4.7 Article

Crashworthiness Assessment of Carbon/Glass Epoxy Hybrid Composite Tubes Subjected to Axial Loads

Journal

POLYMERS
Volume 14, Issue 19, Pages -

Publisher

MDPI
DOI: 10.3390/polym14194083

Keywords

hybrid composites; composite tube; crashworthiness; finite element model; energy absorption; axial load

Funding

  1. Universiti Teknologi Malaysia collaborative research grant [Q.J130000.2409.07G99, R.J130000.7351.4B553]

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This study fabricates and tests composite tubes with different length aspect ratios using the pultrusion method, and investigates the crashworthiness of hybrid glass-carbon composite tubes under quasi-static axial loading through experimental and numerical simulations. The results show that hybrid glass/carbon tubes exhibit high specific energy absorption and crash force efficiency under impact loading.
The crashworthiness of composite tubes is widely examined for various types of FRP composites. However, the use of hybrid composites potentially enhances the material characteristics under impact loading. In this regard, this study used a combination of unidirectional glass-carbon fibre reinforced epoxy resin as the hybrid composite tube fabricated by the pultrusion method. Five tubes with different length aspect ratios were fabricated and tested, in which the results demonstrate how structural energy absorption affects by increasing the length of tubes. Crash force efficiency was used as the criterion to show that the selected L/D are acceptable of crash resistance with 95% efficiency. Different chamfering shapes as the trigger mechanism were applied to the tubes and the triggering effect was examined to understand the impact capacity of different tubes. A finite element model was developed to evaluate different crashworthiness indicators of the test. The results were validated through a good agreement between experimental and numerical simulations. The experimental and numerical results show that hybrid glass/carbon tubes accomplish an average 25.34 kJ/kg specific energy absorption, average 1.43 kJ energy absorption, average 32.43 kN maximum peak load, and average 96.67% crash force efficiency under quasi-static axial loading. The results show that selecting the optimum trigger mechanism causes progressive collapse and increases the specific energy absorption by more than 35%.

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