Research on natural environmentally friendly refrigerants is very important especially because the world-wide agreement about restriction in the use of ozone depleting refrigerants. Carbon dioxide is a natural refrigerant that has been considered for certain refrigeration and air conditioning applications. The aim of this paper is to present a thermodynamic analysis of carbon dioxide cycles in order to evaluate the potential performance of a refrigeration cycle using carbon dioxide. A thermodynamic model for the cycle is developed which can simulate the operation of a carbon dioxide refrigeration/AC cycle. This model takes into account the practical effects of the thermo-physical properties of carbon dioxide as refrigerant in a trans-critical cycle. A sensitivity analysis has been conducted so that cycle performance is estimated. The cooling load, compressor power, and coefficient of performance (C.O.P.) were evaluated. One and two stages of compression were also considered for comparison purposes. Cycle performance was evaluated based on variation of important parameters such as evaporator, intermediate, and discharge pressures. The effects of cycle components on system capacity and cycle performance are also investigated. Comparison between performances of the CO2 cycle and the standard vapor compression cycle is performed. Thermodynamic calculations showed reasonable agreement with available experimental data based on the general assumptions made.

Volume Subject Area:
Advanced Energy Systems
Topics:
Carbon dioxide, Cycles, Refrigerants, Compression, Refrigeration, Air conditioning, Compressors, Cooling, Refrigeration cycles, Sensitivity analysis, Stress, Vapors
1.
Pettersen
J.
,
1994
, “
An Efficient New Automobile Air-Conditioning System based on CO2 Vapor Compression
,”
ASHRAE Transactions
,
100
(
2
), pp.
657
665
.
2.
Hill, W. and Papasavva, S., 2005, “Life Cycle Analysis Framework; A Comparison of HFC-134a, HFC-134a Enhanced, HFC-152a, R744, R744 Enhanced, and R290 Automotive Refrigerant Systems,” 2005 SAE World Congress, Detroit, Michigan, 2005-01-1511.
3.
Martin K., Lang G., Rieberer R., 2005, “Mobile HVAC-System with CO2 as Refrigerant — Simulations and Measurements,” Vehicle Thermal Management Systems Conference and Exhibition, SAE 2005-01-2023.
4.
Brown J. S. and Domanski P.A., 2000, “Semi-Theoretical Simulation Model for a Transcritical Carbon Dioxide Mobile A/C System,” SAE 2000 World Congress, Detroit, Michigan, 2000-01-0985.
5.
McEnaney R. P., Park Y. C., Yin J. M., and Hrnjak P. S., 1999, “Performance of the Prototype of a Transcritical R744 Mobile A/C System,” SAE International Congress and Exposition, Detroit, Michigan, 1999-01-0872.
6.
Vaisman I.B., 2002, “COP Analysis of Carbon Dioxide Cycles,” ASHRAE Transactions, pp. 252–262.
7.
Aydin, C., 2004, “Performance of Two-stage CO2 Refrigeration Cycles,” Master Thesis, University of Maryland, College Park, MD.
8.
Air-Conditioning and Refrigeration Institute, 1997, Standard for Positive Displacement Condensing Units, ANSI/ARI Standard 520.
This content is only available via PDF.
Copyright © 2005
 by ASME
You do not currently have access to this content.