A Thermo-Electro-Elasto-Viscoplastic Damage Internal State Variable (ISV) Model for Ductile Metals

Volume 12: Materials: Genetics to Structures Pub Date : 2018-11-09 DOI:10.1115/IMECE2018-86598

N. Dimitrov, Yucheng Liu, M. Horstemeyer

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引用次数: 3

Abstract

A multiphysics Internal State Variable (ISV) theory that couples the thermoelastoviscoplastic damage model of Bammann-Horstemeyer with electricity-related electromagnetic phenomena is presented in which the kinematics, thermodynamics, and kinetics are internally consistent. An extended multiplicative decomposition of the deformation gradient that accounts for elasticity, plasticity, damage, thermal expansion, electricity, and magnetism is introduced. The different geometrically-affected rate equations are given for each phenomenon after the ISV formalism and have a thermodynamic force pair that acts as an internal stress-like quantity. Guidelines for practical implementation, recommendations for simplifying assumptions, and suggestions for future work supplement the theoretical model. The abstraction of the model can capture the full multi-physics described above; however, the robustness of the model is realized when any of the listed phenomena are not included in the boundary value problem, the model reduces to the previous form — the model will revert to the Bammann-Horstemeyer plasticity-damage ISV model.

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延性金属热-电-弹-粘塑性损伤内状态变量模型

提出了一种将Bammann-Horstemeyer热弹粘塑性损伤模型与电相关电磁现象耦合的多物理场内状态变量(ISV)理论，其中运动学、热力学和动力学是内部一致的。介绍了考虑弹性、塑性、损伤、热膨胀、电和磁的变形梯度的扩展乘法分解。在ISV形式化之后，给出了每种现象的不同几何影响率方程，并具有作为内应力样量的热力学力对。实践实施指南、简化假设的建议和对未来工作的建议是对理论模型的补充。模型的抽象可以捕捉到以上描述的完整的多物理场;然而，当边界值问题中不包含所列任何一种现象时，模型将退化为先前的形式，即模型将恢复为Bammann-Horstemeyer塑性-损伤ISV模型，从而实现了模型的鲁棒性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Volume 12: Materials: Genetics to Structures

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