A comprehensive review of cover-shield-assisted radiant cooling system

[Display omitted] •State-of-the-art review and discussion on the CS-RCS presented.•CS-RCS provides higher cooling capacity without condensation in humid climates.•Heat transfer principles of the different CS-RCS configurations discussed.•Thermal comfort and energy saving potential of CS-RCS discusse...

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Bibliographic Details
Published in:Energy and buildings 2023-07, Vol.291, p.113121, Article 113121
Main Authors: Dharmasastha, K., Zhong, Ziwen, Niu, Jianlei, Liang, Haobin
Format: Article
Language:English
Subjects:
Aerogel-assisted radiant cooling
Membrane-assisted radiant cooling
Outdoor cooling
Spectral IR transparency
Thermal comfort
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Summary:[Display omitted] •State-of-the-art review and discussion on the CS-RCS presented.•CS-RCS provides higher cooling capacity without condensation in humid climates.•Heat transfer principles of the different CS-RCS configurations discussed.•Thermal comfort and energy saving potential of CS-RCS discussed. As an alternative to all-air conditioning systems, radiant cooling has the potential for energy saving and better thermal comfort. One of the limitations of radiant cooling is the risk of condensation on radiating surfaces when the surface temperature falls below the ambient dew point temperature. One of the possibilities to avoid condensation is to isolate the cooling surface from the ambient air with a cover-shield, such as an infrared-transparent membrane or aerogel. This method would reduce surface convective cooling, making the system potentially applicable in outdoor and indoor spaces with natural ventilation. The objective of this review study is to provide a fundamental understanding of cover-shield-assisted radiant cooling systems. The present research study summarizes a review in terms of possible system configurations, the use of infrared-transparent cover materials, heat transfer modeling, ranges of cooling capacity, and thermal comfort performance. As cover-shield-assisted radiant cooling systems are in the early stage of development, this study would aid in identifying further research needs for engineering applications. Future research could focus on improving cover-shield strength and enhancing spectral IR transparency to further improve system design and performance. Additionally, the potential deployment of this technology in open spaces such as bus stops, sitting-out areas, and parks is yet to be explored.
ISSN:0378-7788
DOI:10.1016/j.enbuild.2023.113121