Abstract
Recently, there has been a noticeable increase in the applications of composite mixtures containing molten salt and solid oxide for thermal energy conversion and storage systems. This highlights that thermal conductivity of the composites are central for the purpose of designing and devising processes. Measuring the thermal conductivity of molten samples at elevated temperatures remains challenging. In this study, the possibility to use heat flux differential scanning calorimetry (DSC) to measure the thermal conductivity of molten samples at elevated temperatures is reported for the first time. The thermal conductivity of composite mixtures containing eutectic (Li,Na)2CO3 with and without selected solid oxides at ~675 °C was determined by using the proposed DSC approach. This mixture is a candidate for high temperature waste heat conversion to electric energy. In the DSC measurement program, steps with repeated thermal cycles between 410 and 515 °C were included to limit the effect of the interface thermal contact resistance. The determined values 0.826 ± 0.001, and 0.077 ± 0.004 W m−1K−1 for the carbonate mixtures with and without solid MgO were found to match the reliable analysis at similar conditions.
Highlights
Molten salt based composite mixtures are emerging as vital components for many high temperature heat conversion and storage systems [1,2,3,4]
The thermal conductivity of composite mixtures containing molten carbonate and solid oxides was determined by the differential scanning calorimetry (DSC) approach
For the mixtures containing eutectic (Li,Na)2 CO3 with and without solid MgO, the measured thermal conductivity was identical to the laser flash analysis (LFA) and a reliable data set in the literature [15]
Summary
Molten salt based composite mixtures are emerging as vital components for many high temperature heat conversion and storage systems [1,2,3,4]. Electrolyte mixtures, in the form of composites with molten carbonate and solid oxide, were found to be suitable for high temperature thermoelectric cells with liquid electrolyte (i.e., thermocell) [4,7,8]. Utilization of these composites was found to improve conditions for operation and enhance efficiency. Many high temperature thermal conductivity measurement techniques have been established, such as transient hot-wire/strip and laser flash analysis (LFA) [13,14]. Due to the high electrical conductivity, the transient hot-wire requires a non-conducting probe to measure in melts [15,16]
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