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ENTROPY GENERATION AND THERMODYNAMIC ANALYSIS OF POOL BOILING HEAT TRANSFER ON DOUBLY ENHANCED TUBES

ABSTRACT
To improve the efficiency of the heat exchanger tube, one smooth tube and four doubly enhanced tubes (EX1, EX2, EX3 and EX4) have been investigated for the pool boiling heat transfer experiments in this paper. The indicate that the pool boiling heat transfer coefficient of the doubly enhanced tubes increased visibly with the augmentation of heat flux through the bubble behavior. Heat transfer reinforcement effect of the doubly enhanced tubes are significantly better than that of the smooth tube. Additionally, pool boiling heat transfer coefficient can be further enhanced by raising the saturate temperature. Entropy generation minimization analysis demonstrates that the heat transfer characteristics of like T-shaped tubes (EX1 and EX2) are superior to that of low fin tubes (EX3 and EX4). Particularly, tube EX1 exhibits higher pool boiling heat transfer efficiency. It is observed that a reasonable fin pitch is more advantageous for improving heat transfer characteristics. The utilization of entropy generation minimization analysis provides theoretical support for the design and optimization of doubly enhanced tubes.
KEYWORDS
PAPER SUBMITTED: 2023-08-10
PAPER REVISED: 2023-12-18
PAPER ACCEPTED: 2024-01-10
PUBLISHED ONLINE: 2024-03-10
DOI REFERENCE: https://doi.org/10.2298/TSCI230810053Z
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2024, VOLUME 28, ISSUE Issue 2, PAGES [1927 - 1939]
REFERENCES
  1. Lin, L., Kedzierski, M. A., Review of Low-GWP Refrigerant Pool Boiling Heat Transfer on Enhanced Surfaces, International Journal of Heat and Mass Transfer, 131 (2019), Mar., pp. 1279-1303
  2. Egbo, M., et al., Review: Surface Orientation Effects on Pool-Boiling with Plain and Enhanced Surfaces, Applied Thermal Engineering, 204 (2022), 117927
  3. Chen, Y., et al., Bubble Dynamics of Boiling of Propane and Iso-Butane on Smooth and Enhanced Tubes, Experimental Thermal and Fluid Science, 28 (2004), 2, pp. 171-178
  4. Ardron, K. H., et al., Prediction of Dynamic Contact Angles and Bubble Departure Diameters in Pool Boiling Using Equilibrium Thermodynamics, International Journal of Heat and Mass Transfer, 114 (2017), Nov., pp. 1274-1294
  5. He, J., et al., Analysis and Experimental Study of Nucleation Site Densities in the Boiling of Mixed Refrigerants, International Journal of Heat and Mass Transfer, 105 (2017), Feb., pp. 452-463
  6. Zhao, Z., et al., Investigation of Bubbles Interaction and Coalescence Boiling in the Boiling Heat Transfer Process, Thermal Science, 23 (2019), 5A, pp. 2605-2611
  7. Siddharth, I., et al., Modelling of Bubble Growth and Detachment in Nucleate Pool Boiling, International Journal of Thermal Sciences, 185 (2023), 103041
  8. Ribatski, G., Thome, J. R., Nucleate Boiling Heat Transfer of R134a on Enhanced Tubes, Applied Thermal Engineering, 26 (2006), 10, pp. 1018-1031
  9. Ji, W. T., et al., Effect of Subsurface Tunnel on the Nucleate Pool Boiling Heat Transfer of R1234ze(E), R1233zd(E) and R134a, International Journal of Refrigeration, 122 (2021), Feb., pp. 122-133
  10. Ji,W. T., et al., Pool Boiling Heat Transfer of R134a Outside Reentrant Cavity Tubes at Higher Heat Flux, Applied Thermal Engineering, 127 (2017), Dec., pp. 1364-1371
  11. Zhen, L., et al., Experimental Study on R410A Flow Boiling Heat Transfer Outside Three Enhanced Tubes with Different Fin Structures, AIP Advances, 10 (2020), 11, 115105
  12. Amit, K., et al., Designing of Microsink to Maximize the Thermal Performance and Minimize the Entropy Generation with the Role of Flow Structures, International Journal of Heat and Mass Transfer, 176 (2021), 121421
  13. Sanju, T., Kumar, A. G., Entropy Generation Analysis for Forced Convection Boiling in Absorber Tubes of Linear Fresnel Reflector Solar Thermal System, Thermal Science, 24 (2020), 2A, pp. 735-743
  14. Shi, X., et al., Influence of Structure Parameters on Entropy Generation Performance in Cross Wavy Channels with Fluid-Solid Coupled Heat Transfer, Applied Thermal Engineering, 181 (2020), 115882
  15. Sahiti, N., et al., Entropy Generation Minimization of a Double-Pipe Pin Fin Heat Exchanger, Applied Thermal Engineering, 28 (2008), 17-18, pp. 2337-2344
  16. Dagtekin, I., et al., An Analysis of Entropy Generation Through a Circular Duct with Different Shaped Longitudinal Fins for Laminar Flow, International Journal of Heat and Mass Transfer, 48 (2005), 1, pp. 171-181
  17. Moghadasi, H., Malekian, N., Thermodynamic Analysis of Entropy Generation Due to Energy Transfer Through Circular Surfaces Under Pool Boiling Condition, Journal Thermal Analysis and Calorimetry, 147 (2022), 3, pp. 2495-2508
  18. Ali, N., et al., Investigating Thermo-Hydraulic Behavior of Pillow Plate Heat Exchangers Using Entropy Generation Approach, Chemical Engineering and Processing - Process Intensification, 174 (2022), 108887
  19. Gnielinski, V., New Equations for Heat and Mass Transfer in Turbulent Pipe and Channel Flows, International Chemical Engineering, 16 (1976), 2, pp. 359-368
  20. Revellin, R., et al., Local Entropy Generation for Saturated Two-Phase Flow, Energy, 34 (2009), 9, pp. 1113-1121
  21. Cheng, B., Tao, W. Q., Experimental Study of R152a Film Condensation on Single Horizontal Smooth Tube and Enhanced Tubes, Journal of Heat Transfer, 116 (1994), 1, pp. 266-270
  22. Kline, S. J., Mcclintock, F. A., Describing Uncertainties in Single-Sample Experiments, Mechanical Engineering, 75 (1953), Jan., pp. 3-9
  23. Kedzierski, M. A., Lin, L., State of the Art on the Flammability of Hydrofluoroolefin (HFO) Refrigerants, International Journal of Refrigeration, 104 (2019), Dec., pp. 476-483
  24. Cooper, M. G., Saturation Nucleate Pool Boiling-A Simple Correlation, First U.K. National Conference on Heat Transfer, 2 (1984), 86, pp. 785-793

© 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