Analysis of Localization of
Mohr-Coulomb Strength Law with Damage Effect

doi:10.1007/s12204-012-1334-5

Abstract

Abstract: The damage critical curved surface is derived by considering the related effect of isotropic damage and degradation of cohesion and internal friction angle of Mohr-Coulomb strength law. The characteristics of stress-displacement curve and networks of shear bands with the change of degree of damage, confining pressure and Poisson’s ratio are investigated numerically by monitoring the stress-displacement values in the process of deformation of samples under plane strain and different initial conditions. The dependence of elastic-plastic response of localization is discussed. The non-uniqueness of the solution of equation is given. The orientation angle of shear band is derived by considering the related effect of isotropic damage and degradation of cohesion and internal friction angle. The orientation angle of shear band obtained by numerical simulation is contrasted to the orientation angle by measuring Mohr circle. It is shown that peak strength and residual strength depend on confining pressure. The networks of shear bands begin to appear in phase II of elasticity and develop in soften phase, and the shear band is formed in the phase of residual strength. As the degree of damage increases, axial displacement at the points of bifurcation and shear band decreases. The orientation angle of shear band increases with the increase of the damage degree. The orientation angle of shear band obtained by numerical simulation and measuring Mohr circle is not much difference when the damage degree is equivalent. The Mohr-Coulomb theory may predict the localized instability of sample by considering the degradation of cohesion and internal friction angle.

Key words: bifurcation| shear band| damage| orientation angle| Mohr-Coulomb strength law

摘要： The damage critical curved surface is derived by considering the related effect of isotropic damage and degradation of cohesion and internal friction angle of Mohr-Coulomb strength law. The characteristics of stress-displacement curve and networks of shear bands with the change of degree of damage, confining pressure and Poisson’s ratio are investigated numerically by monitoring the stress-displacement values in the process of deformation of samples under plane strain and different initial conditions. The dependence of elastic-plastic response of localization is discussed. The non-uniqueness of the solution of equation is given. The orientation angle of shear band is derived by considering the related effect of isotropic damage and degradation of cohesion and internal friction angle. The orientation angle of shear band obtained by numerical simulation is contrasted to the orientation angle by measuring Mohr circle. It is shown that peak strength and residual strength depend on confining pressure. The networks of shear bands begin to appear in phase II of elasticity and develop in soften phase, and the shear band is formed in the phase of residual strength. As the degree of damage increases, axial displacement at the points of bifurcation and shear band decreases. The orientation angle of shear band increases with the increase of the damage degree. The orientation angle of shear band obtained by numerical simulation and measuring Mohr circle is not much difference when the damage degree is equivalent. The Mohr-Coulomb theory may predict the localized instability of sample by considering the degradation of cohesion and internal friction angle.

关键词: bifurcation| shear band| damage| orientation angle| Mohr-Coulomb strength law

CLC Number:

TU 443

WANG Zhong-chang1,2* (王忠昶), WANG Hai-tao1,2 (王海涛), YANG Qing2 (杨庆). Analysis of Localization of Mohr-Coulomb Strength Law with Damage Effect[J]. Journal of shanghai Jiaotong University (Science), 2012, 17(5): 619-628.

References

[1] Lu Yun-de, Ge Xiu-run, Jiang Yu, et al. Study on conventional triaxial compression test of complete process for marble and constitutive equation [J]. Chinese Journal of Rock Mechanics and Engineering, 2004, 23(15):2489-2493 (in Chinese).

[2] Wang Jian-guo, Wang Zheng-wei, Ma Shao-peng.Test study on deformation field evolution of rock material under cyclic load [J]. Chinese Journal of Rock Mechanics and Engineering, 2009, 28(Sup2): 3336-3341(in Chinese).

[3] Pan Yi-shan, Yang Xiao-bin, Ma Shao-peng, et al.Experimental study on the deformation localization of rock-soil material [J]. Journal of China Coal Society,2002, 27(3): 281-284 (in Chinese).

[4] Pan Bing, Xie Hui-min, Xia Yong, et al. Largedeformation measurement based on reliable initial guess in digital image correlation method [J]. Acta Optica Sinica, 2009, 29(2): 400-600 (in Chinese).

[5] Zhang Dong-ming, Hu Qian-ting, Wang Hao. Digital speckle experimental research on deformation localization of soft rock [J]. Journal of China Coal Society,2011, 36(4): 567-571 (in Chinese).

[6] Rudnicki J W, Rice J R. Conditions for the localization of deformation in pressure-sensitive dilatant materials [J]. Journal of the Mechanics and Physics of Solids, 1975, 23(6): 371-394.

[7] Rice J R, Rudnicki J W. A note on some features of the theory of localization of deformation [J]. International Journal of Solids Structure, 1980, 16: 597-605.

[8] Vardoulakis I, Karlsruhe B R D. Bifurcation analysis of the triaxial test on sand samples [J]. Acta Mechanica, 1979, 32: 35-54.

[9] Zhang Yong-qiang, Song Li, Yu Mao-hong. Unified solution of discontinuous bifurcation for plane strain problems [J]. China Civil Engineering Journal, 2004,37(4): 54-59 (in Chinese).

[10] Zhao Ji-dong, Zhou Wei-yuan, Huang Yan-song, et al. A damage localization bifurcation model for rockconcrete-like materials and its application [J]. Chinese Journal of Geotechnical Engineering, 2003, 25(1): 80-83 (in Chinese).

