Theoretical calculation on forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside tube

M. Chen; P. W. Li; Q. W. Wang; W. Q. Tao

Theoretical calculation on forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside tube

M. Chen, P. W. Li, Q. W. Wang, W. Q. Tao

Aerospace and Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

A theoretical approach to forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside smooth tubes was developed. Calculations were performed for R32/R134a mixtures with the R32 mass fraction ranged from 0 to 60.1%. The results reveals that there is a reduction of heat transfer coefficient for a nonazeotropic mixture compared with that of a single component substance with the same thermophysical properties. The reduction of the heat transfer coefficient depends not only on the mass fraction of the mixture, but also on the vapor quality of the fluid. Besides, minimum heat transfer coefficients were observed at mass fractions ranging from 10% to 30% for R32/R234a mixtures.

Original language	English (US)
Pages (from-to)	114-118
Number of pages	5
Journal	Huagong Xuebao/Journal of Chemical Industry and Engineering (China)
Volume	52
Issue number	2
State	Published - Feb 2001

Keywords

Condensation heat transfer
Nonazeotropic mixture
Theoretical calculation

ASJC Scopus subject areas

Chemistry(all)
Chemical Engineering(all)

Cite this

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title = "Theoretical calculation on forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside tube",

abstract = "A theoretical approach to forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside smooth tubes was developed. Calculations were performed for R32/R134a mixtures with the R32 mass fraction ranged from 0 to 60.1%. The results reveals that there is a reduction of heat transfer coefficient for a nonazeotropic mixture compared with that of a single component substance with the same thermophysical properties. The reduction of the heat transfer coefficient depends not only on the mass fraction of the mixture, but also on the vapor quality of the fluid. Besides, minimum heat transfer coefficients were observed at mass fractions ranging from 10% to 30% for R32/R234a mixtures.",

keywords = "Condensation heat transfer, Nonazeotropic mixture, Theoretical calculation",

author = "M. Chen and Li, {P. W.} and Wang, {Q. W.} and Tao, {W. Q.}",

year = "2001",

month = feb,

language = "English (US)",

volume = "52",

pages = "114--118",

journal = "Huagong Xuebao/Journal of Chemical Industry and Engineering (China)",

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T1 - Theoretical calculation on forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside tube

AU - Chen, M.

AU - Li, P. W.

AU - Wang, Q. W.

AU - Tao, W. Q.

PY - 2001/2

Y1 - 2001/2

N2 - A theoretical approach to forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside smooth tubes was developed. Calculations were performed for R32/R134a mixtures with the R32 mass fraction ranged from 0 to 60.1%. The results reveals that there is a reduction of heat transfer coefficient for a nonazeotropic mixture compared with that of a single component substance with the same thermophysical properties. The reduction of the heat transfer coefficient depends not only on the mass fraction of the mixture, but also on the vapor quality of the fluid. Besides, minimum heat transfer coefficients were observed at mass fractions ranging from 10% to 30% for R32/R234a mixtures.

AB - A theoretical approach to forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside smooth tubes was developed. Calculations were performed for R32/R134a mixtures with the R32 mass fraction ranged from 0 to 60.1%. The results reveals that there is a reduction of heat transfer coefficient for a nonazeotropic mixture compared with that of a single component substance with the same thermophysical properties. The reduction of the heat transfer coefficient depends not only on the mass fraction of the mixture, but also on the vapor quality of the fluid. Besides, minimum heat transfer coefficients were observed at mass fractions ranging from 10% to 30% for R32/R234a mixtures.

KW - Condensation heat transfer

KW - Nonazeotropic mixture

KW - Theoretical calculation

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JO - Huagong Xuebao/Journal of Chemical Industry and Engineering (China)

JF - Huagong Xuebao/Journal of Chemical Industry and Engineering (China)

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ER -

Theoretical calculation on forced convective condensation heat transfer coefficient of nonazeotropic mixtures inside tube

Abstract

Keywords

ASJC Scopus subject areas

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