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An Experimental Study on the Heat Transfer of Traveling Airborne Water Droplets in Cold Environment

Published online by Cambridge University Press:  09 November 2015

Y.-K. Chuah*
Affiliation:
Department of Energy and Refrigerating Air-Conditioning Engineering National Taipei University of Technology Taipei, Taiwan
J.-T. Lin
Affiliation:
Nextek Engineering Taiwan
K.-H. Yu
Affiliation:
Marketech International Corp. Taiwan
*
*Corresponding author ([email protected])
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Abstract

This paper presents experimental results on rapid freezing of water droplets injected into a low temperature environment. A heat balance method was applied to determine the ratio of the water droplets frozen at the collection after the airborne time. The experimental results show that rapid freezing of water droplets could be achieved within three seconds of airborne time. Droplet size distribution of the frozen water droplets after collection was estimated. Heat transfer during the airborne time was calculated with consideration of the droplet size distribution. At attempt was taken to compare the heat transfer obtained with some previous studies on heat transfer of spherical objects in air. The research results show that droplet size distribution is important for the prediction of heat transfer of water droplets traveling in air. The results presented in this study contribute to the understanding of heat transfer of water droplets injected into a low temperature air.

Type
Research Article
Copyright
Copyright © The Society of Theoretical and Applied Mechanics, R.O.C. 2016 

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References

1.Teraoka, Y., Satio, A. and Okawa, S., “Study on Anisotropy of Growth Rate of Ice Crystal in Supercooled Water,” International Journal of Refrigeration, 17, pp. 242247 (2004).CrossRefGoogle Scholar
2.Miller, D. A., Adams, E. E. and Brown, R. L., “A Microstructural Approach to Predict Dry Snow Metamorphism in Generalized Thermal Conditions,“ Cold Regions Science and Technology, 37, pp. 213226 (2003).Google Scholar
3.Levi, L. and Nasello, O. B., “A Discussion of Mechanisms Proposed to Explain Habit Changes of Vapor-Grown Ice Crystals,” Atmospheric Research, 66, pp. 107122 (2003).Google Scholar
4.Cheng, C. H. and Shiu, C. C., “Frost Formation and Frost Crystal Growth on a Cold Plate in Atmospheric Air Flow,” International Journal of Heat Mass Transfer, 45, pp. 42894303 (2002).Google Scholar
5.Strub, M., Jabbour, O., Strub, F. and Bedecarrats, J. P., “Experimental Study and Modeling of the Crystallization of a Water Droplet,” International Journal of Refrigeration, 26, pp. 5968 (2003).Google Scholar
6.Thongwik, S., Vorayos, N., Kiatsiriroat, T. and Nuntaphan, A., “Thermal Analysis of Slurry Ice Production System Using Direct Contact Heat Transfer of Carbon Dioxide and Water Mixture,“ Heat and Mass Transfer, 35, pp. 756761 (2008).Google Scholar
7.Ranz, W. E. and Marshall, W. R., “Evaporation from Drops,” Chemical Engineering Process, 48, pp. 141146 (1952).Google Scholar
8.Whitaker, S., “Forced Convection Heat Transfer Correlations for Flow in Pipes Past Flat Plates, Single Cylinders, Single Spheres, and for Flow in Packed Beds and Tubes Bundles,” American Institute of Chemical Engineering Journal, 18, pp.361367 (1972).Google Scholar
9.Chiang, C. H., Raju, M. S. and Sirignano, W. A., “Numerical Analysis of a Convection, Vaporizing, Fuel Droplet with Variable Properties,” International Journal of Heat Mass Transfer, 35, pp. 1307–132 (1992).Google Scholar
10.Renkiszbulut, M. and Yuen, M. C., “Experimental Study of Droplet Evaporation in High Temperature Air Stream,” Journal of Heat Transfer, 105, pp.364388 (1983).Google Scholar
11.Clift, R., Grace, J. R. and Weber, M. E., Bubbles, Drops and Particles, Academic Press, New York (1978).Google Scholar
12.Feng, Z. G. and Michaelides, E. E., “Mass and Heat Transfer from Fluid Spheres at Low Reyonolds Numbers,” Power Technology, 112, pp. 6369 (2000).Google Scholar
13.Feng, Z. G. and Michaelides, E. E., “A Numerical Study on the Transient Heat Transfer from a Sphere at High Reynolods and Peclet Numbers,” International Journal of Heat Mass Transfer, 43, pp.219229 (2000).Google Scholar