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A pilot project of TESS equipped with two models of encapsulation for nano-enhanced organic PCMs.

Authors :
Alaei, Pouyan
Ghasemi, Behzad
Raisi, Afrasiab
Torabi, Amir
Source :
Advances in Building Energy Research; Oct2022, Vol. 16 Issue 5, p643-668, 26p
Publication Year :
2022

Abstract

The unique thermal energy storage system (TESS) as an auxiliary system of solar water heater has a critical part to demonstration in preserving and efficiently utilizing energy, resolving demand-supply mismatches, and boosting the efficiency of energy systems. In this research, a suitable Nano enhanced-Composite Phase Change Material (NCPCM) was prepared to utilize in two model of metal cylinders. First of all, an experimental test for determination of melting point has been investigated by temperature variation test (TVT) method for NCPCM based on paraffin component. Then, two nanomaterial types (TiO<subscript>2</subscript> and CuO) mixed at 50%/50% with two concentrations (0.6% and 0.12%) were dispersed with slack paraffin to provide a total of four experiments to compare the average temperature evolution and exergy efficiency. A theoretical framework for exergy analysis give away that use of nano composites in PCMs will improve efficiency rather than a single nanomaterial. However, to assess capability of this system to integrate with solar water heater, if there is no solar radiation limitation, NCPCM with 1.2% wt. will be a better choice with higher cylinders diameter (HD-Cylinders). Neverthless, for climates with limited time in storage energy, NCPCM with 1.2% wt. and lower cylinders diameter (LD-Cylinders) is our best suggestion for maximum efficiency that can be used during the peak solar energy period. Therefore, by considering NCPCM and integrating this novel study with solar technologies as a reliable heat source, outline is an excellent way for saving energy consumption in buildings at any remote area. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
17512549
Volume :
16
Issue :
5
Database :
Complementary Index
Journal :
Advances in Building Energy Research
Publication Type :
Academic Journal
Accession number :
159176888
Full Text :
https://doi.org/10.1080/17512549.2022.2079001