Abstract The bare aluminum alloy (A5052) honeycomb is compressed in the longitudinal direction of the cell. Effect of the cell shape and the foil thickness on crush behavior is investigated by the numerical simulation using an explicit FEM code DYNA3D. Impact experiment using a drop-hammer apparatus whose impact velocity is 10 m/s and the corresponding quasi-static one are also performed. In the impact experiment, compressive stress increases with the hammer travel due to the air enclosed in the honeycomb cells. However, the nominal stress at the incipient compression is very similar for both the cases. In computation, numerical model of one ‘Y’ cross-sectional column is used and the impact velocity is 10 m/s. Internal angle of branch in ‘Y’ cross-section ranges from 30° to 180°. The numerical result shows that the cyclic buckling mode takes place in every case and that the crush strength is higher for smaller branch angle. It increases with the foil thickness. However, when the crush strength is evaluated with respect to the net cross-section of the material part only, it attains the maximum value when the cell shape is of regular hexagon. Numerical results are well consistent with the corresponding experimental ones.
[1]
T. Wierzbicki,et al.
Axial Crushing of Multicorner Sheet Metal Columns
,
1989
.
[2]
Yoshiaki Yasui,et al.
Dynamic axial crushing of multi-layer honeycomb panels and impact tensile behavior of the component members
,
2000
.
[3]
Tomasz Wierzbicki,et al.
Crushing analysis of metal honeycombs
,
1983
.
[4]
M. Yamashita,et al.
Crush behavior of honeycomb structure impacted by drop-hammer and its numerical analysis
,
1996
.
[5]
Han Zhao,et al.
CRUSHING BEHAVIOUR OF ALUMINIUM HONEYCOMBS UNDER IMPACT LOADING
,
1998
.
[6]
Enboa Wu,et al.
AXIAL CRUSH OF METALLIC HONEYCOMBS
,
1997
.
[7]
W. E. Baker,et al.
Static and dynamic properties of high-density metal honeycombs
,
1998
.
[8]
T. Belytschko,et al.
A stabilization procedure for the quadrilateral plate element with one-point quadrature
,
1983
.