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Arabian Journal for Science and Engineering
Published in: Arabian Journal for Science and Engineering 7/2020

22-04-2020 | Research Article-Mechanical Engineering

Comparative Performance of Low-GWP Refrigerants as Substitutes for R134a in a Vapor Compression Refrigeration System

Authors: Ameer Hamza, Tauseef Aized Khan

Published in: Arabian Journal for Science and Engineering | Issue 7/2020

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Abstract

This study predicts numerically the performance of low-GWP refrigerants [R152a, R1234yf and R1234ze(E)] as an alternative to R134a in a vapor compression refrigeration system. The plate heat exchanger was used as a condenser, and the appropriate correlations available in the published literature were used to predict the heat transfer coefficients and friction factors of refrigerants during condensation. Drop-in analysis based on the same conditions of the cooling medium (water) was considered, and the system was modeled in EES software. For this analysis, the inlet temperature of the water was varied from 15 to 40 °C as an input, and its effect on the performance parameters (condensation temperature, input power, discharge temperature, compression ratio, cooling capacity and COP) was analyzed and compared with R134a. The correlation used in this study predicts the better performance of R152a and R1234ze(E) as their heat transfer coefficient values are found to be 67–72% and 0.85–3% higher at condensation temperatures of 40–55 °C, respectively, when compared with R134a. The trends for the predicted frictional pressure drops are also found to be similar. For the drop-in analysis based on the same cooling medium conditions, simulation results reveal better performance for R152a and R1234ze(E). R152a shows 6.3–11% higher COP relative to R134a, whereas R1234yf shows lower COP of 7.6–12%, for the range of cooling water inlet temperatures considered in this study. Simulation results conclude that R152a seems more adequate refrigerant as an alternative of R134a in vapor compression refrigeration system.
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Literature
1.
Lee, Y.; Jung, D.: A brief performance comparison of R1234yf and R134a in a bench tester for automobile applications. Appl. Therm. Eng. 35, 240–242 (2012)CrossRef
2.
Brown, J.S.; Zilio, C.; Cavallini, A.: Thermodynamic properties of eight fluorinated olefins. Int. J. Refrig. 33(2), 235–241 (2010)CrossRef
3.
4.
Meng, Z.; et al.: Performance of low GWP R1234yf/R134a mixture as a replacement for R134a in automotive air conditioning systems. Int. J. Heat Mass Transf. 116, 362–370 (2018)CrossRef
5.
Diani, A.; et al.: Low GWP refrigerants condensation inside a 2.4 mm ID microfin tube. Int. J. Refrig. 86, 312–321 (2018)CrossRef
6.
Zhang, J.; et al.: Condensation heat transfer and pressure drop characteristics of R134a, R1234ze(E), R245fa and R1233zd(E) in a plate heat exchanger. Int. J. Heat Mass Transf. 128, 136–149 (2019)CrossRef
7.
Daviran, S.; et al.: A comparative study on the performance of HFO-1234yf and HFC-134a as an alternative in automotive air conditioning systems. Appl. Therm. Eng. 110, 1091–1100 (2017)CrossRef
8.
Janković, Z.; Atienza, J.S.; Suárez, J.A.M.: Thermodynamic and heat transfer analyses for R1234yf and R1234ze (E) as drop-in replacements for R134a in a small power refrigerating system. Appl. Therm. Eng. 80, 42–54 (2015)CrossRef
9.
Sumerua, K., et al.: Comparative performance between R134a and R152a in an air conditioning system of a passenger car. Jurnal Teknologi. 78, 1–6 (2016)
10.
Jarall, S.: Study of refrigeration system with HFO-1234yf as a working fluid. Int. J. Refrig. 35(6), 1668–1677 (2012)CrossRef
11.
Belman-Flores, J.; et al.: Energy and exergy analysis of R1234yf as drop-in replacement for R134a in a domestic refrigeration system. Energy 132, 116–125 (2017)CrossRef
12.
Jemaa, R.B.; et al.: Energy and exergy investigation of R1234ze as R134a replacement in vapor compression chillers. Int. J. Hydrogen Energy 42(17), 12877–12887 (2017)CrossRef
13.
Gupta, S.; et al.: Thermodynamic analysis and effects of replacing HFC by fourth-generation refrigerants in VCR systems. Int. J. Air-Cond. Refrig. 26(02), 1850013 (2018)CrossRef
14.
Sánchez, D.; et al.: Energy performance evaluation of R1234yf, R1234ze (E), R600a, R290 and R152a as low-GWP R134a alternatives. Int. J. Refrig. 74, 269–282 (2017)CrossRef
15.
Bolaji, B.: Experimental study of R152a and R32 to replace R134a in a domestic refrigerator. Energy 35(9), 3793–3798 (2010)CrossRef
16.
Karber, K.M.; Abdelaziz, O.; Vineyard, E.A.: Experimental performance of R-1234yf as a drop-in replacement for R-134a in domestic refrigerators. International Refrigeration and Air Conditioning Conference. Paper 1228 (2012)
17.
Shapiro, D.: Drop-in testing of next-generation R134a alternates in a commercial bottle cooler/freezer. International Refrigeration and Air Conditioning Conference. Paper 1185 (2012)
18.
Abraham, J.A.P.; Mohanraj, M.: Thermodynamic performance of automobile air conditioners working with R430A as a drop-in substitute to R134a. J. Therm. Anal. Calorim. 136(5), 2071–2086 (2019)CrossRef
19.
The Australian Institute of Refrigeration, A.c.a.H.A., Methods of calculating Total Equivalent Warming Impact (TEWI) 2012—Best Practice Guidelines, p. 21 (2012)
20.
Aprea, C.; et al.: HFO1234ze as drop-in replacement for R134a in domestic refrigerators: an environmental impact analysis. Energy Procedia 101, 964–971 (2016)CrossRef
21.
Longhini, M.: Next generation of refrigerants for residential heat pump systems. September 2015, Tecnico Lisboa
22.
Brander, M., et al.: Technical Paper|Electricity-Specific Emission Factors For Grid Electricity. Ecometrica, Emissionfactors.com (2011)
23.
El-Talouny, A.; Nielsen, O.: Promoting Low-GWP Refrigerants for Air-Conditioning Sectors in High-Ambient Temperature Countries (PRAHA). 2014, UNEP and UNIDO, OzonAction Fact Sheet-November
24.
Engineering Equation Solver. EES Version 9.944, F-chart software
25.
Aized, T.; Hamza, A.: Thermodynamic analysis of various refrigerants for automotive air conditioning system. Arab. J. Sci. Eng. 44(2), 1697–1707 (2019)CrossRef
26.
Fukuda, S.; et al.: Low GWP refrigerants R1234ze (E) and R1234ze (Z) for high temperature heat pumps. Int. J. Refrig. 40, 161–173 (2014)CrossRef
Metadata
Title
Comparative Performance of Low-GWP Refrigerants as Substitutes for R134a in a Vapor Compression Refrigeration System
Authors
Ameer Hamza
Tauseef Aized Khan
Publication date
22-04-2020
Publisher
Springer Berlin Heidelberg
Published in
Arabian Journal for Science and Engineering / Issue 7/2020
Print ISSN: 2193-567X
Electronic ISSN: 2191-4281
DOI
https://doi.org/10.1007/s13369-020-04525-3

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