ConclusionsThe results of a refrige

Conclusions
The results of a refrigeration system simulation software to an increase in the amount of oil flowing with the refrigerant show that there are optimal values of the apparent overheat, for which either the exchanged heat or the refrigeration COP is maximized. It is not possible to optimize both the refrigeration COP and the evaporator energy. However, in most of the cases the optima values of the apparent overheat are below the values that the expansion valves usually impose. It would be possible to improve the refrigeration COP by increasing the apparent overheat above 6 K when the oil mass fraction is greater than 1%, but at the expense of the evaporator energy. In this study, we evaluated the performance of R600a, R134a, R290, R22, R410A, and R32, which differ vastly in critical temperatures and other thermo physical properties. We optimized evaporator circuitry for each refrigerant using a non-Darwinian evolutionary scheme, and performed simulations of the optimized evaporators. The high-pressure refrigerants provided higher evaporator capacities than the low-pressure refrigerants. For a 7.0 °C evaporator exit saturation temperature, and using R22 as a reference, R32, R410A, and R290, had a greater capacity by 14.5%, 10.7%, and 6.0%, while R134a and R690a had a lower capacity by 5.2% and 9.5%, respectively. The subsequent theoretical cycle simulations with the same 7.0 °C evaporator saturation temperature showed the COPs of the studied refrigerants to be in the order of their critical temperatures, i.e. low-pressure refrigerants had the best COPs. However, for the cycle simulations including evaporator effects (carried out at a different evaporator saturation temperature for each fluid to match the R22 capacity), the refrigerants performed within approximately a 2% band of the R22 COP baseline for the two condensing temperatures used. The exception to this was R290, whose COP was better than that of R22 by approximately 3% due to a set of favorable thermo physical properties. It is worth noticing that R32 overcame the 10% COP deficit it had in the theoretical cycle in reference to R600a and showed a comparable performance when evaporator effects were included in the cycle simulation. It must be emphasized that this study isolated the evaporator effects, and did not include similar effects that may be introduced by the condenser. Also, we have to note that selection of the compressor and relative sizing of the remaining components will affect the performance of a complete system. This study was not concerned with design and the cost related to the practical implementation of different refrigerants, equipment size, pressure, or lubricant issues. The condensing and evaporating temperatures used in this study correspond to the comfort cooling application. An additional insight could be obtained from a similar study performed at the same reduced temperatures for the considered refrigerants.