THERMAL SCIENCE

International Scientific Journal

Authors of this Paper

External Links

Onur Agma

,

Sebiha Yildiz

EXPERIMENTAL STUDY OF NUCLEATE POOL BOILING WITH WATER IN ATMOSPHERIC PRESSURE

ABSTRACT
This study experimentally investigated nucleate pool boiling heat transfer for a polished copper surface and water fluid couple under atmospheric pressure. The results were compared with the correlations in the literature. The experimental results were compared with the surface-liquid correlation constants Rohsenow, Pioro, Vachon, Griffith, and Das used for the temperature exceedance values. When the results of Griffith's correlation constant were compared with the experimental values, it was seen that it was the most appropriate correlation compared to other correlations, with a minimum and maximum error of 0.4-12%. In addition, Forster-Zuber, Pioro, Kutateladze old, Kutateladze new, Kruzhilin, and Cooper correlations were compared with experimental results regarding the heat transfer coefficient. Compared with the correlation proposed by Pioro for the heat transfer coefficient, it was calculated as the most suitable correlation with a minimum and maximum difference of 0.2-8%
KEYWORDS
nucleate pool boiling, water, polished copper, Atmospheric pressure
PAPER SUBMITTED: 2023-06-27
PAPER REVISED: 2023-08-22
PAPER ACCEPTED: 2023-08-25
PUBLISHED ONLINE: 2023-10-08
DOI REFERENCE: https://doi.org/10.2298/TSCI230627210A
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2024, VOLUME 28, ISSUE Issue 2, PAGES [1807 - 1818]
REFERENCES
  1. Dahariya, S., Betz, A. R., High Pressure Pool Boiling: Mechanisms for Heat Transfer Enhancement and Comparison to Existing Models, Int. J. Heat Mass Transf., 141 (2019), Oct., pp. 696-706
  2. Balaji, C., et al., Heat Transfer Engineering: Fundamentals and Techniques, Academic Press, London, UK, 2021
  3. Kandlikar, S. G., Handbook of Phase Change: Boiling and Condensation, Taylor&Francis, Philadelphia, Penn., USA, 2019.
  4. Yildiz, S., Effect of Length-to-Diameter Ratio on Critical Heat Flux in Porous-Coated Tubes, Thermal Science, 25 (2021), 1B, pp. 613-623
  5. Guo, J., et al., Experimental Study on Boiling Heat Transfer in Negative-Pressure Flowing Water in a Vertical Annular Tube, Thermal Science, 26 (2022), 6B, pp. 5121-5129
  6. Jing, Q., Luo, Q., Experimental Study on the Correlation of Subcooled Boiling Flow in Horizontal Tubes, Thermal Science, 26 (2022), 1A, pp. 107-117
  7. Guichet, V., et al., Nucleate Pool Boiling Heat Transfer in Wickless Heat Pipes (Two-Phase Closed Thermosyphons): A Critical Review of Correlations, Therm. Sci. Eng. Prog., 13 (2019), 100384
  8. Das, S., et al., Experimental Study of Nucleate Pool Boiling Heat Transfer of Water by Surface Functionalization with Crystalline TiO2 Nanostructure, Appl. Therm. Eng., 113 (2017), Feb., pp. 1345- 1357
  9. Choon, N. K., et al., New Pool Boiling Data for Water with Copper-Foam Metal at Sub-Atmospheric Pressures: Experiments and Correlation, Appl. Therm. Eng., 26 (2006), 11-12, pp. 1286-1290
  10. Gao, L., et al., Experimental Studies for the Combined Effects of Micro-Cavity and Surface Wettability on Saturated Pool Boiling, Exp. Therm. Fluid Sci., 140 (2023), 110769
  11. Yao, H., et al., Modification and Pool Boiling Performance Elevation of Copper Foam Wicks for High Power Applications, Appl. Therm. Eng., 220 (2023), 119788
  12. Pezo, M. L., Stevanović, V. D., Numerical Prediction of Nucleate Pool Boiling Heat Transfer Coefficient Under High Heat Fluxes, Thermal Science, 20 (2016), Suppl. 1, pp. S113-S123
