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<scp>Topology</scp> optimization for three‐dimensional elastoplastic architected materials using a path‐dependent adjoint method

Diab Abueidda, Ziliang Kang, Seid Korić, Kai A. James, Iwona Jasiuk

2020International Journal for Numerical Methods in Engineering27 citationsDOI

Abstract

Abstract This article introduces a computational design framework for obtaining three‐dimensional (3D) periodic elastoplastic architected materials with enhanced performance, subject to uniaxial or shear strain. A nonlinear finite element model accounting for plastic deformation is developed, where a Lagrange multiplier approach is utilized to impose periodicity constraints. The analysis assumes that the material obeys a von Mises plasticity model with linear isotropic hardening. The finite element model is combined with a corresponding path‐dependent adjoint sensitivity formulation, which is derived analytically. The optimization problem is parametrized using the solid isotropic material penalization method. Designs are optimized for either end compliance or toughness for a given prescribed displacement. Such a framework results in producing materials with enhanced performance through much better utilization of an elastoplastic material. Several 3D examples are used to demonstrate the effectiveness of the mathematical framework.

Topics & Concepts

Lagrange multiplierFinite element methodIsotropyvon Mises yield criterionNonlinear systemTopology optimizationPlasticityApplied mathematicsMathematicsPath (computing)Topology (electrical circuits)Structural engineeringMathematical analysisMathematical optimizationComputer scienceMaterials scienceEngineeringPhysicsComposite materialProgramming languageCombinatoricsQuantum mechanicsTopology Optimization in EngineeringComposite Structure Analysis and OptimizationComposite Material Mechanics
<scp>Topology</scp> optimization for three‐dimensional elastoplastic architected materials using a path‐dependent adjoint method | Litcius