Development and Investigation of Nitrate Phase Change Filler Material for Solar Process Heating Applications

Authors

DOI:

https://doi.org/10.52825/solarpaces.v2i.917

Keywords:

Solar Thermal Energy, Thermocline Thermal Energy Storage System, Phase Change Phenomena, Solar Salt, Process Heating Applications

Abstract

Thermocline thermal energy storage system is an imperial system for solar process heating applications. The thermal energy storage system comprises filler material and heat transfer fluid. In the present study, the commercial phase change material (PCM) (filler material) solar salt (60%NaNO3+40%KNO3) is synthesized, and it is encapsulated with a 1mm thickness of stainless steel 316L encapsulation with the macro-size of 60mm; the encapsulated PCMs is considered as a single particle in the thermocline thermal energy storage system. The performance of the single encapsulated PCM is studied with a constant heat transfer fluid (Therminol-VP1) flow rate of 0.00015 kg/s during the charging process. The specific heat of the solar salt is measured in Differential Scanning Calorimeter (DSC) in the solid phase is found as 1.381 J/gK, and liquid phase is identified as 1.551 J/g-K, the enthalpy during the phase change process is found as 116.72 J/g. As well, the thermal conductivity of the solar salt is measured in Transient Heat Conduction method, and the thermal conductivity follows the linear relationship of -0.0025(T)+0.4023 (45ºC<T<100ºC) in the sensible region. The temperature variations and the phase change phenomena for the solar salt is identified and the contours are provided. The charging time for the encapsulated solar salt is identified as ~138 minutes. The energy storage cost for the single filler material (Solar Salt + SS316L encapsulation) is identified as Rs.5.93/- (USD 0.071) for the period of charging duration.

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References

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Published

2024-07-24

How to Cite

Pradeep, N., & Reddy, K. (2024). Development and Investigation of Nitrate Phase Change Filler Material for Solar Process Heating Applications. SolarPACES Conference Proceedings, 2. https://doi.org/10.52825/solarpaces.v2i.917

Conference Proceedings Volume

Section

Thermal Energy Storage Materials, Media, and Systems
Received 2023-10-22
Accepted 2024-05-03
Published 2024-07-24