Infiltration and solidification/remelting of a pure metal in a two-dimensional porous preform are modeled numerically. It is assumed that under the action of constant applied pressure, the flow of liquid metal through the preform is within the range of the validity of Darcy’s Law. The distinguishing feature of this flow and heat transfer problem is the existence of two moving fronts: the infiltration front and the remelting front. The governing momentum and energy equations are nondimensionalized and cast into a Body-Fitted Coordinates (BFC) systems to deal with the transient and irregular physical domains. The dimensionless groups that govern the infiltration and remelting processes are: the dimensionless pressure difference, the dimensionless melting temperature, the preform permeability ratio, porosity, and the geometric parameters (inlet gate size, and the preform aspect ratio). A computational code has been developed to solve the problem and is verified by using the available published results. The key parameters describing the physical phenomena, i.e., the infiltration front and remelting front evolution, the total infiltration time, and the remelting region size, are presented as a function of the operating variables for two different aspect ratios. The results can be used to optimize the infiltration processing of Metal–Matrix Composites and other related manufacturing processes.

1.
Calhoun
R. B.
, and
Mortensen
A.
,
1992
, “
Infiltration of Fibrous Preform by a Pure Metal: Part IV. Morphological Stability of the Remelting Front
,”
Metall. Trans. A
, Vol.
23A
, pp.
2291
2299
.
2.
Clyne
T. W.
, and
Mason
J. F.
,
1987
, “
The Squeeze Infiltration Process for Fabrication of Metal-Matrix Composites
,”
Metall. Trans. A
, Vol.
18A
, pp.
1519
1530
.
3.
Coulter, J. P., Smith, B. F., and Guceri, S. I., 1987, “Experimental and Numerical Analysis of Resin Impregnation During the Manufacturing of Composite Materials,” Proceedings of the American Society for Composites, 2nd Technical Conference, Newark, DE, pp. 209–217.
4.
Coulter
J. P.
, and
Guceri
S. I.
,
1988
, “
Resin Impregnation During the Manufacturing of Composite Materials Subject to Prescribed Injection Rate
,”
J. of Reinforced Plastics and Composites
, Vol.
7
, pp.
200
219
.
5.
Donomoto, T., Miura, N., Funatani, K., and Miyake, N., 1983, “Ceramic Fiber Reinforced Piston for High Performance in Diesel Engine,” SAE Technical Paper No. 83052.
6.
Fukunaga
H.
, and
Goda
K.
,
1985
, “
Formation and Role of the Solidified Layer on a Fiber During the Fabrication of Fiber Reinforced Metal by the Liquid Process
,”
J. Jap. Institute of Metals
, Vol.
49
, pp.
78
83
.
7.
Karki
K. C.
, and
Patankar
S. V.
,
1988
, “
Calculation Procedure for Viscous Incompressible Flows in Complex Geometries
,”
Numerical Heat Transfer
, Vol.
14
, pp.
295
307
.
8.
Kim
C. J.
, and
Kaviany
M.
,
1992
, “
A Numerical Method for Phase-Change Problems With Convection and Diffusion
,”
Int. J. Heat Mass Transfer
, Vol.
35
, pp.
457
467
.
9.
Lim
J. S.
,
Fowler
A. J.
, and
Bejan
A.
,
1993
, “
Spaces Filled With Fluid and Fibers Coated With a Phase-Change Material
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
115
, pp.
1044
1050
.
10.
Martin, G. Q., and Son, J. S., 1986, “Fluid Mechanics of Mold Filling for Fiber Reinforced Plastics,” Proceedings of the ASM/ESD Second Conference on Advanced Composites, Dearborn, MI, pp. 149–157.
11.
Masur
L. J.
,
Mortensen
A.
,
Cornie
J. A.
, and
Flemings
M. C.
,
1989
, “
Infiltration of Fibrous Preform by a Pure Metal: Part II. Experiment
,”
Metall. Trans. A
, Vol.
20A
, pp.
2549
2557
.
12.
Mortensen, A., Cornie, J. A., and Flemings, M. C., 1988, “Solidification Processing of Metal-Matrix Composites,” J. of Metals, Feb., pp. 12–19.
13.
Mortensen
A.
, and
Masur
L. J.
,
Cornie
J. A.
, and
Flemings
M. C.
,
1989
, “
Infiltration of Fibrous Preform by a Pure Metal: Part I. Theory
,”
Metall. Trans, A
, Vol.
20A
, pp.
2535
2547
.
14.
Mortensen, A., and Koczak, M. J., 1993, “The Status of Metal-Matrix Composite Research and Development in Japan,” J. of Metals, Mar., pp. 10–18.
15.
Nagata
S.
, and
Matsuda
K.
,
1983
, “
Pressure Casting Conditions of Metal-Hybrid Particle Composites and Their Applications
,”
Trans. Japan Foundry Men’s Soc.
, Vol.
2
, pp.
616
620
.
16.
Nield, D. A., and Bejan, A., 1992, Convection in Porous Medium, Springer-Verlag, New York, Chaps. 1 and 10.
17.
Patankar, S. V., 1980, Numerical Heat Transfer and Fluid Flow, Hemisphere, Washington, DC.
18.
Rohatgi, P. K., 1991, “Cast Aluminum-Matrix Composites for Automotive Applications,” J. of Metals, Apr., pp. 10–15.
19.
Rohatgi
P. K.
,
Asthana
R.
,
Yadav
R. N.
, and
Ray
S.
,
1990
, “
Energetics of Particle Transfer From Gas to Liquid During Solidification Processing of Composites
,”
Metall. Trans. A
, Vol.
21A
, pp.
2073
2082
.
20.
Sparrow
E. M.
,
Patankar
S. V.
, and
Ramadhyani
S.
,
1977
, “
Analysis of Melting in the Presence of Natural Convection in the Melt Region
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
99
, pp.
520
526
.
21.
Thompson
J. F.
,
Thames
F. C.
, and
Mastin
C. W.
,
1974
, “
Automatic Numerical Generation of Body-Fitted Curvilinear Coordinate System for Field Containing Any Number of Arbitrary Two-dimensional Bodies
,”
J. of Computational Physics
, Vol.
15
, pp.
299
319
.
22.
Tong, X., 1995, “Infiltration, Solidification and Remelting of a Pure Metal in 2-D Porous Preform,” MS thesis, The University of South Carolina, Columbia, SC.
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