Crashworthiness characteristic of aluminum/composite hybrid tubes under axial compression

Crashworthiness characteristic of aluminum/composite hybrid tubes under axial compression

This study investigates the crashworthiness performance and energy absorption characteristics of circular aluminum-composite hybrid tubes reinforced with layers of waru bark fiber. Four tube configurations were fabricated: Aluminum Circular Tube (ACT), Composite Circular Tube (CCT), Hybrid Inner Cir...

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Bibliographic Details
Main Authors: Willy Artha Wirawan, Ayan Sabitah, Gunawan Sakti, Bambang Bagus Harianto, Moch. Agus Choiron, R.A. Ilyas, S.M. Sapuan, Joewono Prasetijo
Format: Article
Language:English
Published: Elsevier 2025-03-01
Series:Results in Engineering
Subjects:
Crashworthiness
Hybrid tubes
Axial compression
Energy absorption
Natural fiber reinforcement
Quasi-static test
Online Access:http://www.sciencedirect.com/science/article/pii/S2590123024021327
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Summary:This study investigates the crashworthiness performance and energy absorption characteristics of circular aluminum-composite hybrid tubes reinforced with layers of waru bark fiber. Four tube configurations were fabricated: Aluminum Circular Tube (ACT), Composite Circular Tube (CCT), Hybrid Inner Circular Tube (HICT), and Hybrid Outer Circular Tube (HOCT). These tubes were subjected to quasi-static axial compression loading tests. The reinforcement layers, oriented at 0°–90°, were bonded using epoxy resin. The experimental results revealed that the addition of reinforcement layers introduced new progressive crushing behaviors, such as internal curling and corkscrew patterns, which effectively mitigated buckling failure. The hybrid designs significantly enhanced energy absorption, with HOCT and HICT achieving improvements of 49.18% and 43.78%, respectively, compared to the unreinforced ACT. Among the configurations, HOCT demonstrated the highest crashworthiness, with a peak crushing force (IPFC) of 42.36 kN, a mean force (MF) of 24.66 kN, and a crush force efficiency (CFE) of 0.49%. However, the specific energy absorption (SEA) decreased as tube diameter and reinforcement density increased. These results offer valuable insights into the optimization of reinforced composite tube designs, highlighting their potential for advanced crashworthiness and energy absorption applications.
ISSN:2590-1230

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