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Multi-physics topology optimization of functionally graded controllable porous structures: Application to heat dissipating problems

Sourav Das, Alok Sutradhar

2020Materials & Design97 citationsDOIOpen Access PDF

Abstract

Graded porous structures can improve the design performance with a smooth transition of material properties over the domain. We present a multi-physics topology optimization approach for designing functionally graded porous structures. As an application, we present a formulation to optimize heat dissipating structures to enhance structural and thermal performance. The pore size, resolution, and porosity of the structures can be controlled to obtain optimized mechanical and thermal performances. Several controlling schemes are introduced which can tailor the design of the porous structures. Design approaches based on the functional variation of porosity, pore size and sensitivity-based porosity control are employed. Numerical examples with different structural loads, thermal loads and boundary conditions are presented to verify the formulation and show the efficacy of the implementation. We also investigate the effect of the controlling parameters on the overall design. The proposed formulation shows good promise to design functionally graded porous structures with targeted porosity in multi-physics systems.

Topics & Concepts

PorosityMaterials scienceTopology optimizationThermalMaterial DesignBoundary value problemPorous mediumOptimal designBoundary (topology)Topology (electrical circuits)Mechanical engineeringFinite element methodStructural engineeringComposite materialComputer scienceEngineeringMathematicsThermodynamicsPhysicsMathematical analysisMachine learningElectrical engineeringTopology Optimization in EngineeringComposite Structure Analysis and OptimizationAdvanced Multi-Objective Optimization Algorithms