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An Experimental Study of Heat Induced Surface-Tension Driven Flow

Published online by Cambridge University Press:  15 February 2011

Y. Kamotani ,
S. Ostrach  and
S. Lowry
Y. Kamotani
Affiliation:
Case Western Reserve University, University Circle, Cleveland, Ohio 44106
S. Ostrach
Affiliation:
Case Western Reserve University, University Circle, Cleveland, Ohio 44106
S. Lowry
Affiliation:
Case Western Reserve University, University Circle, Cleveland, Ohio 44106
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Abstract

Velocity and temperature measurements are taken of heat induced surface-tension driven flows in both silicone oil and Fluorinert FC-43. Each fluid is contained in an open rectangular box and heated from above by a single strand of electrically heated nichrome wire suspended slightly above the fluid's surface. Velocity measurements are obtained for both liquids with a laser anemometer system. For silicone oil the general flow pattern is recorded using time-lapse photography. The surface temperature measurements are taken by a radiation thermometer and the bulk temperature distributions are measured by thermocouples. The velocity and temperature measurements are compared with numerical solutions obtained for the present configuration.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 9 , 1981 , 161
Copyright
Copyright © Materials Research Society 1982

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References

REFERENCES

1.Ostrach, S., Progress in Astronautics and Aeronautics, AIAA, 52, 3 (1977)Google Scholar
2.Ostrach, S., Physiochemical Hydrodynamics-V.G. Levich Festschrift 2, (Advanced Publication Ltd.) pp. 571589, 1977.Google Scholar
3.Pimputkar, S.M. and Ostrach, S., Physics of Fluids 23, 1281 (1980).Google Scholar
4.Levich, V.G.; Physiochemical Hydrodynamics (Prentice-Hall 1962).Google Scholar
5.Birikh, R.V., J. Applied Mech. and Tech. Physics 7, 43 (1966).10.1007/BF00914697Google Scholar
6.Yih, C-S., Physics of Fluids 11, 477 (1968).Google Scholar
7.Schwabe, D., Scharman, A., Preisser, F. and Oeder, R., J. Crystal Growth 43, 305 (1978).Google Scholar
8.Chun, C-H. and Wuest, W., Acta Astronautica 5, 681 (1978).Google Scholar
9.Ostrach, S. and Pradhan, A., AIAA J. 16, 419 (1978).Google Scholar
10.Lowry, S., M.S. Thesis, Case Western Reserve Univ. EFTS/TR–81–154 (1981).Google Scholar