Experiments have been conducted to quantify the interfacial thermal conductance between molten copper and a cold metallic substrate, and in particular to investigate the heat transfer variation as the initial liquid/solid contact becomes a solid/solid contact after nucleation. A high heat transfer coefficient during the earlier liquid cooling phase and a lower heat transfer coefficient during the subsequent solid splat cooling phase were estimated through matching of model calculations and measured temperature history of the sample. The dynamic variations in the interfacial heat transfer resulting from the solidification process were quantified for splat cooling and were found to be affected by the melt superheat, the substrate material, and the substrate surface finish.

1.
Bennett
T.
, and
Poulikakos
D.
,
1994
, “
Heat Transfer Aspects of Splat-Quench Solidification: Modeling and Experiment
,”
J. Mater. Sci.
, Vol.
29
, pp.
2025
2039
.
2.
Brandes, E. A., 1983, Smithells Metals Reference Hand Book, 6th ed., Butter-worths, United Kingdom.
3.
Ho
K.
, and
Pehlke
R. D.
,
1985
, “
Metal-Mold Interfacial Heat Transfer
,”
Metall, Trans. B
, Vol.
16B
, pp.
585
594
.
4.
Kline
S. J.
,
1985
, “
The Purposes of Uncertainty Analysis
,”
ASME Journal of Fluids Engineering
, Vol.
107
, pp.
153
160
.
5.
Liu
W.
,
Wang
G.-X.
, and
Matthys
E. F.
,
1995
, “
Thermal Analysis and Measurements for a Molten Metal Drop Impacting on a Substrate: Cooling, Solidification, and Heat Transfer Coefficient
,”
Int. J. Heat Mass Transfer
, Vol.
38
, pp.
1387
1395
.
6.
Loulou, T., Artyukhin, E. A., and Bardon, J. P., 1994, “Solidification of Molten Tin Drop on a Nickel Substrate,” Heat Transfer 1994, IChemE Pub., Brighton, United Kingdom, Vol. 4, pp. 73–78.
7.
Mizukami
H.
,
Suzuki
T.
, and
Umeda
T.
,
1992
, “
Numerical Analysis for Initial Stage of Rapid Solidification of 18Cr-8Ni Stainless Steel
,”
Tetsu-to-Ha-gane
, Vol.
78
, pp.
767
773
.
8.
O¨Zis¸ik, M. N., Bokar, J. C., Hector, L. G., Jr., Anyalebechi, P. N., and Nai, Y., 1995, “Combined Experimental/Theoretical Study of Mold Casting Interface Behavior During Directional Solidification,” Proceedings of the 1995 NSF Design and Manufacturing Grantees Conference, SME Pub., pp. 471–472.
9.
Ruhl
R. C.
,
1967
, “
Cooling Rates in Splat Cooling
,”
Mater. Sci. Engng.
, Vol.
1
, pp.
313
320
.
10.
Trapaga
G.
,
Matthys
E. F.
,
Valencia
J. J.
, and
Szekely
J.
,
1992
, “
Fluid Flow, Heat Transfer, and Solidification of Molten Metal Droplets Impinging on Substrate: Comparison of Numerical and Experimental Results
,”
Metall. Trans. B
, Vol.
23B
, pp.
701
718
.
11.
Wang
G.-X.
, and
Matthys
E. F.
,
1991
, “
Modelling of Heat Transfer and Solidification During Splat Cooling: Effect of Splat Thickness and Splat/Substrate Thermal Contact
,”
Int. J. Rapid Solidification
, Vol.
6
, pp.
141
174
.
12.
Wang
G.-X.
, and
Matthys
E. F.
,
1992
, “
Numerical Modelling of Phase Change and Heat Transfer During Rapid Solidification Processes: Use of Control Volume Integrals With Element Subdivision
,”
Int. J. Heat Mass Transfer
, Vol.
35
, pp.
141
153
.
13.
Wang, G.-X., and Matthys, E. F., 1994, “Interfacial Thermal Contact During Rapid Solidification on a Substrate,” Heat Transfer 1994, Proceedings of the Tenth International Heat Transfer Conference, IChemE Pub., Brighton, United Kingdom, Vol. 4, pp. 169–174.
14.
Wang, G.-X., 1995, “Experimental and Numerical Study of Heat Transfer and Solidification for Molten Metal in Contact With a Cold Substrate,” Ph.D. Thesis, University of California, Santa Barbara, CA.
This content is only available via PDF.
You do not currently have access to this content.