4.5 Article

Quasi-static mechanical properties of origami-inspired cellular metamaterials made by metallic 3D printing

Journal

MECHANICS OF ADVANCED MATERIALS AND STRUCTURES
Volume 30, Issue 21, Pages 4459-4472

Publisher

TAYLOR & FRANCIS INC
DOI: 10.1080/15376494.2022.2097351

Keywords

Origami cellular metamaterial; quasi-static mechanical properties; experimental study; finite element analysis; metallic 3D printing

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This article presents a systematic study on the mechanical properties of 3D-printed metallic origami cellular metamaterials (OCMs) based on various origami configurations. The OCM specimens were fabricated using metallic 3D printing method, and compression tests were carried out to obtain their mechanical responses. The relationship between key design parameters and mechanical performance was revealed. Finite element modeling and parametric studies were conducted to further analyze the compressive behaviors of different OCM models. This work provides a practical guide for the design and fabrication of 3D-printed metallic OCMs.
Cellular mechanical metamaterials based on origami folded structures have attracted much attention due to their high designability in the mechanical properties. While origami cellular metamaterials (OCMs) made of plastics via 3 D printing have been studied extensively, those fabricated by metallic 3 D printing are relatively rare. This article presents a systematical experimental and numerical study on the quasi-static mechanical properties of 3 D-printed metallic OCMs based on various origami configurations and revealed the relationship between their key design parameters and mechanical performance. First, the OCM specimens based on the Miura pattern were fabricated using a metallic 3 D printing method, and compression tests were carried out to obtain their mechanical responses. The experiment results showed that the OCM specimens made from stainless steel exhibited large elastoplastic deformation, whereas early fracture of the material occurred in the aluminum alloy and titanium alloy specimens, and those with smaller cell size and wall thickness showed enhanced mechanical performance. Second, the FE modeling method for the metallic OCMs was developed and validated with the experiment data. Parametric studies on the compressive behaviors of metallic OCM models based on the two-stage Miura, perforated Miura, graded Miura, and cube pipe structures were then conducted. The relationships between the key geometric parameters and mechanical performance of various OCM models were disclosed. This work can provide a practical guide for the design and fabrication of 3 D-printed metallic OCMs.

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