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Compressive Behavior of 316L Stainless Steel Lattice Structures for Additive Manufacturing: Experimental Characterization and Numerical Modeling

Ignacio Chirosa Ríos, Laurent Duchêne, Anne Habraken, Ángelo Oñate, Rodrigo Valle, Anne Mertens, César Garrido, Gonzalo Pincheira, Víctor Tuninetti

2025Biomimetics11 citationsDOIOpen Access PDF

Abstract

Lattice structures produced by additive manufacturing are increasingly used in lightweight, load-bearing applications, yet their mechanical performance is strongly influenced by geometry, process parameters, and boundary conditions. This study investigates the compressive behavior of body-centered cubic (BCC) 316L stainless steel lattices fabricated by laser powder bed fusion (LPBF). Four relative densities (20%, 40%, 60%, and 80%) were achieved by varying the strut diameter, and specimens were built in both vertical and horizontal orientations. Quasi-static compression tests characterized the elastic modulus, yield strength, energy absorption, and mean force, while finite element simulations reproduced the deformation and hardening behavior. The experimental results showed a direct correlation between density and mechanical properties, with vertically built specimens performing slightly better due to reduced processing defects. Simulations quantified the effect of strut-joint rounding and the need for multi-cell configurations to closely match the experimental curves. Regardless of the boundary conditions, for a density of 20%, simulating a single cell underestimated stiffness because of unconstrained strut buckling. For higher densities and thicker struts, this sensitivity to boundary conditions strongly decreased, indicating the possibility of using a single cell for shorter simulations-a point rarely discussed in the literature. Both experiments and simulations confirmed Gibson-Ashby scaling for elastic modulus and yield strength, while the tangent modulus was highly sensitive to boundary conditions. The combined experimental and numerical results provide a framework for the reliable modeling and design of metallic lattices for energy absorption, biomedical, and lightweight structural applications.

Topics & Concepts

Materials scienceComposite materialFinite element methodBoundary value problemTangentStiffnessHardening (computing)Periodic boundary conditionsRelative densityScalingModulusElastic modulusCompression (physics)Homogenization (climate)Lattice (music)Material propertiesCompressive strengthDeformation (meteorology)Superposition principleMechanicsBoundary (topology)Lattice constantTangent modulusProjectileFusionComputer simulationStrain hardening exponentNanoindentationYield (engineering)PlasticityStructural engineeringBulk modulusSelective laser meltingDissipationYoung's modulusAdditive Manufacturing Materials and ProcessesAdditive Manufacturing and 3D Printing TechnologiesCellular and Composite Structures