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