Modeling the Progressive Axial Crushing of Foam-Filled Aluminum Tubes Using Smooth Particle Hydrodynamics and Coupled Finite Element Model/Smooth Particle Hydrodynamics
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Abstract
As alternatives to the classical finite element model (FEM), a meshless smooth particle hydrodynamics (SPH) method, in which the discrete particles represent a solid domain, and a coupled FEM/SPH modeling technique were investigated for the numerical simulation of the quasi-static axial crushing of polystyrene foam-filled aluminum thin-walled aluminum tubes. The results of numerical simulations, load-deformation histories, fold lengths and specific absorbed energies, were found to show satisfactory correlations with those of experiments and FEM. The results further proved the capabilities of the SPH Method and coupled FEM/SPH modeling technique in predicting the crushing behavior of foam-filled thin-walled tubes.
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Keywords
Energy absorption, Smooth particle hydrodynamics, Coupling phenomena, Foam-filled tubes, Polystyrene foam, Polystyrene foam, Foam-filled tubes, Energy absorption, Smooth particle hydrodynamics, Coupling phenomena
Fields of Science
0203 mechanical engineering, 02 engineering and technology
Citation
Aktay, L., Johnson, A. F., Toksoy, A. K., Kröplin, B. H., and Güden, M. (2008). Modeling the progressive axial crushing of foam-filled aluminum tubes using smooth particle hydrodynamics and coupled finite element model/smooth particle hydrodynamics. Materials & Design, 29(3), 569-575. doi: 10.1016/j.matdes.2007.03.010
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13
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29
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3
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569
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575
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