and Crack Propagation of Granite Based on Discrete Element Method

Mingjian LI(),Tubing YIN(),Xiaosong TAN,Zheng YANG   

  1. School of Resources and Safety Engineering,Central South University,Changsha 410083,Hunan,China
  • Received:2021-11-26 Revised:2022-04-11 Online:2022-08-31 Published:2022-10-31
  • Contact: Tubing YIN E-mail:limingjian@csu.edu.cn;tubing_yin@mail.csu.edu.cn

RichHTML

3

PDF (PC)

290

Abstract:

Under a certain stress state,the thermal induced stress field and the initial stress field are superimposed,resulting in the initiation of new thermal cracks on the basis of the original cracks,which affects the mechanical properties of the rock.However,the effect of thermal stress field can also be applied to rock crushing.It is necessary to study the fracture caused by thermal and mechanical action of rock.Due to the limited monitoring technology of the experiment under high temperature,the relevant research is difficult to carry out.Using the method of combining experiment and simulation,based on the experiment and the discrete element method,the cracking process caused by heat and force of prefabricated crack model with different inclination angles was studied under different initial stress states. The relevant thermal eigenvalues were analyzed,and the propagation path of thermal crack was theoretically analyzed according to the Det.(σij) fracture criterion and the evolution process of the second invariant in the heating process.The results show that under the high stress state,the thermal sensitivity is strong (the crack initiation temperature is low,the crack propagation temperature range is in the front,and the crack propagation process is intense),the peak temperature is low,but the peak thermal stress is high.Prefabricated cracks with different angles will also affect the relevant thermal eigenvalues. Under the same initial stress state,with the increase of prefabricated crack angle,the thermal sensitivity de-creases.Moreover,the peak temperature has a similar law.When the crack initiation state is reached,the thermal crack first forms at the tip of the prefabricated crack.With the increase of temperature,the distribution of the second invariant of stress changes,and the thermal crack will expand at the maximum of the second invariant.The research results have certain reference significance for deep thermal rock breaking and rock engineering stability.

Key words: cracking due to thermal and stress, PFC, thermal eigenvalue, thermal sensitivity, crack propagation, second invariant of stress, discrete element method

CLC Number: 

  • TD313

Fig.1

Composition analysis of granite"

Fig.2

INSTRON 1346 test machine and data acquisition system"

Table 1

Mechanical parameters of uniaxial compression"

温度/℃峰值强度/MPa峰值应变/%弹性模量/GPa
201240.5431.22
1001210.5530.03
2001140.5927.96
3001050.6623.27
400960.6821.11

Fig.3

Two-dimensional discrete element representation model"

Table 2

Microscopic parameters of model structure"

岩石组分占比/%颗粒半径/mm热膨胀系数/(K-1导热系数/(W·m-1·K-1比热/(J·kg-1·K-1密度/(kg·m-3
石英40.90.40~0.5524.3×10-6
长石38.40.30~0.408.7×10-63.51 0152 700
云母20.70.30~0.403.0×10-6

Table 3

Bonding parameters of the model"

参数数值
k154.3
k2129
b0.572
emod20.7e9
pb_emod24.3e9
kratio2.6
pb_ten11.7e7
pb_coh6.50e7

Fig.4

Stress-strain curves of test loading"

Fig.5

Stress-strain curves of simulated loading"

Fig.6

Comparison of experimental results with simulated failure modes"

Fig.7

Schematic diagram of discrete element model"

Fig.8

Relationship diagram of number of crack initiation events and temperature of the model(α=45°)"

Fig.9

Temperature-stress curves(α=45°) of model with 45° prefabricated flaws"

Table 4

Thermal characteristic value of 45 ° prefabricated crack"

初始轴向

应力/MPa

起裂温度/℃

扩展温度

区间/℃

峰值温度/℃

峰值热

应力/MPa

20216-40082
40122300~40035289
6022250~35026792
8020150~25014095

Fig.10

Variation of crack initiation temperature"

Fig.11

Peak temperature variation"

Fig.12

Variation of peak thermal stress"

Fig.13

Relationship diagram of number of crack initiation events and temperature of the model"

Fig.14

Thermal characteristic values of the model"

Fig.15

Types of macroscopic cracks"

Fig.16

Crack propagation modes of prefabricated crack models with 30°,45° and 60° under different initial stress states"

Fig.17

Final crack propagation mode of thermal cracking"

Fig.18

Evolution diagram of the second invariant"

