Design and modeling of a high temperature solar thermal energy storage unit based on molten soda lime silica glass

•The design of a high temperature silica glass based thermal energy storage unit is presented.•The development of a quasi-bidimensional thermal model is discussed.•The performance of the 126kWhth TES is assessed through the transient model.•An in-depth exergy analysis of the behavior of the TES unit...

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Bibliographic Details
Published in:Solar energy 2016-03, Vol.126, p.32-43
Main Authors: Cárdenas, Bruno, León, Noel, Pye, John, García, Héctor D.
Format: Article
Language:English
Subjects:
Design
Energy efficiency
Energy storage
Exergy analysis
High temperature
High temperature energy storage
Mathematical models
Sensible heat storage
Silica
Soda-lime silica glass
Solar energy
Solar power
Solar thermal energy storage
Thermal energy
Thermal storage
Thermodynamics
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Summary:•The design of a high temperature silica glass based thermal energy storage unit is presented.•The development of a quasi-bidimensional thermal model is discussed.•The performance of the 126kWhth TES is assessed through the transient model.•An in-depth exergy analysis of the behavior of the TES unit is performed, obtaining an exergy efficiency of 59%. The present article addresses the design, mathematical modeling and analysis of a high temperature solar thermal energy storage unit based on molten soda-lime silica glass. The 126kWhth storage unit is aimed to be used as one of the main components of a novel solar power-generation system intended for a continuous operation. The proposed design for the unit, as well as the restrictions imposed by its intended operation inside the power generation system, are thoroughly discussed. The development of the mathematical model used to calculate the efficiency and performance of the thermal storage unit during the different stages of the work cycle as well as the assumptions and simplifications made are comprehensively explained. The results obtained through the model are exhaustively analyzed. Special attention is paid to the assessment of the behavior of the storage unit to guarantee that the functional requirements are met; the performance of the unit is not evaluated exclusively from an energy standpoint, but an in-depth exergy analysis is also presented. The overall performance of the TES unit is satisfactory; the unit is capable of supplying the required 4kWth output throughout the 16-h discharge while it reaches its fully charged state during the subsequent 8-h recharge. The proposed designed for the TES unit exhibits a round trip exergy-efficiency of 59%.
ISSN:0038-092X
1471-1257
DOI:10.1016/j.solener.2015.12.034