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Design of stiffened panels for stress and buckling via topology optimization

Sheng Chu, Carol Featherston, H. Alicia Kim

2021Structural and Multidisciplinary Optimization30 citationsDOIOpen Access PDF

Abstract

Abstract This paper investigates the weight minimization of stiffened panels simultaneously optimizing sizing, layout, and topology under stress and buckling constraints. An effective topology optimization parameterization is presented using multiple level-set functions. Plate elements are employed to model the stiffened panels. The stiffeners are parametrized by implicit level-set functions. The internal topologies of the stiffeners are optimized as well as their layout. A free-form mesh deformation approach is improved to adjust the finite element mesh. Sizing optimization is also included. The thicknesses of the skin and stiffeners are optimized. Bending, shear, and membrane stresses are evaluated at the bottom, middle, and top surfaces of the elements. A p -norm function is used to aggregate these stresses in a single constraint. To solve the optimization problem, a semi-analytical sensitivity analysis is performed, and the optimization algorithm is outlined. Numerical investigations demonstrate and validate the proposed method.

Topics & Concepts

Topology optimizationSizingFinite element methodTopology (electrical circuits)Structural engineeringBucklingMathematical optimizationCompliant mechanismEngineering design processComputer scienceEngineeringMathematicsMechanical engineeringVisual artsArtElectrical engineeringTopology Optimization in EngineeringComposite Structure Analysis and OptimizationBuilding Energy and Comfort Optimization