Crashworthiness investigation of kagome honeycomb sandwich cylindrical column under axial crushing loads

For the classic thin-walled energy absorber, the energy dissipation during a collision is concentrated over relatively narrow zones. This means that a great deal of materials of the columns do not participate in the plastic deformation or not enter into the large plastic deformation stage. To expand the plastic deformation zones and improve the energy absorption efficiency, a new type of kagome honeycomb sandwich bitubal circular column is presented in this paper. This innovative impact energy absorber is made of two circular aluminum tubes filled with core shaped as a large-cell kagome lattice. The interaction effect, deformation mode and energy absorption characteristics of the composite structure are investigated numerically. Observing the collapsing process, it is found that the kagome lattices buckle first, which triggers the outer and inner skin tubes to fold locally. This behavior increases the plastic deformation areas. Moreover, the presence of the outer and inner tubes strengthens the buckling capacity of kagome cell. Furthermore, the folded tube walls intrude into the gap of the honeycomb cell, which further retards the collapse of the honeycomb cell. So the interaction effects between the honeycomb and column walls greatly improve the energy absorption efficiency. In addition, the effects of geometrical parameters of the kagome honeycomb on the structural crashworthiness are studied. It is found that the cell wall thickness and cell distribution (cell number in the circumferential direction) have distinct effects on the specific energy absorption. Besides, we also studied the foam-filled column with the same foam density as the kagome honeycomb and compared it with the kagome sandwich structure. It is found that the kagome sandwich column has higher mean crash force and better energy absorption characteristics.

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

[2]  Tongxi Yu,et al.  Energy Absorption of Structures and Materials , 2003 .

[3]  T. Wierzbicki,et al.  On the Crushing Mechanics of Thin-Walled Structures , 1983 .

[4]  O. Hopperstad,et al.  Constitutive modeling of aluminum foam including fracture and statistical variation of density , 2003 .

[5]  Norman Jones,et al.  Dynamic axial crushing of circular tubes , 1984 .

[6]  Tomasz Wierzbicki,et al.  Crash behavior of box columns filled with aluminum honeycomb or foam , 1998 .

[7]  O. Hopperstad,et al.  Modeling of material failure in foam-based components , 2004 .

[8]  M. Langseth,et al.  Static crushing of square aluminium extrusions with aluminium foam filler , 1999 .

[9]  W. Abramowicz,et al.  Dynamic axial crushing of square tubes , 1984 .

[10]  N. Fleck,et al.  Isotropic constitutive models for metallic foams , 2000 .

[11]  H. Zarei,et al.  Optimum honeycomb filled crash absorber design , 2008 .

[12]  Tomasz Wierzbicki,et al.  Effect of an ultralight metal filler on the bending collapse behavior of thin-walled prismatic columns , 1999 .

[13]  T. Y. Reddy,et al.  Axial compression of foam-filled thin-walled circular tubes , 1988 .

[14]  Shaker A. Meguid,et al.  On the crush behaviour of ultralight foam-filled structures , 2004 .

[15]  O. Hopperstad,et al.  Static and dynamic crushing of square aluminium extrusions with aluminium foam filler , 2000 .

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

[17]  Tomasz Wierzbicki,et al.  Experimental and numerical analyses of bending of foam-filled sections , 2001 .

[18]  T. Wierzbicki,et al.  Axial Crushing of Multicorner Sheet Metal Columns , 1989 .

[19]  O. Hopperstad,et al.  Validation of constitutive models applicable to aluminium foams , 2002 .

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