Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Energy absorption mechanism of axially-varying thickness (AVT) multicell thin-walled structures under out-of-plane loading
Highlights Propose a novel multicell structure with axially-varying thickness (AVT). Conduct the quasi-static compression experimental test of AVT nine-cell and five-cell tubes. Compare the crashworthiness of uniform thickness (UT) and AVT columns numerically. Derive an analytical expression of the mean crushing force for AVT multicell tubes.
Abstract Multicell columns have becoming increasingly attractive in crashworthiness applications due to their high efficiency of material utilization. Meanwhile, an urgent need exists to develop new structures to achieve the aim of light weight without sacrificing crashworthiness. A novel multicell column with axially-varying thickness (AVT) is proposed in this study. Quasi-static crushing tests were firstly performed experimentally to investigate crushing behaviors. Subsequently, corresponding numerical simulation models were built, validated, and used to conduct a parametric study. Finally, analytical equations for the mean crushing force for AVT multicell columns were derived and used to assess the crashworthiness of multicell columns according to SFE (super folding element) method. The numerical results agreed well with experimental results in terms of deformation mode and crushing forces, and the theoretical predictions were validated by the experimental results. It was concluded that the thickness gradient of AVT multicell columns could effectively reduce the initial peak crushing force while maintaining energy absorption capacity over a long crushing distance. From this perspective, the AVT multicell columns demonstrated competitive advantages over uniform columns as energy absorbers. Moreover, the analytical prediction could be a powerful tool for designing crashworthy structures.
Energy absorption mechanism of axially-varying thickness (AVT) multicell thin-walled structures under out-of-plane loading
Highlights Propose a novel multicell structure with axially-varying thickness (AVT). Conduct the quasi-static compression experimental test of AVT nine-cell and five-cell tubes. Compare the crashworthiness of uniform thickness (UT) and AVT columns numerically. Derive an analytical expression of the mean crushing force for AVT multicell tubes.
Abstract Multicell columns have becoming increasingly attractive in crashworthiness applications due to their high efficiency of material utilization. Meanwhile, an urgent need exists to develop new structures to achieve the aim of light weight without sacrificing crashworthiness. A novel multicell column with axially-varying thickness (AVT) is proposed in this study. Quasi-static crushing tests were firstly performed experimentally to investigate crushing behaviors. Subsequently, corresponding numerical simulation models were built, validated, and used to conduct a parametric study. Finally, analytical equations for the mean crushing force for AVT multicell columns were derived and used to assess the crashworthiness of multicell columns according to SFE (super folding element) method. The numerical results agreed well with experimental results in terms of deformation mode and crushing forces, and the theoretical predictions were validated by the experimental results. It was concluded that the thickness gradient of AVT multicell columns could effectively reduce the initial peak crushing force while maintaining energy absorption capacity over a long crushing distance. From this perspective, the AVT multicell columns demonstrated competitive advantages over uniform columns as energy absorbers. Moreover, the analytical prediction could be a powerful tool for designing crashworthy structures.
Energy absorption mechanism of axially-varying thickness (AVT) multicell thin-walled structures under out-of-plane loading
Pang, Tong (Autor:in) / Zheng, Gang (Autor:in) / Fang, Jianguang (Autor:in) / Ruan, Dong (Autor:in) / Sun, Guangyong (Autor:in)
Engineering Structures ; 196
23.04.2019
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
Energy absorption in axially loaded square thin-walled aluminium extrusions
| British Library Conference Proceedings | 1994