Sage Journals: Discover world-class research

Abstract

A new material, which has a high energy-absorbing capacity and light weight, has been developed by cold isostatic pressing and sintering. Powder particles of a polymer coated with a nickel-phosphorus alloy layer using electroless plating were pressed into pellets and sintered in a vacuum at a high temperature. A metallic closed cellular material containing an organic material was then fabricated.

The physical, mechanical and ultrasonic properties of this material were measured. The density of this material is about 1.3-2.7 g/cm³. The compressive tests showed that the Young’s modulus of this material is very low and the stress-strain curves of this material have a linear elastic part, a plateau part and a wavy part. These results indicate that this material has a high energy absorbing capacity. The Young’s modulus of this material increases with an increase in the sintering temperature and the thickness of the cell walls. Ultrasonic measurements showed that the attenuation coefficient of this material is very large. These results also indicate that this metallic closed cellular material can be used for the materials in passive damping and energy-absorbing systems.

Get full access to this article

View all access options for this article.

References

Beals, J.T. and Thompson, M.S. (1997). Density gradient effect on aluminum foam compression behaviour. J. Mater. Sci., 32: 3595-3600.

Benhart, J. and Baumeister, J. (1998). Deformation characteristics of metal foams. J. Mater. Sci., 33(18-998): 1431-1440.

Chan, N. and Evans, K.E. (1997). Fabrication methods for auxetic foams. J. Mater. Sci., 32: 5945-5953.

Davies, G.J. and Zhen, S. (1983). Metallic foams: their production, properties and applications. J. Mater. Sci., 18: 1897-1911.

David, D.J. , Phillip, A.P. and Wadly, H.N.G. (June 1998). Novel hollow powder porous structure. Materials Research Society. Porous and Cellular Materials for Structural Applications. Warrendate. pp. 205-210.

Gibson, L.J. and Ashby, M.F. (1988). Cellular Solids-Structure and Properties. Oxford: Pergamon Press, pp. 42-68.

Hurtsz, K.M. , Clark, J.L. , Nagel, A.R. , Hardwicke, C.U. , Lee, K.J. , Cochran, J.K. and Sanders, Jr. T.H. (1998). Steel and Titanium hollow sphere forms. Mat. Res. Soc. Symp. Proc., 521: 191-203.

Kishimoto, S. and Shinya, N. (2000). Development of metallic closed cellular materials containing Polymers. Mater. Design, 21: 575-578.

Maiti, S.K. , Gibson, L.J. and Ashby, M.F. (1988). Deformation and energy absorpton diagrams for cellular solid. Acta Metall., 32: 1963-1975.

10.

Mukai, T. , Kanahashi, H. , Miyoshi, T. , Mabuchi, M. , Nieh, T.G. and Higashi, B K. Experimental study of energy absorption in a closed-celled aluminum foam under dynamic loading. Scripta Mater., 40: 921-927.

11.

Sugiyana, Y , Meyer, Y. , He, M.Y. , Bert-Smith, H. , Grenstedt, J. and Evans, A.E. (1997). On the mechanical performance of closed cell Al alloy foams. Acta Mater., 45: 5245-5259.

Mechanical Property of Metallic Closed Cellular Materials Containing Organic Material for Passive Damping and Energy-Absorbing Systems

Abstract

Get full access to this article

References