Miscibility measurement and evaluation method of R290/R1234yf with mineral oil

被引：0

作者：

Chen Y. ^{[1
]}

Yang Z. ^{[1
]}

Zhai R. ^{[1
]}

Feng B. ^{[1
]}

Lyu Z. ^{[1
]}

Zhao W. ^{[1
]}

Ge Y. ^{[1
]}

机构：

[1] Key Laboratory of Medium-Low Temperature Energy Efficient Utilization of Ministry of Education, Tianjin University, Tianjin

来源：

Huagong Xuebao/CIESC Journal | 2019年 / 70卷 / 09期

关键词：

Critical miscibility temperature; Dissolution; Experimental validation; Mineral oil; Miscibility; Mixtures; R290/R1234yf;

D O I：

10.11949/0438-1157.20190354

中图分类号：

学科分类号：

摘要：

The miscibility of refrigerant and lubricating oil directly affects the service life and cycle performance of refrigeration system. To solve the problem of matching new refrigerant and lubricating oil, a refrigerant and lubricating oil compatibility test system was established. The experimental study on the miscibility of R290/R1234yf and mineral oil was carried out in the temperature range of 223.15-303.15 K. The results show when R290 mass fraction in mixed refrigerant R290/R1234yf changed from 25% to 35% and oil proportion was specified at 10%±0.5%, the critical miscibility temperature of R290/R1234yf and mineral oil decreased with increasing R290. In the test range of oil proportion, based on the common refrigeration conditions, when the mass fraction of R290 in solution changed between 20% and 30%, the critical miscibility temperature was sensitive to the change of components. When the R290 mass fraction in solution was over 30%, the refrigerant/oil solution was believed to be clear and transparent. When the R290 mass fraction in solution was below 20%, the obvious stratification or large flocs would appear. By means of the element contribution evaluation method, the theoretical critical miscibility temperature prediction equation was provided and given in the form of ternary diagram, which has practical guiding significance for the development of new environmental protection refrigerants. © All Right Reserved.

引用

页码：3248 / 3255

页数：7

共 30 条

[1] Qin D.H., Thomas S., Highlights of the report of working group I of the fifth assessment report of the IPCC, Progressus Inquisitiones DE Mutatione Climatis, 1, pp. 1-6, (2014)
[2] McLinden M.O., Kazakov A.F., Steven Brown J., Et al., A thermodynamic analysis of refrigerants: possibilities and tradeoffs for low-GWP refrigerants, International Journal of Refrigeration, 38, pp. 80-92, (2014)
[3] Del Col D., Torresin D., Cavallini A., Heat transfer and pressure drop during condensation of the low GWP refrigerant R1234yf, International Journal of Refrigeration, 33, 7, pp. 1307-1318, (2010)
[4] Saitoh S., Dang C., Nakamura Y., Et al., Boiling heat transfer of HFO-1234yf flowing in a smooth small-diameter horizontal tube, International Journal of Refrigeration, 34, 8, pp. 1846-1853, (2011)
[5] Wang C., An overview for the heat transfer performance of HFO-1234yf, Renewable and Sustainable Energy Reviews, 19, pp. 444-453, (2013)
[6] Cho H., Lee H., Park C., Performance characteristics of an automobile air conditioning system with internal heat exchanger using refrigerant R1234yf, Applied Thermal Engineering, 61, 2, pp. 563-569, (2013)
[7] Zilio C., Brown J.S., Schiochet G., Et al., The refrigerant R1234yf in air conditioning systems, Energy, 36, 10, pp. 6110-6120, (2011)
[8] Jarall S., Study of refrigeration system with HFO-1234yf as a working fluid, International Journal of Refrigeration, 35, 6, pp. 1668-1677, (2012)
[9] Boumaraf L., Haberschill P., Lallemand A., Investigation of a novel ejector expansion refrigeration system using the working fluid R134a and its potential substitute R1234yf, International Journal of Refrigeration, 45, pp. 148-159, (2014)
[10] Qin Y., Zhang H., Wu Y., Et al., Thermodynamic modeling of VLE and VLLE for the ternary system of 2, 3, 3, 3-tetrafluoroprop-1-ene(R1234yf)+propane (R290)+1, 1, 1, 2-tetrafluoroethane(R134a) at 253.15 K-313.15 K, Chemical Engineering Science, 187, pp. 134-147, (2018)

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