The penetration of a saturated liquid (a liquid at its freezing temperature) into a tube that is initially empty and maintained at a temperature below the freezing temperature of the liquid is treated theoretically and experimentally. A convenient approximate method is introduced which involves postulating a reasonable functional form for the instantaneous shape of the frozen layer along the tube wall. Graphical velocity-time and penetration distance-time curves are presented displaying the principal effects of a single dimensionless parameter. In the limit of negligible liquid inertia, shown to be relevant to high Prandtl number materials, a closed-form expression for the liquid penetration length is obtained. The expression compares well with the experimental results.
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Freezing-Controlled Penetration of a Saturated Liquid Into a Cold Tube
M. Epstein,
M. Epstein
Argonne National Laboratory, Reactor Analysis and Safety Division, Argonne, Ill.
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A. Yim,
A. Yim
Argonne National Laboratory, Reactor Analysis and Safety Division, Argonne, Ill.
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F. B. Cheung
F. B. Cheung
Argonne National Laboratory, Reactor Analysis and Safety Division, Argonne, Ill.
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M. Epstein
Argonne National Laboratory, Reactor Analysis and Safety Division, Argonne, Ill.
A. Yim
Argonne National Laboratory, Reactor Analysis and Safety Division, Argonne, Ill.
F. B. Cheung
Argonne National Laboratory, Reactor Analysis and Safety Division, Argonne, Ill.
J. Heat Transfer. May 1977, 99(2): 233-238 (6 pages)
Published Online: May 1, 1977
Article history
Received:
October 8, 1976
Online:
August 11, 2010
Citation
Epstein, M., Yim, A., and Cheung, F. B. (May 1, 1977). "Freezing-Controlled Penetration of a Saturated Liquid Into a Cold Tube." ASME. J. Heat Transfer. May 1977; 99(2): 233–238. https://doi.org/10.1115/1.3450674
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