ANALYSIS OF WARM POWDER COMPACTION PROCESS USING FINITE ELEMENT MODEL

Authors

  • A. K. Ariffin A. K. Ariffin Dept. of Mechanical and Materials Engineering Universiti Kebangsaan Malaysia 43600 Bangi, Selangor Darul Ehsan MALAYSIA
  • Md. Mujibur Rahman Dept. of Mechanical and Materials Engineering Universiti Kebangsaan Malaysia 43600 Bangi, Selangor Darul Ehsan MALAYSIA

Keywords:

Warm compaction, finite element method, staggered-incremental-iterative.

Abstract

This paper presents the development of the finite element model for the simulation of a full cycle of warm powder compaction process. In the modelling of compaction phase, the behaviour of powder is assumed to be rate independent thermo-elastoplastic material and the process has been described by a large displacement based finite element fo rmulation. Two constit utive relations namely Mohr-Coulomb yie ld criterion and Elliptical Cap yield criterion have been used to describe the mechanical behaviour of the powder during the compaction . The staggered-incremental-iterative solution strategy has been established to solve the non-linear systems of equations. The numerical results are validated by experiments, which show a good agreement between the simulation and experiment data.

References

Hoganas , A. B., 1998, Hoganas hand book for warm compaction.

Jogata, A., Dawson, P. R. & Jenkins, J. T., 1988, An Anisotropic Continuum Model for the Sintering and Compaction of Powder Packing, Mechanics of Materials, 7, pp. 255-269.

Brown, S. B. and Weber, G. G. A., 1988, A Constitutive Model for the Compaction of Metal Powders, Modem Development in Powder Metallurgy, vol. l8-2 1, pp.465-476.

Oldenburg, M. and Haggbald, H. A., 1994, Material Parameter Fitting in an Integrated Environment for Analysis of Iron Powder Pressing, Powder Metallurgy World Congress, voLl, June, Paris, pp.693 -696.

Hisatsune, T., Tabata, T. & Masaki, S., 1991, A Yield Criterion of Porous Material With Anisotropy Caused By Geometry or Distribution of Pores, 1. Eng . Mat. Tech., Trans. ASME, Oct., vol. ll3, pp.425-429.

Cytermann, R. & Geva, R., 1987, Powder Metallurgy, Development of New Model for Compaction of Powders, vol. 30, no.4, pp.256-260 .

May, 1. M., Naji, 1. H. and Ganaba, T. H., 1988, Displacement Control for the non-linear analysis of reinforced concrete structures. Engineering Computations, 5, 266.

McMeeking, R. M. and Rice, 1. R., 1975, Finite Element formulation for problems of large elastic -plastic deformation . Int. J. of Solid Structures, 11, 601.

Brekelmans, W. A. M., Janssen, 1. D., Van de Ven, A. A. F. & de With, G., 1991, An Eulerian Approach for Die Compaction Processes, Int. J. Num. Meth. Eng., vo1.31, pp.509-524.

Park, S., Han, H. N., Oh, H. K.and Lee, N. D., 1999. Modelfor Compaction of Metal Powders, International Journal of Mechanical Sciences. 41: 121-141.

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Published

2018-05-14

How to Cite

A. K. Ariffin, A. K. A., & Rahman, M. M. (2018). ANALYSIS OF WARM POWDER COMPACTION PROCESS USING FINITE ELEMENT MODEL. Jurnal Mekanikal, 12(2). Retrieved from https://jurnalmekanikal.utm.my/index.php/jurnalmekanikal/article/view/257

Issue

Issue 12: December 2001

Section

Mechanical

License

Copyright of articles that appear in Jurnal Mekanikal belongs exclusively to Penerbit Universiti Teknologi Malaysia (Penerbit UTM Press). This copyright covers the rights to reproduce the article, including reprints, electronic reproductions or any other reproductions of similar nature.

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