A numerical study of the energy-absorption characteristics of metal tube-reinforced polymer foams

This article investigates the energy-absorbing behaviour of lightweight foam structures reinforced with aluminium and steel cylindrical tubes. Initial testing focuses on establishing the influence of the inner diameter to thickness ratio (D/t) of the metal tubes on their specific energy-absorption characteristics under quasistatic compression and low velocity impact loading. Following this, individual metal tubes are embedded in a range of crosslinked PVC foams, and the specific energy-absorption characteristics of these reinforced systems are determined. The effect of increasing the number of tubes on the energy-absorbing response of the tube-reinforced structures is also studied. The crushing responses of both aluminium and steel structures are then predicted using the finite element analysis package Abaqus/Explicit, and the predictions of the load–displacement responses and the associated failure modes are compared to experimental results. Agreement between the numerical predictions and the experimental data is good across the range of structures investigated, with the model accurately predicting the compression response and failure characteristics observed in the structures. It has been shown that the stiffness of the foam does not significantly alter the energy-absorbing behaviour of the stiffer metal tubes, suggesting that the density of the foam should be as low as possible, whilst maintaining the structural integrity of the part.

[1]  J. M. Alexander AN APPROXIMATE ANALYSIS OF THE COLLAPSE OF THIN CYLINDRICAL SHELLS UNDER AXIAL LOADING , 1960 .

[2]  R. G. Davies,et al.  The Effect of Strain-Rate Upon the Tensile Deformation of Materials , 1975 .

[3]  S. Reid PLASTIC DEFORMATION MECHANISMS IN AXIALLY COMPRESSED METAL TUBES USED AS IMPACT ENERGY ABSORBERS , 1993 .

[4]  J. Carruthers,et al.  The influence of FRP inserts on the energy absorption of a foam-cored sandwich panel , 1997 .

[5]  F. Rammerstorfer,et al.  Crushing of axially compressed steel tubes filled with aluminium foam , 1997 .

[6]  Vikram Deshpande,et al.  Multi-axial yield behaviour of polymer foams , 2001 .

[7]  T. Wierzbicki,et al.  Relative merits of single-cell, multi-cell and foam-filled thin-walled structures in energy absorption , 2001 .

[8]  H. Dell,et al.  A comprehensive failure model for crashworthiness simulation of aluminium extrusions , 2004 .

[9]  Ali Limam,et al.  Experimental and numerical investigation of static and dynamic axial crushing of circular aluminum tubes , 2004 .

[10]  N. Jones,et al.  DYNAMIC AXIAL CRUSHING OF ALUMINIUM ALLOY 6063 -T6 CIRCULAR TUBES , 2004 .

[11]  H. Kavi,et al.  Predicting energy absorption in a foam-filled thin-walled aluminum tube based on experimentally determined strengthening coefficient , 2006 .

[12]  Venkatesh,et al.  A study of the influence of diameter and wall thickness of cylindrical tubes on their axial collapse , 2006 .

[13]  C. Wen,et al.  Crushing Modes of Aluminium Tubes under Axial Compression , 2014, 1408.5390.

[14]  Wenyi Yan,et al.  Crushing simulation of foam-filled aluminium tubes , 2007 .

[15]  Norman Jones,et al.  Energy-absorbing effectiveness factor , 2010 .

[16]  Norman Jones Structural Impact: Author Index , 2011 .

[17]  Gianpietro Del Piero,et al.  The influence of viscosity on the response of open-cell polymeric foams in uniaxial compression: experiments and theoretical model , 2012 .

[18]  Z. Guan,et al.  The energy-absorption characteristics of metal tube-reinforced polymer foams , 2015 .