Review on the challenges of salt phase change materials for energy storage in concentrated solar power facilities

•The latest findings of salt phase change material research for energy storage are presented.•An analysis of factors required for successful commercial implementation is presented.•Modelling studies show cost-effectiveness of latent heat energy storage systems surpasses sensible heat storage.•Cascad...

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Veröffentlicht in:Applied thermal engineering 2024-02, Vol.238, p.122034, Article 122034
Hauptverfasser: Ong, Teng-Cheong, Sarvghad, Madjid, Bell, Stuart, Will, Geoffrey, Steinberg, Theodore A., Yin, Yanting, Andersson, Gunther, Lewis, David
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Sprache:eng
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Zusammenfassung:•The latest findings of salt phase change material research for energy storage are presented.•An analysis of factors required for successful commercial implementation is presented.•Modelling studies show cost-effectiveness of latent heat energy storage systems surpasses sensible heat storage.•Cascaded shell and tube or encapsulated configurations are most cost-competitive.•Chlorides and fluoride salts are the best candidates for high-temperature energy storage.•Recommendations for future proto-typing of salt phase change material storage systems are presented. Concentrated Solar Thermal Power has an advantage over other renewable technologies because it can provide 24-hour power availability through its integration with a thermal energy storage system. Phase change materials in the form of eutectic salt mixtures show great promise as a potential thermal energy storage medium. These salts are typically low cost, have a large energy storage density, are easily sourced/abundant and their use has a low environmental impact. Implementing molten salts as part of a thermal energy storage system, however, comes with some unique challenges. There are significant engineering design and material compatibility hurdles that need to be overcome and have made prototyping such a storage system difficult. This review summarises new advancements in phase change material research, a comparison analysis of salts and other storage technologies, and recommendations for future work required to address these challenges. Topics of interest include the latest simulation/modeling work for shell-and-tube and encapsulated storage configurations, corrosion degradation studies, and innovative optimization investigations from a larger power plant perspective. From the overall findings presented, if impurity levels can be stringently controlled in conjunction with better salt selection and better fidelity modeling studies, the prototyping of an effective commercial-scale storage system is feasible. Even though this technology is still in its infancy stage, salt phase change materials are a promising solution to the energy storage problem.
ISSN:1359-4311
DOI:10.1016/j.applthermaleng.2023.122034