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Droplet Statics Read chapter Read first chapter

2020 | OriginalPaper | Chapter

14. Measurement of Heat Transfer Rates under a Liquid Drop During Dropwise Condensation

Authors : Gagan Bansal, S. Khandekar, K. Muralidhar

Published in: Drop Dynamics and Dropwise Condensation on Textured Surfaces

Publisher: Springer International Publishing

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Abstract

The quasi-periodic and statistical nature of drop formation, along with very high heat transfer coefficients at low operating temperature difeerentials, makes the experimental determintaion of transfer coefficients quite challenging. We demonstrate the use of high resolution Liquid Crystal Thermography (LCT) coupled with digital videography to measure the spatial distribution of temperature during dropwise condensation in the pendant mode over a polyethylene substrate. Using a one-dimensional heat transfer model, heat flux profiles through individual condensing droplets have been obtained. The measured heat flux as a function of drop diameter matches published data for large drop sizes but fails for small drops (< 0.4 mm) where the thermal resistance of the LCT sheet is a limiting factor. To a first approximation, the present work shows that drop size can be correlated to the local heat flux. It is demonstrated that the average condensation heat flux over a surface can be obtained entirely from the drop-size distribution.

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previous chapter Measurement of Condensation Heat Transfer
next chapter Evaporation Dynamics of a Sessile Droplet on a Hydrophobic Surface
Literature
Abu-Orabi, M. (1998). Modeling of heat transfer in dropwise condensation. International Journal of Heat and Mass Transfer, 41, 81–87.CrossRef
Bansal, G. D., Khandekar, S., & Muralidhar, K. (2009). Measurement of Heat Transfer during Dropwise Condensation of Water on Polyethylene, Nanoscale and Microscale Thermophysical Engineering, 13(3), 184–201.
Beysens, D. (2006). Dew nucleation and growth. Comptes Rendus Physique, 7, 1082–1100.CrossRef
Briscoe, B. J., Williams, D. R., & Galvin, K. P. (2005). Condensation on hydrosol modified polyethylene. Colloids and Surfaces A, 264, 101–105.CrossRef
Carey, V. P. (2008). Liquid-vapor phase-change phenomena (2nd ed., pp. 45–472). New York: Taylor and Francis Group LLC.
Collier, J.G., Thome, J. R., (1996). Convective Boiling and Condensation, 3rd ed., Oxford Engineering Science Series, Clarendon Press, ISBN-10: 0198562969.
Goldstein, R. J., Ibele, W. E., Patankar, S. V., Simon, T. W., Kuehn, T. H., Strykowski, P. J., Tamma, K. K., Heberlein, J. V. R., Davidson, J. H., Bischof, J., Kulacki, F. A., Kortshagen, U., Garrick, S., & Srinivasan, V. (2006). Heat transfer—a review of 2003 literature. International Journal of Heat and Mass Transfer, 49, 451–534.CrossRef
Graham, C., & Griffith, P. (1973). Dropwise size distribution and heat transfer in dropwise condensation. International Journal of Heat and Mass Transfer, 16, 337–346.CrossRef
Hay, J. L., & Hollingsworth, D. K. (1998). Calibration of micro-encapsulated liquid crystals using hue angle and a dimensionless temperature. Experimental Thermal and Fluid Sciences, 18, 251–257.CrossRef
Höhmann, C., & Stephan, P. (2002). Microscale temperature measurement at an evaporating liquid meniscus. Experimental Thermal and Fluid Sciences, 26, 157–162.CrossRef
Kananeh, B., Rausch, M. H., Fröba, A. P., & Leipertz, A. (2006). Experimental study of dropwise condensation on plasma-ion implanted stainless steel tubes. International Journal of Heat and Mass Transfer, 49, 5018–5026.CrossRef
Leipertz, A., & Fröba A. P. (2006). Improvement of condensation heat transfer by surface modification. In Proceedings of the 7th ASME, Heat and Mass Transfer Conference, IIT Guwahati, India (Vol. K7, pp. k85–k99).
Ma, X., Chen, J., Xu, D., Lin, J., Ren, C., & Long, Z. (2002). Influence of processing conditions of polymer film on dropwise condensation heat transfer. International Journal of Heat and Mass Transfer, 45, 3405–3411.CrossRef
Muwanga, R., & Hassan, I. (2006). Local heat transfer measurements in microchannels using liquid crystal thermography: Methodology development and validation. ASME Journal of Heat Transfer, 128, 617–627.CrossRef
Rose, J. W. (1981). Dropwise condensation theory. International Journal of Heat and Mass Transfer, 24, 191–194.CrossRef
Rose, J. W. (1998). Condensation heat transfer fundamentals. Transactions of the AIChE Journal, 76A, 143–152.
Rose, J. W. (2002). Dropwise condensation theory and experiment: A review. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 216, 115–128.
Rose, J. W. (2004). Surface tension effects and enhancements of condensation heat transfer. Chemical Engineering Research and Design, 82, 419–429.CrossRef
Stasiek, J., Stasiek, A., Jewartowski, M., & Collins, M. W. (2006). Liquid crystal thermography and true-color digital image processing. Optics and Laser Technology, 38, 243–256.CrossRef
Van der Geld, C. W. M., Ganzevles, F. L. A., Simons, C. T. P. F., & Weitz, F. (2001). Geometry adaptations to improve the performance of compact polymer condensers. Transactions of the IChemE (Part A), 79, 357–362.CrossRef
Vemuri, S., Kim, K. J., Wood, B. D., Govindaraju, S., & Bell, T. W. (2006). Long term testing for dropwise condensation using self-assembled monolayer coating of n-octadecyl mercaptan. Applied Thermal Engineering, 26, 421–429.CrossRef
Venables, J. A. (2000). Introduction to surface and thin film processes (1st ed., pp. 144–165). Cambridge: Cambridge University Press. ISBN-10 #0521785006.CrossRef
Metadata
Title
Measurement of Heat Transfer Rates under a Liquid Drop During Dropwise Condensation
Authors
Gagan Bansal
S. Khandekar
K. Muralidhar
Copyright Year
2020
Book
Drop Dynamics and Dropwise Condensation on Textured Surfaces

Print ISBN: 978-3-030-48460-6

Electronic ISBN: 978-3-030-48461-3

Copyright Year: 2020

DOI
https://doi.org/10.1007/978-3-030-48461-3_14

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