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Thermal Stability Calculation and Experimental Investigation of Common Binary Chloride Molten Salts Applied in Concentrating Solar Power Plants

Jingyu Zhong, Jing Ding, Jianfeng Lu, Xiaolan Wei, Weilong Wang

2022Energies14 citationsDOIOpen Access PDF

Abstract

A computational study on thermal stability was conducted the first time, combining the modified quasi-chemical model, the Antoine equation, and the adiabatic flash evaporation calculation principle to design a method to calculate the system pressure-temperature (P-T) phase diagram of binary chloride molten salts. The evaporation temperature of the molten salt obtained by analyzing the P-T phase diagram of the eutectic molten salt clearly defined the upper limit of the optimal operating temperature of the mixed molten salt. The results indicated that the upper-temperature limits of NaCl-KCl, NaCl-CaCl2, KCl-CaCl2, NaCl-MgCl2, and KCl-MgCl2 are determined to be 1141 K, 1151 K, 1176 K, 1086 K, and 1068 K. The maximum working temperature was measured experimentally using a thermogravimetric analysis (TGA), and the relative error between the calculation and experiment was calculated. The maximum error between the calculated and experimental values of the maximum operating temperature was 6.02%, while the minimum was 1.29%, demonstrating the method’s high accuracy. Combined with the lowest eutectic temperature and the upper-temperature limits of binary chloride molten salts, the stable operating temperature ranges of NaCl-KCl, NaCl-CaCl2, KCl-CaCl2, NaCl-MgCl2, and KCl-MgCl2 are 891~1141 K, 750~1151 K, 874~1176 K, 732~1086 K, and 696~1086 K.

Topics & Concepts

Eutectic systemMolten saltThermodynamicsPhase diagramChemistryAdiabatic processAnalytical Chemistry (journal)EvaporationThermal stabilityPhase (matter)Thermogravimetric analysisSalt (chemistry)Inorganic chemistryPhysical chemistryPhysicsCrystallographyChromatographyMicrostructureOrganic chemistryMetallurgical Processes and ThermodynamicsPhase Change Materials ResearchRadiative Heat Transfer Studies