Numerical Simulation and Experimental Study on Energy Absorption of
Numerical Simulation and Experimental Study on Energy Absorption of
Numerical Simulation and Experimental Study on Energy Absorption of
Numerical Simulation and Experimental Study on Energy Absorption of
Numerical Simulation and Experimental Study on Energy Absorption of
Numerical Simulation and Experimental Study on Energy Absorption of
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Experimental and numerical studies of foam-filled sections
Of interests in the study are the instantaneous crushing force, the mean crushing force, and the deformation mode of the aluminum foam-filled columns. The numerical study was conducted at the Impact and Crashworthiness Laboratory, MIT, while the experimental study was conducted at the Norwegian University of Science and Technology.
Experimental and numerical studies of foam-filled sections
A comprehensive experimental and numerical studies of the crush behavior of aluminum foam-filled sections undergoing axial compressive loading is performed. Non-linear dynamic finite element analyses are carried out to simulate quasi-static test conditions. The predicted crushing force and fold formation are found to be in good agreement with the experimental results.
Experimental and numerical studies of foam-filled sections
DOI: 10.1016/S0734-743X(99)00036-6 Corpus ID: 137381420; Experimental and numerical studies of foam-filled sections @article{Santosa2000ExperimentalAN, title={Experimental and numerical studies of foam-filled sections}, author={Sigit Puji Santosa and Tomasz Wierzbicki and Arve Gr{\o}nsund Hanssen and Magnus Langseth}, journal={International Journal of Impact Engineering}, year={2000}, volume ...
Experimental and Numerical Studies Of Foam-Filled Sections
A comprehensive experimental and numerical studies of the crush behavior of aluminum foam-filled sections undergoing axial compressive loading is performed.
Parametric study and numerical analysis of empty and foam-filled thin
Experimental and numerical predictions of the dynamic test of double-tapered tube filled with foam (ρ f =54.7 kg/m 3, t=0.76 mm, θ=10°, upper cross-section 100×50 mm 2). Table 6 . Comparison between the initial peaks and the mean dynamic load for foam-filled double tapered tube (experimental versus FE)
Experimental and numerical analyses of bending of foam-filled sections
Numerical simulations and experiments are conducted to study the bending crush behavior of thin-walled columns filled with closed-cell aluminum foam. A nonlinear dynamic finite element code was used to simulate quasi-static three point bending experiments. The aluminum foam filler provides a higher bending resistance by retarding inward fold formation at the compression flange Moreover, the ...
PDF Experimental and numerical analyses of bending of foam-filled sections
Potential applications of foam-filled sections for crash- worthy structures are suggested. 1 Introduction ... numerical and experimental studies that the axial resistance of a thin-walled column is improved dramatically by filling it with the aluminum foam, see [6], [7]. The objective of the present work is to study the bending response of thin ...
PDF Bending crush behavior of foam-filled sections
ratio [4]. The aluminum foam filling is intended to prevent or retard the sectional crush. A pilot study on planar bending response of thin-walled beams with a lightweight metal filler was recently computed by Santosa [5]. It has been shown through numerical and experimental studies that the
Aluminum foam-filled extrusions subjected to oblique loading
DOI: 10.1016/J.IJSOLSTR.2003.09.053 Corpus ID: 135936641; Aluminum foam-filled extrusions subjected to oblique loading: experimental and numerical study @article{Reyes2004AluminumFE, title={Aluminum foam-filled extrusions subjected to oblique loading: experimental and numerical study}, author={Aase Reyes and Odd Sture Hopperstad and Magnus Langseth}, journal={International Journal of Solids ...
Experimental and numerical analyses of bending of foam-filled sections
SummaryNumerical simulations and experiments are conducted to study the bending crush behavior of thin-walled columns filled with closed-cell aluminum foam. A nonlinear dynamic finite element code was used to simulate quasi-static three point bending experiments. The aluminum foam filler provides a higher bending resistance by retarding inward fold formation at the compression flange Moreover ...
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Of interests in the study are the instantaneous crushing force, the mean crushing force, and the deformation mode of the aluminum foam-filled columns. The numerical study was conducted at the Impact and Crashworthiness Laboratory, MIT, while the experimental study was conducted at the Norwegian University of Science and Technology.
A comprehensive experimental and numerical studies of the crush behavior of aluminum foam-filled sections undergoing axial compressive loading is performed. Non-linear dynamic finite element analyses are carried out to simulate quasi-static test conditions. The predicted crushing force and fold formation are found to be in good agreement with the experimental results.
DOI: 10.1016/S0734-743X(99)00036-6 Corpus ID: 137381420; Experimental and numerical studies of foam-filled sections @article{Santosa2000ExperimentalAN, title={Experimental and numerical studies of foam-filled sections}, author={Sigit Puji Santosa and Tomasz Wierzbicki and Arve Gr{\o}nsund Hanssen and Magnus Langseth}, journal={International Journal of Impact Engineering}, year={2000}, volume ...
A comprehensive experimental and numerical studies of the crush behavior of aluminum foam-filled sections undergoing axial compressive loading is performed.
Experimental and numerical predictions of the dynamic test of double-tapered tube filled with foam (ρ f =54.7 kg/m 3, t=0.76 mm, θ=10°, upper cross-section 100×50 mm 2). Table 6 . Comparison between the initial peaks and the mean dynamic load for foam-filled double tapered tube (experimental versus FE)
Numerical simulations and experiments are conducted to study the bending crush behavior of thin-walled columns filled with closed-cell aluminum foam. A nonlinear dynamic finite element code was used to simulate quasi-static three point bending experiments. The aluminum foam filler provides a higher bending resistance by retarding inward fold formation at the compression flange Moreover, the ...
Potential applications of foam-filled sections for crash- worthy structures are suggested. 1 Introduction ... numerical and experimental studies that the axial resistance of a thin-walled column is improved dramatically by filling it with the aluminum foam, see [6], [7]. The objective of the present work is to study the bending response of thin ...
ratio [4]. The aluminum foam filling is intended to prevent or retard the sectional crush. A pilot study on planar bending response of thin-walled beams with a lightweight metal filler was recently computed by Santosa [5]. It has been shown through numerical and experimental studies that the
DOI: 10.1016/J.IJSOLSTR.2003.09.053 Corpus ID: 135936641; Aluminum foam-filled extrusions subjected to oblique loading: experimental and numerical study @article{Reyes2004AluminumFE, title={Aluminum foam-filled extrusions subjected to oblique loading: experimental and numerical study}, author={Aase Reyes and Odd Sture Hopperstad and Magnus Langseth}, journal={International Journal of Solids ...
SummaryNumerical simulations and experiments are conducted to study the bending crush behavior of thin-walled columns filled with closed-cell aluminum foam. A nonlinear dynamic finite element code was used to simulate quasi-static three point bending experiments. The aluminum foam filler provides a higher bending resistance by retarding inward fold formation at the compression flange Moreover ...