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Topology optimization and 3D printing of large deformation compliant mechanisms for straining biological tissues

Prabhat Kumar, Christina Schmidleithner, Niels B. Larsen, Ole Sigmund

2021Technical University of Denmark, DTU Orbit (Technical University of Denmark, DTU)38 citationsOpen Access PDF

Abstract

This paper presents a synthesis approach in a density-based topology optimization setting to design large deformation compliant mechanisms for inducing desired strains in biological tissues. The modelling is based on geometrical nonlinearity together with a suitably chosen hypereleastic material model, wherein the mechanical equilibrium equations are solved using the total Lagrangian finite element formulation. An objective based on least-square error with respect to target strains is formulated and minimized with the given set of constraints and the appropriate surroundings of the tissues. To circumvent numerical instabilities arising due to large deformation in low stiffness design regions during topology optimization, a strain-energy-based interpolation scheme is employed. The approach uses an extended robust formulation, i.e., the eroded, intermediate, and dilated projections for the design description as well as variation in tissue stiffness. Efficacy of the synthesis approach is demonstrated by designing various compliant mechanisms for providing different target strains in biological tissue constructs. Optimized compliant mechanisms are 3D printed and their performances are recorded in a simplified experiment and compared with simulation results obtained by a commercial software.

Topics & Concepts

Topology optimizationCompliant mechanismStiffnessFinite element methodTopology (electrical circuits)Deformation (meteorology)Interpolation (computer graphics)Nonlinear systemComputer scienceEngineering design processStrain energy density functionMathematical optimizationMathematicsStructural engineeringMechanical engineeringEngineeringMaterials sciencePhysicsQuantum mechanicsFrame (networking)Composite materialCombinatoricsTopology Optimization in EngineeringPiezoelectric Actuators and ControlComposite Structure Analysis and Optimization
Topology optimization and 3D printing of large deformation compliant mechanisms for straining biological tissues | Litcius