Hybridization of CSP Plants: Characterization of a Molten Salt Heater for Binary and Ternary Nitrate Salt Mixtures Fueled with Gas/Biogas Heaters

Hybridization of CSP plants with alternative energy sources (fuels) represents a means to improve flexibility of operation, power dispatchability and utilization factor of the plant. New generation CSP plants make use of molten salts as Heat Transfer Fluid (HTF) besides Thermal Energy Storage (TES) medium. Therefore, proper interfaces should be developed to effectively transfer the heat from the back-up source to the molten salt. This paper presents the results obtained in the experimental validation of an innovative gas-fueled Molten Salt Heater (MSH) prototype. The objective of this research is to validate the MSH design, where the specific properties of molten salts (compared to other HTFs, e.g., thermal oils) have to be taken into account. The developed reduced-scale MSH (90 kW thermal) consists of a heat exchanger with the molten salt flowing inside finned tubes cross-flowed with the hot flue gas generated in an upstream combustion chamber. LPG or a biogas-like mixture has been used as gas fuel. Experimental results have been obtained with two different molten salt mixtures: the solar salt binary mixture (NaNO3/KNO3, 60/40%w) typically used in CSP applications (up to 565 & DEG;C) and the ternary mixture known as Hitec XL(R) containing sodium/potassium/calcium nitrates (NaNO3/KNO3/Ca(NO3)(2), 15/43/42%w) characterized by lower freezing temperatures. Experimental tests have been carried out changing some operative parameters like the flow rate of the molten salt (0.45-0.94 kg/s), the inlet temperatures of the molten salt (303-445 & DEG;C) and of the hot gas (596-632 & DEG;C). For both molten salt mixtures, it was demonstrated that heat transfer correlations based on the Dittus-Boelter equation allow to predict experimental results with < 10% deviation between experimental and theoretical values of the heat transfer coefficient.

Automated summary

Hybridization of CSP plants with alternative energy sources can improve flexibility of operation and utilization factor of the plant. Experimental results show that heat transfer correlations based on the Dittus-Boelter equation can predict experimental results effectively.