Boiling heat transfer characteristics of the R744 coolant in the evaporator of the separated heat pipe system

•Studied the boiling heat transfer character of R744 in separated heat pipe system.•Boiling heat transfer character of R410A, R22 and R744has been compared.•Flow patterns of the three coolants in the vapor pipe were compared.•New empirical equations have been developed. This paper studies boiling he...

Full description

Saved in:
Bibliographic Details
Published inInternational journal of heat and mass transfer Vol. 113; pp. 1254 - 1264
Main Authors Ding, Tao, Wen Cao, Han, Guang He, Zhi, Li, Zhen
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.10.2017
Elsevier BV
Subjects
Boiling heat transfer coefficient
Bubbles
Coolants
Cooling
Empirical formula
Evaporation
Evaporative cooling
Flowing pattern
Heat flux
Heat transfer
Heat transfer coefficients
Pipes
R744
Visualization
Visualization
Flowing pattern
Boiling heat transfer coefficient
R744
Empirical formula
Online AccessGet full text

Cover

More Information
Summary:•Studied the boiling heat transfer character of R744 in separated heat pipe system.•Boiling heat transfer character of R410A, R22 and R744has been compared.•Flow patterns of the three coolants in the vapor pipe were compared.•New empirical equations have been developed. This paper studies boiling heat transfer characteristics of the R744 coolant. The heat transfer characteristics comprise the boiling heat transfer coefficient and the flowing pattern inside the vapor tube. The R744’s boiling heat transfer coefficients were measured for different filling ratios, and the results show that within the 107–138% filling ratio range, the heat transfer coefficient is almost the same for different filling ratios, but increases with increasing the heat flux. Next, the heat transfer coefficient at the high pressure region is measured. For the same filling ratio and heat transfer capacity, increasing the pressure increased the heat transfer coefficient. The boiling heat transfer coefficients and the flowing patterns for different coolants is compared, including R134a, R410A, and R744, and the boiling heat transfer coefficient of R744 was much higher than those of the other two coolants. In addition, for R744, the diameter of bubbles at the exit point of the evaporator was also smaller than those for R410A and R134a. Finally, we compared our experimental results with existing empirical results, and developed our own empirical formula based on our experimental results.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2017.05.122