Diederichs M S, Kaiser P K, Eberhardt E,2004. Damage initiation and propagation in hard rock during tunnelling and the influence of near-face stress rotation [J].International Journal of Rock Mechanics and Mining Sciences,41(5):785-812.
Eberhardt E, Stead D, Stimpson B,et al,1998. Identifying crack initiation and propagation thresholds in brittle rock [J].Canadian Geotechnical Journal,35(2):222-233.
Fairhurst C E, Hudson J,1999.Draft ISRM suggested method for the complete stress-strain curve for intact rock in uniaxial compression[J].International Journal of Rock Mechanics and Mining Science & Geomechanics Abstracts,36(3):281-289.
Fei Y W,1995.Thermal expansion[C]//Mineral physics and crystallography:A handbook of physical constants,AGU Reference Shelf 2.Washington:The American Geophysical Union,2:29-44.
Guo Qifeng, Wu Xu, Cai Meifeng,et al,2019.Crack initiation mechanism of pre-existing cracked granite[J].Journal of China Coal Society,44(Supp.2):84-91.
Hazzard J F, Young R P,2000.Simulating acoustic emissions in bonded-particle models of rock[J].International Journal of Rock Mechanics and Mining Sciences,37(5):867-872.
Jiang Mingjing, Chen He, Zhang Ning,et al,2014.Distinct element numerical analysis of crack evolution in rocks containing pre-existing double flaw[J].Rock and Soil Mechanics,35(11):3259-3268.
Lockner D A,1993.The role of acoustic emission in the study of rock fracture[J].International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts,30(7):883-899.
Martin C D, Christiansson R,2009. Estimating the potential for spalling around a deep nuclear waste repository in crystalline rock [J].International Journal of Rock Mechanics and Mining Sciences,46(2):219-228.
Ming X, Zhao C, Hobbs B E,2014.Particle simulation of thermally-induced rock damage with consideration of temperature-dependent elastic modulus and strength[J].Computers and Geotechnics,55:461-473.
Pan Pengzhi, Ding Wuxiu, Feng Xiating,et al,2008.Research on influence of pre-existing crack geometrical and material properties on crack propagation in rocks[J].Chinese Journal of Rock Mechanics and Engineering,27(9):1882-1889.
Papadopoulos G,1993.Fracture Mechanics[M]//The Experimental Method of Caustics and the Det.-Criterion of Fracture.New York:Springer-Verlag: 211-222.
Peng J, Rong G, Tang Z C,et al,2019.Microscopic characterization of microcrack development in marble after cyclic treatment with high temperature[J].Bulletin of Engineering Geology and the Environment,78(8):5965-5976.
Potyondy D O, Cundall P A,2004.A bonded-particle model for rock[J].International Journal of Rock Mechanics and Mining Sciences,41(8):1329-1364.
Sun Qiang, Zhang Zhizhen, Xue Lei,et al,2013. Physico-mechanical properties variation of rock with phase transformation under high temperature[J].Chinese Journal of Rock Mechanics and Engineering,35(5):935-942.
Wanne T S, Young R P,2008.Bonded-particle modeling of thermally fractured granite[J].International Journal of Rock Mechanics and Mining Sciences,45(5):789-799.
Wu Yun, Li Xiaozhao, Huang Zhen,et al,2020.Deformation and failure characteristics of granite under uniaxial compression after high temperature[J].Journal of Engineering Geology,28(2):240-245.
Xu X L, Gao F, Shen X,et al,2010. Research on mechanical characteristics and micropore structure of granite under high-temperature[J].Rock and Soil Mechanics,31(6):1752-1758.
Xu Z Y, Li T B, Chen G Q,et al,2018.The grain-based model numerical simulation of unconfined compressive strength experiment under thermal-mechanical coupling effect[J]. KSCE Journal of Civil Engineering,22(8):1-12.
Yang Guitong,1980.Elastic-Plastic Mechanics[M].Beijing:People’s Education Press.
Yang S Q, Huang Y H, Jing H W,et al,2014.Discrete element modeling on fracture coalescence behavior of red sandstone containing two unparallel fissures under uniaxial compression[J].Engineering Geology,178(21):28-48.
Yin T B, Zhang S S, Li X B,et al,2018.A numerical estimate method of dynamic fracture initiation toughness of rock under high temperature[J].Engineering Fracture Mechanics,204:87-102.
Yin Tubing, Li Xibing, Yin Zhiqiang,et al,2012.Study and comparison of mechanical properties of sandstone under static and dynamic loadings after high temperature[J].Chinese Journal of Rock Mechanics and Engineering,31(2):273-279.
