On the Energy Absorption Capability of Metallic Tubes Subjected to the Radial Wall Crushing Process

Year 2021, Volume: 9 Issue: 2, 238 - 242, 28.05.2021

Yaşar Kahraman

https://doi.org/10.21541/apjes.855080

Abstract

Metallic tubes, under axial loading, are frequently preferred in many different industries due to their high energy absorption efficiency. The studies to increase the energy absorption capacity (EAC) of these structures are still up to date. In this study, the deformation behavior and EAC of regionally pre-deformed identical aluminum and steel tubes under axial loading were investigated experimentally. Regional strength increase in tubes was obtained by the radial wall crushing (RWC) process. The RWC process is carried out by radially crushing the desired areas of the metallic tube from the outside with the aid of a specially designed device. Strengthening (hardening) occurs in the pre-deformed regions and as a result, the EAC of the metallic tubes can be increased. It is also noteworthy that the increase in absorbed energy is provided without reinforcement materials. When the experimental results were examined, it was seen that the RWC increased the energy absorption value of aluminum and steel tubes approximately 23% and by 33%, respectively. In addition to energy increases, the folding beginning of the metallic tubes can also be directed by using the RWC process.

Keywords

Radial wall crushing, Aluminum, Steel tubular, Energy absorption capability

References

• [1].J. Alexander, “An approximate analysis of the collapse of thin cylindrical shells under axial loading”, The Quarterly Journal of Mechanics and Applied Mathematics, 13(1), pp.10-15, 1960.
• [2].D. Al Galib and A. Limam, “Experimental and numerical investigation of static and dynamic axial crushing of circular aluminum tubes”, Thin-Walled Structures, 42(8), pp.1103-1137, 2004.
• [3].R. Baleh and A. Abdul-Latif, “Quasi-static biaxial plastic buckling of tubular structures used as an energy absorber”, Journal of Applied Mechanics, 74(4), pp.628-635, 2006.
• [4].Z. Tang, S. Liu and Z. Zhang, “Analysis of energy absorption characteristics of cylindrical multi-cell columns”, Thin-Walled Structures, 62, pp.75-84, 2013.
• [5].M. Yalçın, O. Mete and K. Genel, “Axial crushing behavior of circular aluminum tubes”, Materials Testing, 61(8), pp.749-754, 2019.
• [6].A. Baroutaji, M. Gilchrist, D. Smyth and A. Olabi, “Crush analysis and multi-objective optimization design for circular tube under quasi-static lateral loading”, Thin-Walled Structures, 86, pp.121-131, 2015.
• [7].S. Guillow, G. Lu and R. Grzebieta,. “Quasi-static axial compression of thin-walled circular aluminium tubes”, International Journal of Mechanical Sciences, 43(9), pp.2103-2123, 2001.
• [8].M. Langseth, O. Hopperstad and A. Hanssen, “Crash behaviour of thin-walled aluminium members”, Thin-Walled Structures, 32(1-3), pp.127-150, 1998.
• [9].M. Yalçın and K. Genel, “On the axial crush performance of PVC foam-filled aluminum/CFRP hybrid circular tube”, Sakarya University Journal of Science, pp.1154-1162, 2019.
• [10].M. Bambach and M. Elchalakani, “Plastic mechanism analysis of steel SHS strengthened with CFRP under large axial deformation”, Thin-Walled Structures, 45(2), pp.159-170, 2007.
• [11].G. Hatzigeorgiou and D. Beskos, “Minimum cost design of fibre-reinforced concrete-filled steel tubular columns” Journal of Constructional Steel Research, 61(2), pp.167-182, 2005.
• [12].A. Henningsgaard and C. Yanchar,. “Carbon fiber reinforced steel spaceframe techniques”, SAE Technical Paper Series, 1998.
• [13].H. Kim, D. Shin, J. Lee and J. Kwon, “Crashworthiness of aluminum/CFRP square hollow section beam under axial impact loading for crash box application”, Composite Structures, 112, pp.1-10, 2014.
• [14].M. Yalçın and K. Genel, “On the axial deformation characteristic of PVC foam-filled circular aluminium tube: Effect of radially-graded foam filling”, Thin-Walled Structures, 144, p.106335, 2019.
• [15].T. Reddy and R. Wall, “Axial compression of foam-filled thin-walled circular tubes”, International Journal of Impact Engineering, 7(2), pp.151-166, 1988.
• [16].F. Mokhtarnezhad, S. Salehghaffari and M. Tajdari, “Improving the crashworthiness characteristics of cylindrical tubes subjected to axial compression by cutting wide grooves from their outer surface”, International Journal of Crashworthiness, 14(6), pp.601-611, 2009.
• [17].S. Salehghaffari, M. Tajdari, M. Panahi and F. Mokhtarnezhad, “Attempts to improve energy absorption characteristics of circular metal tubes subjected to axial loading”, Thin-Walled Structures, 48(6), pp.379-390, 2010.
• [18].A. Darvizeh, M. Darvizeh, R. Ansari and A. Meshkinzar, “Effect of low density, low strength polyurethane foam on the energy absorption characteristics of circumferentially grooved thick-walled circular tubes”, Thin-Walled Structures, 71, pp.81-90, 2013.
• [19].G. Daneshi. and S. Hosseinipour, “Elastic–plastic theory for initial buckling load of thin-walled grooved tubes under axial compression”, Journal of Materials Processing Technology, 125-126, pp.826-832, 2002.
• [20].S. Lee, C. Hahn, M. Rhee and J. Oh, “Effect of triggering on the energy absorption capacity of axially compressed aluminum tubes”, Materials & Design, 20(1), pp.31-40, 1999.