Investigation on heat transfer of in-tube supercritical water cooling accompanying out-tube pool boiling

•Tested in-tube cooling heat transfer of SCW accompanying out-tube pool boiling.•Measured heat duty accurately by using thermal amplification system.•Developed a modified Gnielinski correlation for heat transfer coefficient. Heat transfer of in-tube supercritical fluid cooling accompanying out-tube...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2019-06, Vol.136, p.938-949
Main Authors: Lv, Haicai, Bi, Qincheng, Dong, Xinyu, Zhang, Zanjian, Zhu, Ge
Format: Article
Language:English
Subjects:
Circular tubes
Cooling
Cooling with pool boiling
Film boiling
Heat flux
Heat transfer
Heat transfer coefficients
Liquid cooling
Nucleate boiling
Physical properties
Supercritical fluids
Supercritical water
Temperature gradients
Thermal amplification
Thermophysical properties
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Summary:•Tested in-tube cooling heat transfer of SCW accompanying out-tube pool boiling.•Measured heat duty accurately by using thermal amplification system.•Developed a modified Gnielinski correlation for heat transfer coefficient. Heat transfer of in-tube supercritical fluid cooling accompanying out-tube pool boiling was investigated. A smooth horizontal circular tube with an inside-diameter of 20 mm was submerged in a water pool at atmospheric pressure. Test parameters of in-tube were as follows: Pressure: 23–28 MPa, mass flux: 600–1000 kg·m−2·s−1, fluid temperature: 400–725 K, and the temperature difference between bulk and wall: 300–374 K. A thermal amplification system based on out-tube pool boiling was used to improve the measurement accuracy of local heat duty near pseudocritical region. According to the experiment, the transition from nucleate boiling to film boiling in the pool occurred near the pseudo-critical fluid region. Sharp variation on thermo-physical properties led to the peak value of heat transfer coefficient in the pseudo-critical region. The pool boiling heat flux increased gradually to 1.19 MW·m−2 near the pseudocritical point. Based on the experimental data, a modified Gnielinski equation was adopted to predict the heat transfer coefficient of in-tube supercritical fluid cooling with out-tube pool boiling. The thermophysical property ratio of the wall to the bulk as well as the effect of buoyancy were taken into consideration in the new correlation. The predicted correlation has an error of less than 20% to the experimental data.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2019.03.069