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Experimental and numerical study on splitting process of circular steel tube with enhanced crashworthiness performance.

Authors :
Li, Jian
Gao, Guangjun
Yu, Yao
Guan, Weiyuan
Source :
Thin-Walled Structures. Dec2019, Vol. 145, pN.PAG-N.PAG. 1p.
Publication Year :
2019

Abstract

The axial splitting of thin-walled tube is usually considered as an efficient deformation mode to dissipate impact energy thanks to its large stroke ratio. However, the low crushing force and the unstable deformation process, such as crack merging and branching, significantly limit its application in crashworthiness design. In this paper, we propose to enhance the deformation stability through introducing initial kerfs on the inner and outer surfaces of the circular steel tube in its axial direction to guide the propagation of cracks during the splitting process, thus we can improve the crushing force via a significant increase in tube wall thickness. To demonstrate the feasibility of the proposed method, quasi-static compressive experiments on single tube (inner radius r = 55 mm, wall thickness t = 5 mm) and doubled tube (consisted of two tubes with wall thickness t = 5 mm) with kerf depth δ = 0.5 mm split by a radiused die are performed, which exhibit stable deformation processes and high steady-state compression forces (103.32 kN for single tube, and 216.44 kN for doubled tube). Then, finite element simulations are conducted to model the tested samples. It is found that the experimentally observed deformation processes are well captured by simulations, and the relative errors of numerical steady-state compression forces in comparison to experimental results are 0.39% (single tube) and 1.90% (doubled tube), respectively. Finally, based on the validated numerical model, the influence of tube and die dimensions on its crashworthiness performance is discussed. It is observed that the axial load significantly depends on kerf depth, crack number, and tube thickness. The curling radius is nearly not affected by kerf depth, but it almost linearly depends on die radius. Moreover, the tube with larger wall thickness has a higher specific energy absorption. • The crashworthiness of circular tube during axial splitting process is enhanced through introducing initial kerfs on tube surfaces. • Thicker steel tubes with initial kerfs are experimentally demonstrated to have stable splitting processes and high crushing forces. • The introduction of oblique notches significantly weakens the crushing peak force without losing steady-state force. • Effect of the tube and die dimensions on its crashworthiness performance is numerically investigated. [ABSTRACT FROM AUTHOR]

Subjects

Subjects :
*TUBES
*STEEL tubes
*AXIAL loads

Details

Language :
English
ISSN :
02638231
Volume :
145
Database :
Academic Search Index
Journal :
Thin-Walled Structures
Publication Type :
Academic Journal
Accession number :
140989258
Full Text :
https://doi.org/10.1016/j.tws.2019.106406