Thermal performance of a binary carbonate molten eutectic salt for high- temperature energy storage applications
GCQ Pan and XL Wei and C Yu and YT Lu and J Li and J Ding and WL Wang and J Yan, APPLIED ENERGY, 262, 114418 (2020).
DOI: 10.1016/j.apenergy.2019.114418
Molten carbonate eutectic salts are promising thermal storage and heat transfer fluid materials in solar thermal power plant with the feature of large specific heat capacity, wide operating temperature range and little corrosive. The high-temperature properties of molten carbonates should be determined accurately over the entire operating temperature for energy system design. In this paper, molecular dynamic simulation is used to study temperature and component dependence of microstructures and thermophysical properties of the binary carbonate molten salt. Negative linear temperature dependence of densities and thermal conductivities of binary mixtures of different components is confirmed with respect to the distances of ion clusters. Besides, positive linear temperature dependence of self-diffusion coefficient is also obtained. When temperature is constant, densities and thermal conductivities of binary mixtures are linearly related with components. Self-diffusion coefficients of CO32- firstly increase and then decrease with increasing mole fraction of Na2CO3. The temperature-thermophysical properties- composition correlation formulas are obtained, and the database of thermophysical properties of molten carbonate salts over the entire operating temperature is complemented, which will provide the essential data for heat transfer and storage system design, operation, and optimization in CSP.
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