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Bending behavior of cenosphere aluminum matrix syntactic foam-filled circular tubes
Highlights New cenosphere foam-filled tubes are developed for higher energy absorption capacity. The effects of wall thickness, particle sizes, and filled-ratios are investigated. Specimens failed with different failure modes. Parametric numerical studies are conducted to compare and extend results.
Abstract Thin-walled tubes filled with aluminum foam have been widely studied in the field of energy absorption. Embedding fly ash cenospheres into aluminum matrix provides a low-cost, yet effective solution to enhance its strength and energy absorption capability significantly, as shown in the authors’ previous study. In this paper, the bending performance of the developed cenosphere Al matrix syntactic foam (SF) is further investigated, and its dependence on geometrical features, including thickness of tube and diameter of cenospheres, as well as filled ratios is established. The result that bending resistance and energy absorption performance of the tubes are mainly governed by wall thickness and filled ratios is acknowledged. In parallel, numerical models were developed in LS-DYNA, and the simulation results were in good agreement with the test results, which suggest that such developed SF potentially will have extensive practical applications.
Bending behavior of cenosphere aluminum matrix syntactic foam-filled circular tubes
Highlights New cenosphere foam-filled tubes are developed for higher energy absorption capacity. The effects of wall thickness, particle sizes, and filled-ratios are investigated. Specimens failed with different failure modes. Parametric numerical studies are conducted to compare and extend results.
Abstract Thin-walled tubes filled with aluminum foam have been widely studied in the field of energy absorption. Embedding fly ash cenospheres into aluminum matrix provides a low-cost, yet effective solution to enhance its strength and energy absorption capability significantly, as shown in the authors’ previous study. In this paper, the bending performance of the developed cenosphere Al matrix syntactic foam (SF) is further investigated, and its dependence on geometrical features, including thickness of tube and diameter of cenospheres, as well as filled ratios is established. The result that bending resistance and energy absorption performance of the tubes are mainly governed by wall thickness and filled ratios is acknowledged. In parallel, numerical models were developed in LS-DYNA, and the simulation results were in good agreement with the test results, which suggest that such developed SF potentially will have extensive practical applications.
Bending behavior of cenosphere aluminum matrix syntactic foam-filled circular tubes
Zhang, Boyi (Autor:in) / Zhang, Jian (Autor:in) / Wang, Li (Autor:in) / Jiang, Yuexin (Autor:in) / Wang, Wei (Autor:in) / Wu, Gaohui (Autor:in)
Engineering Structures ; 243
29.05.2021
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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