Measurement of Viscosity of a Binary Mixture of R1123 + R32 Refrigerant by Tandem Capillary Tube Method

A refrigerant mixture of R1123 + R32 is expected to be an alternative working fluid for refrigeration systems, organic Rankine cycle and heat pumps due to its lower global warming potential and transport properties. The goals of this work are to measure the viscosity of the liquid and vapor phases o...

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Veröffentlicht in:	International journal of thermophysics 2020, Vol.41 (6), Article 83
Hauptverfasser:	Mondal, Dipayan, Hori, Yoshiya, Kariya, Keishi, Miyara, Akio, Jahangir Alam, Md
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Sprache:	eng
Schlagworte:	Atpc 2019 ATPC 2019: Selected Papers of the 12th Asian Thermophysical Properties Conference Binary mixtures Capillary tubes Classical Mechanics Condensed Matter Physics Geophysics Heat pumps Industrial Chemistry/Chemical Engineering Liquid phases Physical Chemistry Physics Physics and Astronomy Rankine cycle Refrigerants Refrigeration Thermodynamics Transport properties Vapor phases Viscosity Viscosity measurement Working fluids
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creator	Mondal, Dipayan Hori, Yoshiya Kariya, Keishi Miyara, Akio Jahangir Alam, Md
description	A refrigerant mixture of R1123 + R32 is expected to be an alternative working fluid for refrigeration systems, organic Rankine cycle and heat pumps due to its lower global warming potential and transport properties. The goals of this work are to measure the viscosity of the liquid and vapor phases of this mixture refrigerant. Consequently, the viscosity of mixture refrigerant was measured by the tandem capillary tube method up to 4.5 MPa over a temperature range from 250.64 K to 312.61 K for the liquid phase and from 323.35 K to 382.88 K in the vapor phase, respectively. Mass fractions of measured R1123/R32 refrigerant mixture were 0.428/0.572 in the liquid phase and 0.425/0.575 in the vapor phase. The obtained experimental data were compared with estimated values of the ECS model, and the average absolute deviation (AAD) was found at 3.63 % in the liquid phase and 2.45 % of the vapor phase. Also, the measured liquid and vapor viscosity data were correlated with the Grunberg–Nissan method and Wilke mixture correlation, respectively, while the AAD was 1.33 % for liquid and 3.69 % for vapor phases. The total combined standard uncertainties in the liquid and vapor viscosity measurements were estimated to be less than 2.9 % and 3.0 %, respectively.
doi_str_mv	10.1007/s10765-020-02653-4
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The goals of this work are to measure the viscosity of the liquid and vapor phases of this mixture refrigerant. Consequently, the viscosity of mixture refrigerant was measured by the tandem capillary tube method up to 4.5 MPa over a temperature range from 250.64 K to 312.61 K for the liquid phase and from 323.35 K to 382.88 K in the vapor phase, respectively. Mass fractions of measured R1123/R32 refrigerant mixture were 0.428/0.572 in the liquid phase and 0.425/0.575 in the vapor phase. The obtained experimental data were compared with estimated values of the ECS model, and the average absolute deviation (AAD) was found at 3.63 % in the liquid phase and 2.45 % of the vapor phase. Also, the measured liquid and vapor viscosity data were correlated with the Grunberg–Nissan method and Wilke mixture correlation, respectively, while the AAD was 1.33 % for liquid and 3.69 % for vapor phases. 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The goals of this work are to measure the viscosity of the liquid and vapor phases of this mixture refrigerant. Consequently, the viscosity of mixture refrigerant was measured by the tandem capillary tube method up to 4.5 MPa over a temperature range from 250.64 K to 312.61 K for the liquid phase and from 323.35 K to 382.88 K in the vapor phase, respectively. Mass fractions of measured R1123/R32 refrigerant mixture were 0.428/0.572 in the liquid phase and 0.425/0.575 in the vapor phase. The obtained experimental data were compared with estimated values of the ECS model, and the average absolute deviation (AAD) was found at 3.63 % in the liquid phase and 2.45 % of the vapor phase. Also, the measured liquid and vapor viscosity data were correlated with the Grunberg–Nissan method and Wilke mixture correlation, respectively, while the AAD was 1.33 % for liquid and 3.69 % for vapor phases. 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subjects	Atpc 2019 ATPC 2019: Selected Papers of the 12th Asian Thermophysical Properties Conference Binary mixtures Capillary tubes Classical Mechanics Condensed Matter Physics Geophysics Heat pumps Industrial Chemistry/Chemical Engineering Liquid phases Physical Chemistry Physics Physics and Astronomy Rankine cycle Refrigerants Refrigeration Thermodynamics Transport properties Vapor phases Viscosity Viscosity measurement Working fluids
title	Measurement of Viscosity of a Binary Mixture of R1123 + R32 Refrigerant by Tandem Capillary Tube Method
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