[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/scs.2016.21.5.1145

Effects of foam core density and face-sheet thickness on the mechanical properties of aluminum foam sandwich

Yan, Chang (Key Laboratory of Road Construction Technology & Equipment of Chang'an University)
Song, Xuding (Key Laboratory of Road Construction Technology & Equipment of Chang'an University)

Publication Information

Steel and Composite Structures / v.21, no.5, 2016 , pp. 1145-1156 More about this Journal

Abstract

To study the effects of foam core density and face-sheet thickness on the mechanical properties and failure modes of aluminum foam sandwich (AFS) beam, especially when the aluminum foam core is made in aluminum alloy and the face sheet thickness is less than 1.5 mm, three-point bending tests were investigated experimentally by using WDW-50E electronic universal tensile testing machine. Load-displacement curves were recorded to understand the mechanical response and photographs were taken to capture the deformation process of the composite structures. Results demonstrated that when foam core was combined with face-sheet thickness of 0.8 mm, its carrying capacity improved with the increase of core density. But when the thickness of face-sheet increased from 0.8 mm to 1.2 mm, result was opposite. For AFS with the same core density, their carrying capacity increased with the face-sheet thickness, but failure modes of thin face-sheet AFS were completely different from the thick face-sheet AFS. There were three failure modes in the present research: yield damage of both core and bottom face-sheet (Failure mode I), yield damage of foam core (Failure mode II), debonding between the adhesive interface (Failure mode III).

Keywords

aluminum foam sandwich; three-point bending; mechanical properties; deformation; failure mode;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Ashby, M.F., Evans, A.G., Fleck, N.A., Gibson, L.J., Hutchinson, J.W. and Wadley, H.N.G. (2000), Metal Foams: A Design Guide Burlington, Butterworth-Heinemann, UK.
2	Banhart, J. (2001), "Manufacture, characterisation and application of cellular metals andmetal foams", Prog. Mater. Sci., 46(6), 559-632. DOI
3	Banhart, J. and Seeliger, H.W. (2008), "Aluminum foam sandwich panels: Manufacture, metallurgy and applications", Adv. Eng. Mater., 10(9), 793-802. DOI
4	Baumeister, J., Banhart, J. and Weber, M. (1997), "Aluminum foams for transport industry", Mater. Des., 18(4-6), 217-220. DOI
5	Crupi, V., Epasto, G. and Guglielmino, E. (2013), "Comparison of aluminum sandwiches for lightweight shipstructures: Honeycomb vs. foam", Marine Struct., 30, 74-96. DOI
6	D'Alessandro, V., Petrone, G., De Rosa, S. and Franco, F. (2014), "Modelling of aluminum foam sandwich panels", Smart Struct. Syst., Int. J., 13(4), 615-636. DOI
7	Duarte, I., Vesenjak, M. and Krstulovic-Opara, L. (2014), "Variation of quasi-static and dynamic compressive properties in a single aluminum foam block", Mater. Sci. Eng. A, 616, 171-182. DOI
8	Duarte, I., Vesenjak, M., Krstulovic-Opara, L., Anzel, I. and Ferreira, J.M.F. (2015), "Manufacturing and bending behavior of in situ foam-filled aluminum alloy tubes", Mater. Des., 66, 532-544. DOI
9	Duarte, I., Krstulovic-Opara, L. and Vesenjak, M. (2016), "Analysis of performance of in-situ carbon steel bar reinforced Al-alloy foams", Compos. Struct., 152, 432-443. DOI
10	Gibson, L.J. (2000), "Mechanical behavior of metallic foams", Annual Review of Materials Science, 30(1), 191-227. DOI
11	Gibson, L.J. and Ashby, M.F. (1997), Cellular Solids: Structure and Properties, Cambridge University Press, New York, NY, USA.
12	Huang, L., Wang, H., Yang, D.H., Ye, F. and Lu, Z.P. (2012), "Effects of scandium additions on mechanical properties of cellular Al-based foams", Intermetallics, 28, 71-76. DOI
13	Kabir, K., Vodenitcharova, T. and Hoffman, M. (2014), "Response of aluminum foam-cored sandwich panels to bending load", Composites: Part B, 64, 24-32. DOI
14	Liu, H., Cao, Z.K., Yao, G.C., Luo, H.J. and Zu, G.Y. (2013), "Performance of aluminum foam-steel panel sandwich composites subjectedto blast loading", Mater. Des., 47, 483-488. DOI
15	Lu, T.J. and Ong, J.M. (2001), "Characterization of close-celled cellular aluminum alloys", J. Mater. Sci., 36(11), 2773-2786. DOI
16	McCormack, T.M., Miller, R., Kesler, O. and Gibson, L.J. (2001), "Failure of sandwich beams with metallic foam cores", Int. J. Sol. Struct., 38(28-29), 4901-4920. DOI
17	Mohan, K., Hon, Y.T., Idapalapati, S. and Seowa, H.P. (2005), "Failure of sandwich beams consisting of alumina face sheet and aluminum foam core in bending", Mater. Sci. Eng. A, 409(1-2), 292-301. DOI
18	Nammi, S.K., Myler, P. and Edwards, G. (2010), "Finite element analysis of closed-cell aluminum foam under quasi-static loading", Mater. Des., 31(2), 712-722. DOI
19	Styles, M., Compston, P. and Kalyanasundaram, S. (2008), "Finite element modeling of core thickness effects in aluminum foam/composite sandwich structure under flexural loading", Compos. Struct., 86(1-3), 227-232. DOI
20	Ruan, D., Lu, G. and Wong, Y.C. (2010), "Quasi-static indentation tests on aluminum foam sandwich panels", Compos. Struct., 92(9), 2039-2046. DOI
21	Thoma, K., Schafer, F., Hiermaier, S. and Schneider, E. (2004), "An approach to achieve progress in spacecraft shielding", Adv. Space Res., 34(5), 1063-1075. DOI
22	Wang, N.Z., Chen, X., Li, A., Zhang, H.W. and Liu, Y. (2016), "Three-point bending performance of a new aluminum foam composite structure", Trans. Nonferrous Met. Soc. China, 26(2), 359-368. DOI
23	Wei, L., Yao, G.C., Zhang, X.M. and Luo, H.J. (2003), "Preparation of Foam Aluminum by Powder Metallurgy Process", J. Northeastern Univ. (Natural Science), 24(11), 1071-1074.
24	Zu, G., Song, B., Zhong, Z., Li, X., Mu, Y. and Yao, G. (2012), "Static three-point bending behavior of aluminum foam sandwich", J. Alloys Compounds, 540, 275-278. DOI
25	Zu, G.Y., Lu, R.H., Li, X.B., Zhong, Z., Ma, X.J., Han, M.B. and Yao, G.C. (2013), "Three-point bending behavior of aluminum foam sandwich with steel panel", Trans. Nonferrous Met. Soc. China, 23(9), 2491-2495. DOI

