Heat transfer characteristics of ceramic foam/molten salt composite phase change material (CPCM) for medium-temperature thermal energy storage

•Phase change heat transfer of medium-temperature thermal energy storage.•Experimental and numerical investigations.•Boosted heat conduction by the ceramic foam accelerates the melting.•Porous ceramic foam is proved to enhance the heat transfer in molten salts. Molten salts have been widely used as...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2022-11, Vol.196, p.123262, Article 123262
Main Authors: Zhang, Shuai, Yao, Yuanpeng, Jin, Yingai, Shang, Zhen, Yan, Yuying
Format: Article
Language:English
Subjects:
Ceramic
Medium temperature
Molten salt
Phase change heat transfer
Thermal energy storage
Visualization
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Summary:•Phase change heat transfer of medium-temperature thermal energy storage.•Experimental and numerical investigations.•Boosted heat conduction by the ceramic foam accelerates the melting.•Porous ceramic foam is proved to enhance the heat transfer in molten salts. Molten salts have been widely used as energy storage materials in medium- and high-temperature thermal energy storage. However, pure salt commonly suffers from low thermal conductivity and many conventional methods of heat transfer enhancement do not apply due to the serious corrosion and the extremely high temperature. In the current study, the open-cell SiC ceramic foam was integrated with solar salt (60wt% NaNO3 + 40wt% KNO3) to enhance the heat transfer of salt and avoid severe corrosion issues. A visualised experiment was for the first time conducted to investigate the melting phase change heat transfer in the ceramic foam/molten salt composite phase change material (CPCM). A representative elementary volume (REV)-scale simulation was simultaneously performed and the computational results were compared with experimental data. It is found that the conduction-friendly ceramic skeleton remarkably enhances the heat transfer in molten salt, especially in the region far away from the heat source. The spatial temperature difference across the composite is decreased in both horizontal and vertical directions and the local superheating is mitigated. The enhancement of heat conduction is greater than the suppression of natural convection; as a result, the melting rate of the CPCM is increased by 41.3%. This study provides crucial benchmark data of phase change heat transfer for medium-temperature thermal energy storage and paves the way for system design and optimization.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2022.123262