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Crushing performance of bioinspired hierarchical tapered structures

Xinmei Xiang, Chenkun Xiao, Guoxing Lu, Yi Min Xie, Miaochang Zhu, Ngoc San Ha

2024Materials & Design33 citationsDOIOpen Access PDF

Abstract

This paper introduces a new type of energy-absorbing hierarchical tapered structure, mimicking the hierarchical architecture of barnacle. The proposed structures are designed by iteratively incorporating sub-tapered tubes at the junctions of primary ribs aiming to enhance the crashworthiness performance. The finite element models of the proposed structures are constructed in Abaqus software and validated using experimental testing. The effects of the geometrical parameters including the number of substructures and the external-to-internal wall thickness ratio on the energy absorption characteristics of the proposed structures are investigated. The results demonstrate that as the number of substructures increases, the specific energy absorption (SEA) and mean crushing force of the proposed design show a significant improvement. Specially, the SEA of the proposed structures with four substructures can reach 32.78 kJ/kg, which is 85.8 % higher than the conventional tapered tube. Additionally, decreasing the ratio of external to internal wall thickness leads to enhanced performance. After optimizing the wall thickness ratio, the maximum SEA can reach 40.87 kJ/kg, which is 26.0 % higher than that before optimization. To complement the findings, a theoretical study is presented, which exhibits excellent agreement with the numerical results, further validating the effectiveness of the proposed design. This study highlights the potential of incorporating hierarchical and tapered features into tapered structures, offering promising prospects for advancements in energy absorption technology across diverse industries.

Topics & Concepts

CrashworthinessMaterials scienceStructural engineeringAbsorption (acoustics)Finite element methodAspect ratio (aeronautics)Mechanical engineeringComposite materialEngineeringCellular and Composite StructuresAdvanced Materials and MechanicsCalcium Carbonate Crystallization and Inhibition