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Solar photovoltaics integrated with hydrated salt-based phase change material

Solar photovoltaics integrated with hydrated salt-based phase change material
Solar photovoltaics integrated with hydrated salt-based phase change material

Maintaining the temperature of the photovoltaic (PV) panel within the described standard helps in achieving higher power conversion efficiency. To regulate the PV temperature, phase change material (PCM)-based cooling techniques have been proposed in several literature. However, most of the studies utilize organic PCMs whose low thermal conductivity confines their potential. Thus, in the proposed work, the rear side of the 20 Wp PV panel is coated with hydrated salt-based PCM and is integrated with an aluminum sheet (PV–PCM–Al) to increase the thermal conductivity of the system. The effect of the PV–PCM–Al panel in enhancing the PV efficiency is realized by comparing it with a standard uncooled PV panel. This concept was experimented under direct sunlight for about a week in Chennai, the southern part of India. To perceive the performance enhancement, thermal images were taken for both the cooled and uncooled PV panels. In addition, open-circuit voltage, short-circuit current, and power output were measured. The experimentation is also backed up by numerical simulations to understand the heat transfer characteristic features of the designed integrated PCM and aluminum cooling system. The experimentation results highlight that a maximum increase of about 7.67% in the PV efficiency was obtained using a cooled PV panel when compared to an uncooled PV panel. A maximum increase of 7.34% in the open-circuit voltage and a maximum drop of 4.6 °C in the PV temperature were obtained.

aluminum, CFD, cooling, efficiency, energy, heat transfer, phase change material, photovoltaic, solar
0199-6231
Elavarasan, Rajvikram Madurai
76908d38-015a-4164-a939-574a59ff5ff1
Singh, Preeti
eba3a34d-0500-424e-8481-5ee3c5eb06a3
Leoponraj, S.
88cd5541-961b-48e0-bf6d-766e6eda0540
Khanna, Sourav
107f4edb-7b07-4bea-bdfb-818d4f03bea9
Chandran, Mohanraj
8632dbae-cd21-4cc4-a334-5572d199ef88
Elavarasan, Rajvikram Madurai
76908d38-015a-4164-a939-574a59ff5ff1
Singh, Preeti
eba3a34d-0500-424e-8481-5ee3c5eb06a3
Leoponraj, S.
88cd5541-961b-48e0-bf6d-766e6eda0540
Khanna, Sourav
107f4edb-7b07-4bea-bdfb-818d4f03bea9
Chandran, Mohanraj
8632dbae-cd21-4cc4-a334-5572d199ef88

Elavarasan, Rajvikram Madurai, Singh, Preeti, Leoponraj, S., Khanna, Sourav and Chandran, Mohanraj (2022) Solar photovoltaics integrated with hydrated salt-based phase change material. Journal of Solar Energy Engineering, Transactions of the ASME, 144 (5), [051004]. (doi:10.1115/1.4054028).

Record type: Article

Abstract

Maintaining the temperature of the photovoltaic (PV) panel within the described standard helps in achieving higher power conversion efficiency. To regulate the PV temperature, phase change material (PCM)-based cooling techniques have been proposed in several literature. However, most of the studies utilize organic PCMs whose low thermal conductivity confines their potential. Thus, in the proposed work, the rear side of the 20 Wp PV panel is coated with hydrated salt-based PCM and is integrated with an aluminum sheet (PV–PCM–Al) to increase the thermal conductivity of the system. The effect of the PV–PCM–Al panel in enhancing the PV efficiency is realized by comparing it with a standard uncooled PV panel. This concept was experimented under direct sunlight for about a week in Chennai, the southern part of India. To perceive the performance enhancement, thermal images were taken for both the cooled and uncooled PV panels. In addition, open-circuit voltage, short-circuit current, and power output were measured. The experimentation is also backed up by numerical simulations to understand the heat transfer characteristic features of the designed integrated PCM and aluminum cooling system. The experimentation results highlight that a maximum increase of about 7.67% in the PV efficiency was obtained using a cooled PV panel when compared to an uncooled PV panel. A maximum increase of 7.34% in the open-circuit voltage and a maximum drop of 4.6 °C in the PV temperature were obtained.

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More information

Published date: October 2022
Additional Information: Publisher Copyright: Copyright © 2022 by ASME.
Keywords: aluminum, CFD, cooling, efficiency, energy, heat transfer, phase change material, photovoltaic, solar

Identifiers

Local EPrints ID: 506110
URI: http://eprints.soton.ac.uk/id/eprint/506110
DOI: doi:10.1115/1.4054028
ISSN: 0199-6231
PURE UUID: 852ebb66-a436-4423-9eea-f30215944c62

Catalogue record

Date deposited: 28 Oct 2025 18:28
Last modified: 28 Oct 2025 18:28

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Contributors

Author: Rajvikram Madurai Elavarasan
Author: Preeti Singh
Author: S. Leoponraj
Author: Sourav Khanna
Author: Mohanraj Chandran

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