Mechanical responses of sheet-based gyroid-type triply periodic minimal surface lattice structures fabricated using selective laser melting

Owing to their lightweight design, high energy absorption capacity, and excellent thermal and sound insulation properties, lattice structures have many potential applications in the fields of security, aerospace, biomedicine, and heat dissipation. In this study, a gyroid-type triply periodic minimal surface is used to design lattice structures. Gyroid uniform lattice structures and gyroid graded lattice structures are mathematically designed and fabricated using selective laser melting with a SS 316 L stainless steel powder. The mechanical properties of these structures are studied under a compression load, and the deformation differences between the graded and uniform structures are compared. The finite element method is used to simulate the compression process, and the experimental and simulation results are qualitatively compared. Results show that during plastic deformation, the stress change in the graded structure is larger than that in the uniform structure. By controlling the volume fraction, mechanical properties can be specifically tailored, which provides the design guidelines for the application of this structure. (C) 2022 The Author(s). Published by Elsevier Ltd.

Automated summary

Due to their lightweight design, high energy absorption capacity, and excellent thermal and sound insulation properties, lattice structures have great potential in various fields. In this study, a specific geometric design was used to create lattice structures, and their mechanical properties and deformation characteristics were investigated through experiments and simulations. The results showed that the stress change in the graded structure was larger during plastic deformation, and the mechanical properties could be customized by controlling the volume fraction.