Measurements of the bubble-point pressures and the saturated-liquid densities of the binary mixtures difluoromethane + 1,1,1,2-tetrafluoroethane (R-32 + R-134a) and pentafluoroethane + 1,1,1,2-tetrafluoroethane (R-125 + R-134a) and the ternary mixture difluoromethane + pentafluoroethane + 1,1,1,2tetrafluoroethane (R-32 + R-125 + R-134a) are presented. The estimated uncertainties of (15 mK in temperature, (12 kPa in pressure, (0.2% in density, and (0.3 mol % in composition are reported. The Peng-Robinson equation and the modified Hankinson-Brobst-Thomson equation have been optimized to represent the measured properties satisfactorily. The calculated temperature glides of the mixtures of the present interest have also been presented.
IntroductionReplacement of the conventional refrigerant, chlorodifluoromethane (R-22) is one of the urgent issues to be solved within the scheduled time frame of the amended Montreal Protocol. It is well believed that either a binary or ternary refrigerant mixture constituted by R-32, R-125, and/or R-134a would be the optimum candidate to replace R-22. As a continuation to our previous measurements of thermodynamic properties including the bubble-point pressures and saturated-and compressed-liquid densities (liquid PFTx properties) of the binary R-32 + R-134a and R-32 + R-125 (Widiatmo et al., 1993) systems: similar measurements on the binary R-125 + R-134a system and the ternary R-32 + R-125 + R-134a system are reported here along with an evaluation of reliable representations of bubble-point pressures and saturated-liquid densities for industrial applications.
Experimental ApparatusAll measurements in the present work were performed with a magnetic densimeter coupled with a variable volume cell which enables measurements either at the saturatedliquid condition or at the compressed-liquid condition. The saturation state of the mixture of the known composition was determined by observing the appearance and disappearance of a bubble in the liquid phase. Since the details of the apparatus have been reported elsewhere (Widiatmo et al., 1993), it will not be repeated in the present paper. By using the present apparatus, the bubble-point pressures were determined with uncertainties within (12 kPa, while the densities were within (0.2%. The uncertainty of temperature and pressure measurements were estimated to be within (15 mK and (12 kPa, respectively, while the determination of the composition of the mixture was done within (0.3 mol %. The purity of the samples analyzed by the manufacturers was 99.998 mass % for R-32, 99.98 mass % for R-125, and 99.8 mass % for R-134a, respectively, and no further purification was performed in the present work.
Results and DiscussionThe bubble-point pressures and saturated-and compressed-liquid densities of the binary R-32 + R-134a system are obtained only for compositions of 20, 25, 40, 60, and 80 mass % R-32 (0.3293, 0.3953, 0.5661, 0.7483, and 0.8869 mole fraction of R-32). Those of the binary R-125 + R-134a system are measured for temperatures from 280...
