Development of low-cost sodium acetate trihydrate-based eutectic hydrate composites for thermal energy storage

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🔬研究者:Materials scientists can leverage the cost-effective eutectic formulation to further optimize thermal storage systems for grid-scale renewable applications.

Research into more effective energy storage materials and technologies has recently come to the forefront as a means to meet the urgent need for renewable energy. The CH3COONa⋅3H2O (sodium acetate trihydrate, SAT) offers great promise as a phase change material (PCM) for energy storage devices that operate at medium to low temperatures, but it has serious drawbacks such a strong supercooling effect and poor thermal conductivity. The use of expensive chemicals in traditional methods to improve SAT’s thermal performance has limited their industrial scale usage. This research presents SAT as a starting point, and then uses a fusion blending technique to eutectic hydrated salt composite phase change materials (CPCMs) with various ratios of disodium hydrogen phosphate dodecahydrate (DHPD) or sodium sulfate decahydrate (SSD). The findings show that the eutectic hydrates that were made successfully reduce the angle of pure SAT more than 35℃ to less than 5℃. Notably, these eutectic blends exhibit enhanced thermal conductivity (sodium acetate trihydrate /SSD-3/7 coefficient of 0.893 W·(m⋅K) -1 ) and remarkable latent heat capacity (SAT/SSD9/1 provides 195.42 J·g -1 ). In addition, the sodium acetate trihydrate eutectic hydrates were ideal for commercially significant scale applications since they do not contain costly additives, easy to produce, and work throughout a wide temperature range (20-60℃).

• semanticscholar https://doi.org/10.1051/epjconf/202634501061first seen 2026-05-15 20:39:33 · last seen 2026-06-10 05:24:47