Strength Evaluation Criteria and Equivalent Plastic Strain for Ideal M-C Materials
-
摘要: 基于理想Mohr-Coulomb(M-C)屈服准则,该文提出了拉伸、压缩和剪切等效应力的概念及其公式,并给出了三个相应的强度评估条件.根据塑性功等效原则,分别导出了与上述等效应力共轭的拉伸、压缩等效塑性应变和等效塑性剪应变,探论了不同的摩擦因数下等效应变的变化特征.与Mises等效应变不同,所得到的M-C等效应变能够反映静水压力的影响,也可退化为简单应力状态.这些等效应力和等效应变概念都具有明确的物理意义,将能够应用于更准确、有效地评估拉、压性能不同材料的强度,对于用简单拉伸、压缩或剪切试验标定复杂应力状态下本构模型参数也具有直接应用价值.
-
关键词:
- M-C等效应力 /
- M-C等效塑性应变 /
- 理想Mohr-Coulomb屈服准则 /
- 强度评估判据
Abstract: Based on the ideal Mohr Coulomb (M-C) yield criterion, the concepts and formulas of equivalent stresses in tension, compression, and shear, as well as the corresponding three strength evaluation conditions were presented. According to the equivalent principle of plastic work, the equivalent plastic strain and the equivalent plastic shear strain in tension and compression were derived, which are conjugated with the equivalent stress mentioned above. For different friction coefficients, the variation characteristics of these equivalent strains were discussed. Differing from the Mises equivalent strain, the M-C equivalent strain can reflect the influence of the hydrostatic pressure, and can also degenerate into a simple stress state. These concepts of equivalent stress and equivalent strain have clear physical meanings and can be applied to more accurately and effectively evaluate the strengths of materials with different tensile and compressive properties. They also have direct application values for calibrating constitutive model parameters under complex stress states through experiments under simple stress states. -
图 1 主应力空间的M-C屈服面及应力状态表示
Figure 1. The M-C yield surface and the representation of the stress state in the principal stress space
图 2 σet/q-η-θ关系曲面
注 为了解释图中的颜色,读者可以参考本文的电子网页版本,后同.
Figure 2. Relationship surfaces of σet/q-η-θ
-
[1] 王仁, 熊祝华, 黄文彬. 塑性力学基础[M]. 北京: 科学出版社, 1982.WANG Ren, XIONG Zhuhua, HAUNG Wenbin. Fundamentals of Plastic Mechanics[M]. Beijing: Science Press, 1982. (in Chinese) [2] 周喆, 秦伶俐, 黄文彬, 等. 有限变形下的等效应力和等效应变问题[J]. 应用数学和力学, 2004, 25(5): 542-550. http://www.applmathmech.cn/article/id/75ZHOU Zhe, QIN Lingli, HUANG Wenbin, et al. Effective stress and strain in finite deformation[J]. Applied Mathematics and Mechanics, 2004, 25(5): 542-550. (in Chinese) http://www.applmathmech.cn/article/id/75 [3] VERSHININ V V. A correct form of Bai-Wierzbicki plasticity model and its extension for strain rate and temperature dependence[J]. International Journal of Solids and Structures, 2017, 126: 150-162. [4] POURHOSSEINI O, SHABANIMASHCOOL M. Development of an elasto-plastic constitutive model for intact rocks[J]. International Journal of Rock Mechanics and Mining Sciences, 2014, 66: 1-12. doi: 10.1016/j.ijrmms.2013.11.010 [5] 张学言. 岩土塑性力学[M]. 北京: 人民交通出版社, 1993.ZHANG Xueyan. Geotechnics Plastic Mechanics[M]. Beijing: China Communications Press, 1993. (in Chinese) [6] BRIDGMAN P W. Studies in Large Plastic Flow and Fracture: With Special Emphasis on the Effects of Hydrostatic Pressure[M]. Cambridge: Harvard University Press, 1964. [7] ALGARNI M, GHAZALI S, ZWAWI M. The emerging of stress triaxiality and Lode angle in both solid and damage mechanics: a review[J]. Mechanics of Solids, 2021, 56(5): 787-806. doi: 10.3103/S0025654421050058 [8] STOUGHTON T B, YOON J W. A pressure-sensitive yield criterion under a non-associated flow rule for sheet metal forming[J]. International Journal of Plasticity, 2004, 20(4/5): 705-731. [9] ARETZ H. A consistent plasticity theory of incompressible and hydrostatic pressure sensitive metals[J]. Mechanics Research Communications, 2007, 34(4): 344-351. doi: 10.1016/j.mechrescom.2007.01.002 [10] BAI Y, WIERZBICKI T. A new model of metal plasticity and fracture with pressure and Lode dependence[J]. International Journal of Plasticity, 2008, 24(6): 1071-1096. doi: 10.1016/j.ijplas.2007.09.004 [11] JOHNSON G R, COOK W H. Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures[J]. Engineering Fracture Mechanics, 1985, 21(1): 31-48. doi: 10.1016/0013-7944(85)90052-9 [12] HAN Peihua, CHENG Peng, YUAN Shuai, et al. Characterization of ductile fracture criterion for API X80 pipeline steel based on a phenomenological approach[J]. Thin-Walled Structures, 2021, 164: 107254. doi: 10.1016/j.tws.2020.107254 [13] VERSHININ V V. Validation of metal plasticity and fracture models through numerical simulation of high velocity perforation[J]. International Journal of Solids and Structures, 2015, 67/68: 127-138. doi: 10.1016/j.ijsolstr.2015.04.007 [14] PAREDES M, WIERZBICKI T. On mechanical response of zircaloy-4 under a wider range of stress states: from uniaxial tension to uniaxial compression[J]. International Journal of Solids and Structures, 2020, 206: 198-223. doi: 10.1016/j.ijsolstr.2020.09.007 [15] BAI Yuanli, WIERZBICKI T. Application of extended Mohr-Coulomb criterion to ductile fracture[J]. International Journal of Fracture, 2010, 161(1): 1-20. doi: 10.1007/s10704-009-9422-8 [16] DA SILVA SANTOS I, SARZOSA D F B, PAREDES M. Ductile fracture modeling using the modified Mohr-Coulomb model coupled with a softening law for an ASTM A285 steel[J]. Thin-Walled Structures, 2022, 176: 109341. doi: 10.1016/j.tws.2022.109341 [17] GRANUM H, MORIN D, BØRVIK T, et al. Calibration of the modified Mohr-Coulomb fracture model by use of localization analyses for three tempers of an AA6016 aluminium alloy[J]. International Journal of Mechanical Sciences, 2021, 192: 106122. doi: 10.1016/j.ijmecsci.2020.106122 [18] ABAQUS Inc. ABAQUS Analysis User's Manual v[Z]. 2023. [19] LI X X. Parametric study on numerical simulation of missile punching test using concrete damaged plasticity (CDP) model[J]. International Journal of Impact Engineering, 2020, 144: 103652. doi: 10.1016/j.ijimpeng.2020.103652 [20] CHEN W F. Constitutive Equations for Engineering Materials: Plasticity and Modeling[M]. New York: John Wiley & Sons Inc, 1994. [21] 赵亚溥. 近代连续介质力学[M]. 北京: 科学出版社, 2016.ZHAO Yapu. Modern Continuum Mechanics[M]. Beijing: Science Press, 2016. (in Chinese) -
下载:
图(5)
计量
- 文章访问数: 83
- HTML全文浏览量: 33
- PDF下载量: 11
- 被引次数: 0
渝公网安备50010802005915号