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Stress-based structural topology optimization for design-dependent self-weight loads problems using the BESO method

G. L. Garcez, Renato Pavanello, Renato Picelli

2021Engineering Optimization12 citationsDOIOpen Access PDF

Abstract

This article aims to propose an approach to the stress-based topology optimization of continuous elastic bi-dimensional structures subjected to design-dependent self-weight loads using the Bi-directional Evolutionary Structural Optimization (BESO) method. Topology optimization is developed through the minimization of <i>P</i>-norm von Mises stress while satisfying a volume constraint. To implement the algorithm, a consistent sensitivity analysis including design-dependent loads has been developed by the adjoint method. A series of tests has been performed to explore and validate the method through three numerical examples: an L-bracket; a doubly supported beam with one pre-existing crack notch; and a cantilever beam. Comparison between traditional compliance minimization and stress minimization analyses, including design-dependent self-weight loads, shows that the method is an effective way to reduce the maximum stress.

Topics & Concepts

Topology optimizationCantileverMinificationvon Mises yield criterionTopology (electrical circuits)Mathematical optimizationMinimum weightConstraint (computer-aided design)Norm (philosophy)Stress (linguistics)MathematicsStructural engineeringSensitivity (control systems)Computer scienceFinite element methodEngineeringGeometryPolitical scienceElectronic engineeringPhilosophyLinguisticsCombinatoricsLawTopology Optimization in EngineeringComposite Structure Analysis and OptimizationAdvanced Multi-Objective Optimization Algorithms
Stress-based structural topology optimization for design-dependent self-weight loads problems using the BESO method | Litcius