6	Chang Yan. (2018) Journal of Adhesion Science and Technology Effects of epoxy resin liquidity on the mechanical properties of aluminum foam sandwich / 32 (6) , 673
	Chang Yan. (2017) Journal of Composite Materials Flexural response of carbon fiber reinforced aluminum foam sandwich / , 002199831773516
2	(2016) Steel & Composite structures : an international journal Analytical solutions for sandwich plates considering permeation effect by 3-D elasticity theory / 25 (2) , 127
3	(2016) Steel & Composite structures : an international journal Bending behavior of aluminum foam sandwich with 304 stainless steel face-sheet / 25 (3) , 327
3	(2016) Steel & Composite structures : an international journal Geometrically nonlinear analysis of sandwich beams under low velocity impact: analytical and experimental investigation / 27 (3) , 273
3	(2016) Steel & Composite structures : an international journal Effects of face-sheet materials on the flexural behavior of aluminum foam sandwich / 29 (3) , 301
2	(2016) Steel & Composite structures : an international journal Energy absorption of foam-filled lattice composite cylinders under lateral compressive loading / 31 (2) , 133
6	(2016) The journal of sandwich structures & materials Viscoelastic behaviour investigation and new developed laboratory slamming test on foam core sandwich / 22 (6) , 2049
19	(2016) Proceedings of the Institution of Mechanical Engineers. Part C : Journal of mechanical engineering science Effect of infill pattern, density and material type of 3D printed cubic structure under quasi-static loading / 235 (19) , 4254