[11] Wang Xue-bing, Pan Yi-shan, Yu Hai-jun. Axial response of rock specimen considering strain rate gradient effect in uniaxial compression [J]. Rock and Soil Mechanics, 2003, 24(6): 943-946 (in Chinese).

[12] Hill R. Some basic principles in the mechanics of solids without nature time [J]. Journal of Mechanics and Physics of Solids, 1959, 7(3): 209-225.

[13] Zhang Hong-wu. Uniqueness and localization bifurcation analysis solution of saturated porous media[J]. Acta Mechanica Sinica, 2000, 32(6): 686-697 (in Chinese).

[1]	CAO Zheng, LEI Xuelin, ZHANG Hang, CAI Xiaojiang. Cryogenic Minimal Quantity Lubrication Assisted Cutting Process for Polyimide Materials [J]. Journal of Shanghai Jiao Tong University, 2022, 56(6): 784-793.
[2]	CAI Shuyu∗ (蔡舒妤), SHI Lizhong (师利中). Airframe Damage Region Division Method Based on Structure Tensor Dynamic Operator [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(6): 757-767.
[3]	TANG Jianhui, CHEN Xudong, BAI Yin. Fracture Damage Characteristics of Rock Under Pre-Peak and Post-Peak Cyclic Loading Condition [J]. Journal of Shanghai Jiao Tong University, 2022, 56(12): 1700-1709.
[4]	ZHANGKai, ZHANGShousen, QIDelu. Design and Research of the Ballastand De-Ballast Systemof Semi-Submersible Production and Storage Platforms [J]. Ocean Engineering Equipment and Technology, 2022, 9(1): 15-20.
[5]	LIU Jianhui (刘俭辉), L ¨U Xin (吕鑫), WEI Yaobing∗ (韦尧兵),ZHANG Rupeng (张如鹏), ZHANG Yonggui (张永贵). Notched Component Fatigue Life Prediction in Torsional Loading [J]. J Shanghai Jiaotong Univ Sci, 2021, 26(6): 813-818.
[6]	ZHANG Songlin, MA Dongliang, WANG Deyu. Method for Plate Crack Damage Detection Based on Long Short-Term Memory Neural Network [J]. Journal of Shanghai Jiao Tong University, 2021, 55(5): 527-535.
[7]	ZHUANG Weimin (庄蔚敏), WANG Pengyue (王鹏跃), AO Wenhong (熬文宏), CHEN Gang (陈刚) . Experiment and Simulation of Impact Response of Woven CFRP Laminates with Different Stacking Angles [J]. J Shanghai Jiaotong Univ Sci, 2021, 26(2): 218-230.
[8]	GUAN Qingyu, XIA Pinqi, ZHENG Xiaoling, WU Guanghui. Fitting Model to Compressive Strength of Composite Laminate After Impact [J]. Journal of Shanghai Jiao Tong University, 2021, 55(11): 1459-1466.
[9]	LONG Teng, LIU Zhenyu, SHI Renhe, WANG Shengyin. Neural Network Based Air Defense Weapon Target Intelligent Assignment Method [J]. Air & Space Defense, 2021, 4(1): 1-7.
[10]	WANG Xiangmin, WANG Jun, XIE Jietao, GUO Zhi. A Damage Probability Calculation Model Based on State Equation of Firing Error for Anti-Aircraft Artillery [J]. Journal of Shanghai Jiaotong University, 2020, 54(9): 961-966.
[11]	YU Zelin, SUN Pengwen, WANG Dong. Fatigue Life Prediction for Flange Connecting Bolts of Wind Turbine Tower [J]. Journal of Shanghai Jiao Tong University(Science), 2020, 25(4): 526-530.
[12]	GAO Jianxiong (高建雄), AN Zongwen (安宗文), MA Qiang (马强), ZHAO Shendan (赵申诞). Probability Model of Residual Strength of Materials Under Uncertain Cyclic Load [J]. Journal of Shanghai Jiao Tong University (Science), 2020, 25(2): 266-272.
[13]	ZHANG Yunhao,Alimu·Anwaier,MI Xiang,ZHANG Daxu,CHEN Wujun,LU Guofu,ZHANG Jinkui. Effects of Short-Term Aging and Creasing Damage on Air Leakage Properties of Airship Envelope Materials [J]. Journal of Shanghai Jiaotong University, 2020, 54(11): 1189-1199.
[14]	LIU Hailong，ZHANG Daxu，QI Heyin，WU Haihui，GUO Hongbao，HONG Zhiliang，CHEN Chao，ZHANG Yi. Tensile Damage Evolution of Plain Weave SiC/SiC Composites Based on In-situ X-Ray CT Tests [J]. Journal of Shanghai Jiaotong University, 2020, 54(10): 1074-1083.
[15]	WANG Hui,JING Weichuan,ZHAO Guochao,JIN Xin. Fatigue Life Prediction for Hydraulic Support Foundation Based on Grey System Model GM (1, 1) Improved Miner Criterion [J]. Journal of Shanghai Jiaotong University, 2020, 54(1): 106-110.

Analysis of Localization of Mohr-Coulomb Strength Law with Damage Effect

Analysis of Localization of Mohr-Coulomb Strength Law with Damage Effect

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments