论文信息 - Dynamic axial crushing of multilayer core structures of folded Chevron patterns

Dynamic axial crushing of multilayer core structures of folded Chevron patterns

The objective of this paper is to investigate our recently developed innovative sheet folding theory and manufacturing processes in designing impact energy absorbing structures with superior properties to existing structures, such as honeycomb, while achieving a volume reduction of between 40 and 50%. Initial results indicate that we can mathematically generate three-dimensional patterns and use our folding technology to produce such patterns by simply folding flat sheets of materials, resulting in significant cost savings. The three-dimensional patterns, folded from different sheet materials, can be used as cores for laminated structures for impact energy absorption applications, such as in high speed airdrops of heavy items and in improving crash worthiness of vehicle body and bumpers. The results of testing samples of the Chevron patterns (the simplest to fold from flat sheets) indicate that core structures made from this pattern will serve as absorbers of high velocity impact energy per unit volume when compared with the well known and typically used honeycomb structures.

Elsayed A. Elsayed | Basily B. Basily

[1] Shaik Jeelani,et al. Impact response of integrated hollow core sandwich composite panels , 2000 .

[2] Sankaran Mahadevan,et al. Damage tolerance reliability analysis of automotive spot-welded joints , 2003, Reliab. Eng. Syst. Saf..

[3] R. B. Aronson,et al. MATERIALS FOR THE NEXT-GENERATION VEHICLE , 1999 .

[4] Ulf G. Goranson,et al. Fatigue issues in aircraft maintenance and repairs , 1997 .

[5] Sankaran Mahadevan,et al. Damage tolerance approach for probabilistic pitting corrosion fatigue life prediction , 2001 .

[6] Yoshiaki Yasui,et al. Dynamic axial crushing of multi-layer honeycomb panels and impact tensile behavior of the component members , 2000 .

[7] John Dalsgaard Sørensen,et al. A probabilistic damage tolerance concept for welded joints. Part 1: data base and stochastic modelling , 2002 .

[8] W. Abramowicz,et al. Thin-walled structures as impact energy absorbers , 2003 .

[9] Carsten Proppe,et al. Probabilistic design of mechanical components , 2002 .

[10] J. Banhart,et al. Ultra-Lightweight Aluminum Foam Materials for Automotive Applications , 2000 .

[11] Jeom Kee Paik,et al. The strength characteristics of aluminum honeycomb sandwich panels , 1999 .

[12] Elsayed A. Elsayed,et al. A continuous folding process for sheet materials , 2004 .