Litcius/Paper detail

Study on the crashworthiness of multi-cell thin-walled tubes filled with triply periodic minimal surface lattices

Suchao Xie, Shiwei Zheng, Jing Zhang, Zinan Liu, Hao Wang, Hui Zhou

2024Mechanics of Advanced Materials and Structures23 citationsDOI

Abstract

To improve energy absorption and efficiency and develop a structure with outstanding energy absorption capability, this study proposed designing multi-cell tubes filled with triply periodic minimal surface (TPMS) lattices. Based on experimental and simulation methods, the crashworthiness of multi-cell tubes filled with three types of TPMS lattices (Diamond, Gyroid, and Primitive) was investigated. Five multi-cell tube structures were fabricated by increasing the thin-walled tube corner units, improving the energy absorption efficiency by 67.98%. The results show that due to the coupling between TPMS lattices and thin-walled tubes, multi-cell tubes filled with TPMS lattices exhibited better crashworthiness performance. The energy absorption of multi-cell tubes filled with Diamond, Gyroid, and Primitive lattices increased sequentially. The energy absorption per unit mass and energy absorption capability were most notably enhanced for the multi-cell tubes filled with Diamond lattice, with energy absorption efficiency 17.24% higher and energy absorption 104.26% greater than empty multi-cell tubes. This inspires crash designs of rail vehicles and automotive fronts.

Topics & Concepts

CrashworthinessMaterials scienceSurface (topology)Structural engineeringComposite materialFinite element methodGeometryEngineeringMathematicsCellular and Composite StructuresAdvanced Materials and MechanicsQuasicrystal Structures and Properties