Exploration of dual-phase change coupled heat transfer in solar regenerative evaporator

To improve the efficiency of the system, a solar assisted heat pump (SAHP) evaporator could be used in conjunction with phase change slurry (PCS) as a working fluid for heat storage, transfer, and release. However, more research needs to be carried out on the state-of-the-art of dual-phase change co...

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Bibliographic Details
Published in:Energy (Oxford) 2024-04, Vol.293, p.130560, Article 130560
Main Authors: Li, Sheng, Gao, Jinshuang, Zhang, Lizhe, Zhao, Yazhou, Zhang, Xuejun
Format: Article
Language:English
Subjects:
Dual-phase change coupled
energy
Heat pump
heat pumps
Heat transfer
heat transfer coefficient
particle size
Phase change
phase transition
slurries
Solar energy
vapors
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Summary:To improve the efficiency of the system, a solar assisted heat pump (SAHP) evaporator could be used in conjunction with phase change slurry (PCS) as a working fluid for heat storage, transfer, and release. However, more research needs to be carried out on the state-of-the-art of dual-phase change coupled heat transfer between PCS and refrigerant. In order to explore coupled heat transfer and the influences on the upper and lower coupling interfaces of the horizontal evaporator pipe, a numerical heat transfer model that integrates phase change material capsule (PCMC) flow is applied. The ideal mixture of 15 vol% PCS with the particle size of 10 μm was shown to increase heat transfer by 0.60 %–1.17 % and 1.14 %–1.69 % at the upper and lower coupling interfaces, respectively. As a consequence, an increase in PCS inflow rate and inlet vapor leads to an increase in the equilibrium concentration of PCMC near the lower coupling interface. Additionally, a decrease in heat transfer around 3.64 %–4.87 % was experienced when the inflow rate of PCS was increased from 0.2 m∙s−1 to 0.4 m∙s−1. When the initial volume fraction of vapor at the upper coupling interface increased from 0 vol% to 5 vol%, the heat transfer coefficient decreased from 329.44 W∙m−2 K−1 to 299.36 W∙m−2 K−1. Although the heat transfer reduction ratios at the lower coupling interface varied from 4.16 % to 4.51 %, they were still higher than those at the upper coupling interface. The study provides first findings and insights into the coupled heat transfer under consideration. Geometric model of coupled heat transfer. [Display omitted] •PCS with PCMC content of 15 vol% and diameter of 10 μm is preferred for SAHP.•PCMC accumulates more near the lower interface due to heat transfer and flow.•Enhanced heat transfer ratio due to PCMC accumulation reaches 7.17 %–11.30 %.•Increasing PCS flow rate and volume fraction of vapor would lead to increase in PCMC concentration.
ISSN:0360-5442
DOI:10.1016/j.energy.2024.130560