  13. Haji, A., et al., Enhanced Boiling Heat Transfer Efficiency Through the Simultaneous Use of Electrospray and Photolithography Methods: An Experimental Study and Correlation, Therm. Sci. Eng. Prog., 38 (2023), 101661
  14. Theofanous, T. G., et al., The Boiling Crisis Phenomenon Part I: Nucleation and Nucleate Boiling Heat Transfer, Experimental Thermal and Fluid Science, 26 (2002), 6-7, pp. 775-792
  15. Theofanous, T. G., et al., The Boiling Crisis Phenomenon Part II: Dryout Dynamics and Burnout, Experimental Thermal and Fluid Science, 26 (2002), 6-7, pp. 793-810
  16. Jo, H., et al., A Study of Nucleate Boiling Heat Transfer on Hydrophilic, Hydrophobic and Heterogeneous Wetting Surfaces, Int. J. Heat Mass Transf., 54 (2011), 25-26, pp. 5643-5652
  17. Wen, D., et al., Boiling Heat Transfer of Nanofluids: The Effect of Heating Surface Modification, Int. J. Therm. Sci., 50 (2011), 4, pp. 480-485
  18. Cooke, D., Kandlikar, S. G., Effect of Open Microchannel Geometry on Pool Boiling Enhancement, Int. J. Heat Mass Transf., 55 (2012), 4, pp. 1004-1013
  19. Sarangi, S., et al., Effect of Particle Size on Surface-Coating Enhancement of Pool Boiling Heat Transfer, Int. J. Heat Mass Transf., 81 (2015), Feb., pp. 103-113
  20. Thangavelu, N., et al., Influence of Surface Roughness and Wettability of Novel Surface on Nucleate Boiling Performance in Deionised Water at Atmospheric Pressure, Thermal Science., 26 (2022), 6A, pp. 4645-4656
  21. Kathiravan, R. et al., Preparation and Pool Boiling Characteristics of Copper Nanofluids Over a Flat Plate Heater, Int. J. Heat Mass Transf., 53 (2010), 9-10, pp. 1673-1681
  22. Xuan, Y., Li, Q., Heat Transfer Enhancement of Nanofluids, International Journal of Heat and Fluid Flow, 21 (2000), 1, pp. 58-64
  23. Park, K. J., Jung, D., Enhancement of Nucleate Boiling Heat Transfer Using Carbon Nanotubes, Int. J. Heat Mass Transf., 50 (2007), 21-22, pp. 4499-4502
  24. Ali, H. M., et al., Experimental Investigation of Nucleate Pool Boiling Heat Transfer Enhancement of TiO2-Water Based Nanofluids, Appl. Therm. Eng., 113 (2017), Feb., pp. 1146-1151
  25. Rohsenow, W. M., et al., Handbook of Heat Transfer, McGraw-Hill, New York, USA, 1998
  26. Rohsenow, W. M., A Method of Correlating Heat Transfer Data for Surface Boiling of Liquids, Report No. 5, MIT, Cambridge, Mass., USA, 1951
  27. Pioro, I. L., Experimental evaluation of constants for the Rohsenow pool boiling correlation, Int. J. Heat Mass Transf., 42 (1999), 11, pp. 2003-2013
  28. Vachon, R. I., Evaluation of Constants for the Rohsenow Pool-Boiling Correlation, J. Heat Transf., 90 (1968), 2, pp. 239-246
  29. Das, A. K., et al., Nucleate Boiling of Water from Plain and Structured Surfaces, Exp. Therm. Fluid Sci., 31 (2007), 8, pp. 967-977
  30. Cengel, Y. A., et al., Isı ve Kütle Transferi Pratik bir Yaklaşım (Heat and Mass Transfer A Pratical Approach - in Turkish), Güven Kitabevi, Istanbul, Turkey, 2011
  31. Forster, H. K., Zuber, N., Dynamics of Vapor Bubbles and Boiling Heat Transfer, AIChE J., 1 (1955), 4, pp. 531-535
  32. Pioro, I. L., et al., Nucleate Pool-Boiling Heat Transfer. II: Assessment of Prediction Methods, Int. J. Heat Mass Transf., 47 (2004), 23, pp. 5045-5057
  33. Jones, B. J., et al., The Influence of Surface Roughness on Nucleate Pool Boiling Heat Transfer, J. Heat Transf., 131 (2009), 121009
  34. Cooper, M. G., Saturation Nucleate Pool Boiling - A Simple Correlation, First U.K. National Conference on Heat Transfer, 2.86, (1984), pp. 785-793
  35. Moffat, R. J., Describing the Uncertainties in Experimental Results, Exp. Therm. Fluid Sci., 1 (1988), 1, pp. 3-17
PDF VERSION [DOWNLOAD]
Experimental study of nucleate pool boiling with water in atmospheric pressure

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence