Keywords and phrases: alternative refrigerants, R152a, R134a, heat transfer coefficient.
Received: February 9, 2023; Accepted: March 30, 2023; Published: May 18, 2023
How to cite this article: Vijay W. Bhatkar, Mangesh R. Mahajan, Narhar K. Patil and Dhiresh S. Shastri, Development of heat transfer coefficient correlation for minichannel condenser, JP Journal of Heat and Mass Transfer 33 (2023), 29-40. http://dx.doi.org/10.17654/0973576323021
This Open Access Article is Licensed under Creative Commons Attribution 4.0 International License
References:
[1] A. Baskaran and P. Mathews, A performance comparison of vapour compression refrigeration system using eco-friendly refrigerants of low global warming potential, Inter. J. Scientific Research Publication 2(9) (2012), 1-7. [2] B. O. Bolaji, M. A. Akintunde and T. O. Falade, Comparative analysis of performance of three ozone-friendly HFC refrigerants in a vapour compression refrigerator, J. Sustainable Energy and Environment 2 (2011), 61-64. [3] J. Calm, The next generation of refrigerants – historical review, considerations and outlook, Int. J. Refrigeration 31 (2008), 1123-1133. [4] A. S. Dalkilic and S. Wongwises, A performance comparison of vapour-compression refrigeration system using various alternative refrigerants, Int. Communication in Heat and Mass Transfer 37 (2010), 1340-1349. [5] K. Mani and V. Selladurai, Experimental analysis of a new refrigerant mixture as drop-in replacement for CFC 12 and HFC134a, Int. J. Thermal Sciences 47 (2008), 1490-1495. [6] M. Mohanraj, S. Jayraj and C. Muraleedharan, Environment friendly alternatives to halogenated refrigerants - a review, Int. J. Greenhouse Gas Control 3 (2009), 108-119. [7] T. M. Bandhauer, A. Agarwal and S. Garimella, Measurement and modeling of condensation heat transfer coefficients in circular micro-channels, J. Heat Transfer 128 (2006), 1050-1058. [8] J. B. Copetti, M. H. Macagnan and C. O. Figueiredo, Design and optimization of microchannel parallel flow condensers, 7th Int. Conf. on Enhanced, Compact and Ultra-Compact Heat Exchangers: From Micro Scale Phenomena to Industrial Applications, 2009, pp. 1-8. [9] M. M. Shah, A general correlation for heat transfer during film condensation inside pipes, Int. J. Heat and Mass Transfer 22(4) (1979), 547-556. [10] M. M. Shah, An improved and extended general correlation for heat transfer during condensation in plain tubes, HVAC & R Research 15(5) (2009), 889-913. [11] S. P. Gupta, Statistical Methods, Sultan Chand and Son’s Educational Publishers, New Delhi, 2012. [12] S. Koyama, K. Kuwahara, K. Nakashita and K. Yamamoto, An experimental study on condensation of refrigerant R134a in a multi-port extruded tube, Int. J. Refrigeration 24 (2003), 425-432. [13] W. W. Wang, T. D. Radclif and R. N. Christensen, A condensation heat transfer correlation for millimeter-scale tubing with flow regime transition, Experimental Thermal and Fluid Science 26 (2002), 473-485. [14] V. W. Bhatkar, V. M. Kriplani and G. K. Awari, Experimental performance of R134a and R152a using microchannel condenser, Journal of Thermal Engineering 1(7) (2015), 575-582. [15] V. W. Bhatkar and A. Sur, An experimental analysis of liquid air jet pump, Frontiers in Heat and Mass Transfer (FHMT) 17(12) (2021), 1-5. [16] V. W. Bhatkar, V. M. Kriplani and G. K. Awari, Alternative refrigerants in vapor compression refrigeration cycle for sustainable environment: a review of recent research, Int. J. Environmental Science and Technology 10 (2013), 871-880. [17] V. W. Bhatkar, Experimental study of multistage indirect evaporative coolers, JP Journal of Heat and Mass Transfer 24(1) (2021), 69-77. [18] V. W. Bhatkar, V. M. Kriplani and G. K. Awari, Numerical simulations of an aluminium microchannel condenser for household air conditioner, Int. Review of Mech. Engineering 7(1) (2013), 181-188.
|