使用基于快速傅立叶变换的求解器求解微观弹塑性

Noah M. Francis, Ricardo A. Lebensohn, Fatemeh Pourahmadian, Rémi Dingreville
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引用次数: 0

摘要

这项研究提出了一种微机械光谱公式,用于获得弹性微波复合材料的全场和均质响应。从基于热力学的微观弹塑性构成方程中推导出封闭形式的径向返回映射,以确定将广义应力状态返回屈服面所需的塑性应变增量,并使用数值制造解的方法验证了算法的实现。然后,显示了尺寸依赖性材料响应和微塑性的特征,这些特征可以在这个微元弹塑性框架中得到有效模拟。该计算方法的计算效率使其能够在合理的计算时间内生成大型数据集。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Micropolar elastoplasticity using a fast Fourier transform-based solver
This work presents a micromechanical spectral formulation for obtaining the full-field and homogenized response of elastoplastic micropolar composites. A closed-form radial-return mapping is derived from thermodynamics-based micropolar elastoplastic constitutive equations to determine the increment of plastic strain necessary to return the generalized stress state to the yield surface, and the algorithm implementation is verified using the method of numerically manufactured solutions. Then, size-dependent material response and micro-plasticity are shown as features that may be efficiently simulated in this micropolar elastoplastic framework. The computational efficiency of the formulation enables the generation of large datasets in reasonable computing times.
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