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Abstract

In this paper, the mechanical behavior and energy absorption characteristics of carbon fiber reinforced polymer (CFRP) thin-walled tubes with different geometrical parameters (wall thickness and length) and their aluminum foam-filled tubes were investigated at four loading angles, namely, 0°, 15°, 30°, and 45°, through systematic experimental studies. Custom-angled molds were used for oblique loading tests. Structure-filler synergy was analyzed through damage morphology, load-displacement curves, and energy absorption indexes. The results show that the hollow tube under axial compression is dominated by progressive buckling, while the damage mode gradually evolves into local buckling, delamination, and lateral cracking with the increase of the angle during oblique loading, leading to a significant decrease in energy absorption efficiency. Aluminum foam filling can significantly enhance the energy absorption of CFRP thin-walled tubes under axial compression, and the enhancement is weakened in inclined angle loading compared with axial loading but still shows excellent energy absorption performance and stability. Geometric parameters significantly impact tube performance. Increased wall thickness enhances stiffness and energy absorption stability, but excessively thick tubes may exhibit unfavorable damage modes under large-angle compression. Tube length effects should be considered in conjunction with angle and wall thickness to optimize energy dissipation and stability.

Keywords

CFRP composite thin-walled tubes oblique loading energy absorption damage modes

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References

Kim

D-H

Choi

D-H

Kim

H-S

. Design optimization of a carbon fiber reinforced composite automotive lower arm. Compos B Eng 2014; 58: 400–407.

Beardmore

Johnson

. The potential for composites in structural automotive applications. Compos Sci Technol 1986; 26: 251–281.

Guan

Al-Husainy

Al Teneiji

, et al. Concentric and eccentric compression behaviour of recycled aggregate concrete filled steel tube columns strengthened with CFRP. Appl Compos Mater 2022; 29: 983–1005.

Sun

Wang

, et al. Experimental and numerical investigation into the crashworthiness of metal-foam-composite hybrid structures. Compos Struct 2019; 209: 535–547.

Ran

Ren

Jiang

. Design and assessments of gradient chamfer trigger for enhancing energy-absorption of CFRP square tube. Appl Compos Mater 2023; 30: 1333–1352.

Xie

Zhang

Kuang

, et al. Experimental investigation of normal and oblique impacts on CFRPs by high velocity steel sphere. Composites Part B 2016; 99: 483–493.

Liu

, et al. Experimental investigation into dynamic axial impact responses of double hat shaped CFRP tubes. Compos B Eng 2015; 79: 494–504.

Jiang

Zhang

, et al. Impact damage behavior of lightweight CFRP protection suspender on railway vehicles. Mater Des 2022; 213: 110332.

Jacob

. BMW counts on carbon fibre for its megacity vehicle. Reinforc Plast 2010; 54: 38–41.

10.

Lin

Zhang

, et al. Crushing characteristics comparison between Aluminum/CFRP and Aluminum/CFRP/Aluminum hybrid tubes. Polymers 2022; 14: 4034.

11.

Yang

Ren

. On energy absorption capability and controllable failure modes of CFRP circular tube using numerical simulation. Thin-Walled Struct 2024; 205: 112423.

12.

Wen

Zhao

, et al. Energy absorption of graded thin-walled origami tubes. Int J Mech Sci 2024; 282: 109609.

13.

Qin

Yang

, et al. Crashworthiness design of bionic-shell thin-walled tube under axial impact. J Mech Sci Technol 2023; 37: 3427–3436.

14.

Luo

Zhu

, et al. A new method to investigate the energy absorption characteristics of thin-walled metal circular tube using finite element analysis. Thin-Walled Struct 2015; 95: 24–30.

15.

Mamalis

Manolakos

Ioannidis

, et al. Crashworthy characteristics of axially statically compressed thin-walled square CFRP composite tubes: experimental. Compos Struct 2004; 63: 347–360.

16.

Zhu

Zhao

, et al. Energy-absorbing mechanisms and crashworthiness design of CFRP multi-cell structures. Compos Struct 2020; 233: 111631.

17.

Wang

Jin

Tian

. Axial compressive mechanical behavior of a CFRP-Confined composite member composed of bamboo strips and a thin-walled steel tube. Constr Build Mater 2024; 443: 137751.

18.

Alkhatib

Tarlochan

Hashem

, et al. Collapse behavior of thin-walled corrugated tapered tubes under oblique impact. Thin-Walled Struct 2018; 122: 510–528.

19.

Gao

Wang

, et al. Crushing analysis and multiobjective crashworthiness optimization of foam-filled ellipse tubes under oblique impact loading. Thin-Walled Struct 2016; 100: 105–112.

20.

Ying

Dai

Zhang

, et al. Multiobjective crashworthiness optimization of thin-walled structures with functionally graded strength under oblique impact loading. Thin-Walled Struct 2017; 117: 165–177.

21.

Guo

. Deformation and energy absorption of aluminum foam-filled tubes subjected to oblique loading. Int J Mech Sci 2012; 54: 48–56.

22.

Xiao

Zang

. Effects of aluminum honeycomb filler on crashworthiness of CFRP thin-walled beams under dynamic impact. Int J Crashworthiness 2022; 27: 985–994.

23.

Pan

Qiao

Wang

, et al. A novel damage mechanism analysis of integrally braided CFRP and CFRP/Aluminum hybrid composite tube subjected to transverse impact. Mater Des 2021; 206: 109815.

24.

Duarte

Krstulović-Opara

Vesenjak

. Axial crush behaviour of the aluminium alloy in-situ foam filled tubes with very low wall thickness. Compos Struct 2018; 192: 184–192.

25.

Zhu

Wang

Huo

, et al. Experimental and numerical investigation into axial compressive behaviour of thin-walled structures filled with foams and composite skeleton. Int J Mech Sci 2017; 122: 104–119.

26.

Liu

, et al. Crush response of CFRP square tube filled with aluminum honeycomb. Compos B Eng 2016; 98: 406–414.

27.

Xiao

Wen

, et al. Analysis of factors affecting crashworthiness of CFRP thin-walled square tubes filled with gradient aluminum foam. J of Materi Eng and Perform 2024; 33: 7334–7344.

28.

Xiao

Wen

Liang

. Failure modes and energy absorption mechanism of CFRP Thin-walled square beams filled with aluminum honeycomb under dynamic impact. Compos Struct 2021; 271: 114159.

29.

Zhu

Zhao

, et al. On energy-absorbing mechanisms and structural crashworthiness of laterally crushed thin-walled structures filled with aluminum foam and CFRP skeleton. Thin-Walled Struct 2021; 160: 107390.

30.

Isaac

Oluwole

. Energy absorption improvement of circular tubes with externally press-fitted ring around tube surface subjected under axial and oblique impact loading. Thin-Walled Struct 2016; 109: 352–366.

31.

Xiang

Yang

. Comparative analysis of energy absorption capacity of polygonal tubes, multi-cell tubes and honeycombs by utilizing key performance indicators. Mater Des 2016; 89: 689–696.

Study on multi-mode failure mechanisms and synergistic energy absorption effects of CFRP composite thin-walled tubes under oblique compression

Abstract

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