Experimental study on CHF of R134a flow boiling in a horizontal helically-coiled tube near the critical pressure

•Character of temperatures in CHF locations was investigated at near critical pressures.•Parameter trends for CHF at near critical pressures were discussed.•A CHF correlation was developed based on the experiment. Critical heat flux (CHF) experiments were conducted in a uniformly heated horizontal h...

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Bibliographic Details
Published in:Experimental thermal and fluid science 2017-04, Vol.82, p.472-481
Main Authors: Tan, Luzhi, Chen, Changnian, Dong, Xiaoming, Gong, Zhiqiang, Wang, Mingtao
Format: Article
Language:English
Subjects:
Boiling
Coiling
Critical heat flux
Critical point
Critical pressure
Cross-sections
Fluctuations
Heat flux
Heat transfer
Horizontal helically-coiled tube
Nucleate boiling
Pressure
R134a
Supercritical processes
Temperature
Temperature effects
The critical pressure
Wall temperature
Working fluids
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Summary:•Character of temperatures in CHF locations was investigated at near critical pressures.•Parameter trends for CHF at near critical pressures were discussed.•A CHF correlation was developed based on the experiment. Critical heat flux (CHF) experiments were conducted in a uniformly heated horizontal helically-coiled tube to investigate the CHF characteristics at near the critical pressures with R134a as the working fluid. The experiments were performed over a wide range of parameters: pressure from 2.85 to 4.03MPa, i.e., reduced pressures (Pr) ranging from 0.70 to 0.99, mass flux from 250 to 2100kgm−2s−1, inlet subcooling from 45 to 160kJkg−1 and heat flux from 20 to 450kWm−2. Two types of CHF phenomenon which are dry-out (DO) and departure from nucleate boiling (DNB) have occurred under the experimental conditions. The DO happens at the lower pressures while the DNB happens at the higher pressures. The wall temperature shows a very different characteristic for the two types of CHF. Under the DO conditions, wall temperature gets a sudden rise firstly at the inner-side of the outlet cross-section and temperature at the other side remains on a lower level, while under the DNB conditions, wall temperature around the outlet cross-section jumps almost simultaneously. When the pressure is very close to the critical point, there is a constant pressure region where the wall temperature rises gently and the CHF no longer exists. The effects of the mass flux and inlet subcooling on CHF have also been discussed. Based on the experiment, a correlation applied for the pressure region close to the critical pressure was proposed to estimate the CHF in the horizontal helically-coiled tube.
ISSN:0894-1777
1879-2286
DOI:10.1016/j.expthermflusci.2016.12.005