Yu Qinglei, Zheng Chao, Yang Tianhong,et al,2012.Meso-structure characterization based on coupled thermal-mechanical model for rock failure process and applications[J].Chinese Journal of Rock Mechanics and Engineering,31(1):42-51.
Zhang Zhizhen, Gao Feng, Xu Xiaoli,2010.Acoustic emission characteristics and thermodynamic coupling model of granite under uniaxial compression[J].Chinese Journal of Underground Space and Engineering,6(1):70-74.
Zhao Z H,2016.Thermal influence on mechanical properties of granite:A microcracking perspective[J].Rock Mechanics and Rock Engineering,49(3):747-762.
Zhou Guanglei, Xu Tao, Zhu Wancheng,et al,2017.A time-dependent thermo-mechanical creep model of rock[J].Engineering Mechanics,34(10):1-9.
Zhu Hehua, Yan Zhiguo, Deng Tao,et al,2006. Testing study on mechanical properties of tuff,granite and breccia after high temperatures[J].Chinese Journal of Rock Mechanics and Engineering,25(10):1945-1950.
郭奇峰,武旭,蔡美峰,等,2019.预制裂隙花岗岩的裂纹起裂机理试验研究[J]. 煤炭学报,44(增2):84-91.
蒋明镜,陈贺,张宁,等,2014.含双裂隙岩石裂纹演化机理的离散元数值分析[J].岩土力学,35(11):3259-3268.
潘鹏志,丁梧秀,冯夏庭,等,2008.预制裂纹几何与材料属性对岩石裂纹扩展的影响研究[J].岩石力学与工程学报,27(9):1882-1889.
孙强,张志镇,薛雷,等,2013.岩石高温相变与物理力学性质变化[J].岩石力学与工程学报,32(5):935-942.
吴云,李晓昭,黄震,等,2020.高温作用后花岗岩单轴压缩下变形破坏特征研究[J].工程地质学报,28(2):240-245.
杨桂通,1980. 弹塑性力学[M].北京:人民教育出版社.
尹土兵,李夕兵,殷志强,等,2012.高温后砂岩静,动态力学特性研究与比较[J].岩石力学与工程学报,31(2):273-279.
于庆磊,郑超,杨天鸿,等,2012.基于细观结构表征的岩石破裂热—力耦合模型及应用[J].岩石力学与工程学报,31(1):42-51.
张志镇,高峰,徐小丽,2010.花岗岩单轴压缩的声发射特征及热力耦合模型[J].地下空间与工程学报,6(1):70-74.
周广磊,徐涛,朱万成,等,2017.基于温度—应力耦合作用的岩石时效蠕变模型[J].工程力学,34(10):1-9.
朱合华,闫治国,邓涛,等,2006.3种岩石高温后力学性质的试验研究[J].岩石力学与工程学报,25(10):1945-1950.
[1] Bo LI, Chen WEN, Xiuzhi SHI. Optimization of Stope Sidewall Controlled Blasting Parameters for High-Stress Fan-Shaped Medium-Depth Hole [J]. Gold Science and Technology, 2024, 32(3): 511-522.
[2] Dabing LIU, Yindong HE. Study on the Effect of Cutting Angle of Cutting Teeth on Cutting Performance [J]. Gold Science and Technology, 2024, 32(1): 91-99.
[3] Yanan ZHAO, Yihang ZHAO, Zhongming JIANG, Hongmin ZHAO. Preliminary Study on Static and Dynamic Stability of Canister for High-level Radioactive Nuclear Waste Disposal Based on Discrete Element Method [J]. Gold Science and Technology, 2023, 31(4): 592-604.
[4] Jielin LI,Jingyao WANG,Yigai XIAO,Xiaoshuang LI. Research on Meso-mechanical Properties of Rock Under Different Stress Paths Based on Discrete Element Method [J]. Gold Science and Technology, 2023, 31(1): 102-112.
[5] Kefan ZHOU,Kewei LIU,Tengfei GUO. Study on Failure Characteristics of Inclined Soft and Hard Interbedded Rocks Based on Acoustic Emission [J]. Gold Science and Technology, 2022, 30(6): 923-934.
[6] Guang LI,Fengshan MA,Jie GUO,Long ZOU,Yongyuan KOU. Study on Ground Stress Characteristics and Its Influence on Roadway De-formation Failure in Jinchuan No.2 Mining Area [J]. Gold Science and Technology, 2021, 29(6): 817-825.
[7] Weihua WANG,Jie LUO,Tian LIU,Zhenyu HAN. Particle Flow Simulation on Influence of Joint Roughness Coefficient on Stress Wave Propagation and Specimens Failure [J]. Gold Science and Technology, 2021, 29(2): 208-217.
[8] Peng JIN,Kewei LIU,Xudong LI,Jiacai YANG. Numerical Simulation Study of Crack Propagation in Deep Rock Mass Under Water-coupling Blasting [J]. Gold Science and Technology, 2021, 29(1): 108-119.
[9] Chuanfeng FANG,Jinmiao WANG,Shanbing LI,Mingtao JIA. Numerical Simulation Research of Natural Caving Method Based on PFC2D-DFN [J]. Gold Science and Technology, 2019, 27(2): 189-198.
[10] Sheng ZENG,Shaoping WANG,Ni ZHANG. Research Progress of Rock Crack Propagation Under Impact Loading [J]. Gold Science and Technology, 2019, 27(1): 52-62.
[11] Xiang LI,Zhen HUAI,Xibing LI,Zhuoyao ZHANG. Study on Fracture Characteristics and Mechanical Properties of Brittle Rock Based on Crack Propagation Model [J]. Gold Science and Technology, 2019, 27(1): 41-51.
[12] ZENG Qingtian,LIU Kewei,YAN Ti,WANG Liguan. Study on Natural Caving Mining Method Based on Multi-numerical  Simulation Method [J]. Gold Science and Technology, 2015, 23(1): 66-73.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!

©2018 Gold Science and Technology 

Telephone:0931-8277791 

E-mail: hjkx@lzb.ac.cn Postcode:730000 

Powered by Beijing Magtech Co. Ltd

陇ICP备17001318号-1