Energy and Exergy Analysis of Vapor Compression Refrigeration System with Integrated Mechanical Subcooling Using R134a, R450a, R513a, and R515a

Kunal Singh; Naveen Solanki; Dheeraj Joshi; Diptanshu Chowdhury; Vaibhav Jain

doi:10.4028/p-iA207G

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HomeEngineering HeadwayEngineering Headway Vol. 26Energy and Exergy Analysis of Vapor Compression...

Energy and Exergy Analysis of Vapor Compression Refrigeration System with Integrated Mechanical Subcooling Using R134a, R450a, R513a, and R515a

Abstract:

This study compares the performance of a vapor compression refrigeration system (VCRS) with an integrated mechanical subcooled vapor compression refrigeration system (IMS-VCRS) in water-cooled centrifugal chillers. Specifically, this study uses four different refrigerants R134a, R450a, R513a, and R515a. A mathematical model of IMS-VCRS is developed to determine the performance parameters at a fixed cooling capacity of 1750 kW. This study investigates that the energy consumption of an IMS-VCRS is reduced by 11.36% for R134a, 11.98% for R450a, 13.36% for R513a, and 11.89% for R515a. The mechanical subcooled system's COP is increased by 12.84% for R134a, 13.59% for R450a, 15.40% for R513a, and 13.48% for R515a due to the low power requirement. In addition, exergetic analysis is also used to determine the system's second law efficiencies, which in this study improved by 11.25%, 11.84%, 13.41%, and 11.77% for R134a, R450a, R513a, and R515a respectively. Furthermore, parametric analyses were performed to investigate the effects of various system parameters such as evaporator and condenser temperatures.

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Periodical:

Engineering Headway (Volume 26)

Pages:

89-102

DOI:

https://doi.org/10.4028/p-iA207G

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Online since:

August 2025

Authors:

Kunal Singh, Naveen Solanki*, Dheeraj Joshi, Diptanshu Chowdhury, Vaibhav Jain

Keywords:

COP, Energy, Exergy, Mechanical Subcooling, Second-Law Efficiency

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References

[1] J. W., Thornton, S. A., Klein, and J. W., Mitchell, "Dedicated mechanical-subcooling design strategies for supermarket applications," Int. J. Refrig. 1994;17(8):508–15.