Static and dynamic crushing of circular aluminium extrusions with aluminium foam filler

“…5(a) and (b). A similar deformation behavior was also previously observed in empty Al tubes and it was proposed to be due to the influence of the axisymmetric trigger on the first fold [2]. Totally 11-12, 8-9 and 5-6 diamond folds formed in 50, 40 and 27 mm long Al empty tubes, respectively.…”

“…Studies on crushing behavior of Al honeycomb and foam filled box columns also showed that the effect of filling on the column crushing load was similar when the strong axis of honeycomb was through and normal to the compression axis, proving that both axial and transverse strength of the filler were effective in increasing the crushing load of filled tube [6]. Hannsen et al [2,4] developed an equation for the average crushing load of foam filled (P af ) columns by including contributions of the average crushing load of empty tube (P ae ), foam plateau stress (r pl ) and interaction effect. The equation was found to be well agreed with experimental results and is given as…”

“…It has been shown that when aluminum and steel metal tubes are filled with light weight core materials such as Al closed cell foams, there exists an interaction effect between tube wall and foam filler [1][2][3][4][5][6]. The crushing loads of foam filled tubes are therefore found to be higher than the sum of the crushing loads of foam (alone) and tube (alone) mainly due to this effect.…”

“…Studies on the crushing behavior of foam filled tubes were particularly aimed at determining the effect of foam filling on the average crushing load and the specific energy absorption [1,2,5,[8][9][10]. In designing with foam filled tubes, knowledge of upper and lower limits of the strengthening may be however required for the accurate prediction of the specific energy absorption of any tube-filler combination.…”

Predicting energy absorption in a foam-filled thin-walled aluminum tube based on experimentally determined strengthening coefficient

“…5(a) and (b). A similar deformation behavior was also previously observed in empty Al tubes and it was proposed to be due to the influence of the axisymmetric trigger on the first fold [2]. Totally 11-12, 8-9 and 5-6 diamond folds formed in 50, 40 and 27 mm long Al empty tubes, respectively.…”

“…Studies on crushing behavior of Al honeycomb and foam filled box columns also showed that the effect of filling on the column crushing load was similar when the strong axis of honeycomb was through and normal to the compression axis, proving that both axial and transverse strength of the filler were effective in increasing the crushing load of filled tube [6]. Hannsen et al [2,4] developed an equation for the average crushing load of foam filled (P af ) columns by including contributions of the average crushing load of empty tube (P ae ), foam plateau stress (r pl ) and interaction effect. The equation was found to be well agreed with experimental results and is given as…”

“…It has been shown that when aluminum and steel metal tubes are filled with light weight core materials such as Al closed cell foams, there exists an interaction effect between tube wall and foam filler [1][2][3][4][5][6]. The crushing loads of foam filled tubes are therefore found to be higher than the sum of the crushing loads of foam (alone) and tube (alone) mainly due to this effect.…”

“…Studies on the crushing behavior of foam filled tubes were particularly aimed at determining the effect of foam filling on the average crushing load and the specific energy absorption [1,2,5,[8][9][10]. In designing with foam filled tubes, knowledge of upper and lower limits of the strengthening may be however required for the accurate prediction of the specific energy absorption of any tube-filler combination.…”

Predicting energy absorption in a foam-filled thin-walled aluminum tube based on experimentally determined strengthening coefficient

“…6c and d. The switch in the deformation mode was attributed to the wall thickening effect of foam filling [25]. It is noted that the deformed shapes and load-displacement curves of FEM show good agreement with the experimental results.…”

Modeling the progressive axial crushing of foam-filled aluminum tubes using smooth particle hydrodynamics and coupled finite element model/smooth particle hydrodynamics

Axial Impact Performances of Composite Aluminum Foam Tubes