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The role of unit cell topology in modulating the compaction response of additively manufactured cellular materials using simulations and validation experiments

Sushan Nakarmi, Ji Hyeon Kim, Lindsey B. Bezek, Jeffery A. Leiding, Kwan‐Soo Lee, Nitin Daphalapurkar

2024Modelling and Simulation in Materials Science and Engineering10 citationsDOIOpen Access PDF

Abstract

Abstract Additive manufacturing has enabled a transformational ability to create cellular structures (or foams) with tailored topology. Compared to their monolithic polymer counterparts, cellular structures are potentially suitable for systems requiring materials with high specific energy-absorbing capability to provide enhanced damping. In this work, we demonstrate the utility of controlling unit-cell topology with the intent of obtaining a desired stress–strain response and energy density. Using mesoscale simulations that resolve the unit-cell sub-structures, we validate the role of unit-cell topology in selectively activating a buckling mode and thereby modulating the characteristic stress–strain response. Simulations incorporate a linear viscoelastic constitutive model and a hyperelastic model for simulating large deformation of the polymer under both tension and compression. Simulated results for nine different cellular structures are compared with experimental data to gain insights into three different modes of buckling and the corresponding stress–strain response.

Topics & Concepts

Materials scienceHyperelastic materialTopology optimizationTopology (electrical circuits)Strain energy density functionStress (linguistics)Deformation (meteorology)ViscoelasticityTension (geology)Compression (physics)Biological systemMechanicsStructural engineeringComposite materialFinite element methodPhysicsEngineeringLinguisticsElectrical engineeringPhilosophyBiologyCellular and Composite StructuresPolymer Foaming and CompositesAdvanced Materials and Mechanics