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Experimental investigation of solar photovoltaic panel integrated with phase change material and multiple conductivity-enhancing-containers

Experimental investigation of solar photovoltaic panel integrated with phase change material and multiple conductivity-enhancing-containers
Experimental investigation of solar photovoltaic panel integrated with phase change material and multiple conductivity-enhancing-containers

Among all passive methods for photovoltaics (PV) cooling, phase change material (PCM) can be highly effective due to high latent heat capacity. However, very low thermal-conductivity of PCM restricts its potential. The proposed work focuses on the enhancement of rate of heat transfer from PV to PCM by using conductivity-enhancing-containers. The proposed approach was experimented outdoor and compared with the reference panel for different seasons at Chennai, India. PV temperature, open circuit voltage, short circuit current, Current-Voltage (I–V) and Power-Voltage (P–V) curves, fill-factors, power outputs, efficiency and daily electricity generation are reported. The results show that the proposed heat sink was able to decrease the maximum PV temperature from 64.4 °C to 46.4 °C for January and 77.1 °C to 53.8 °C for June. It increased the open circuit voltage of PV from 24.3 V to 26.4 V for January and 23.6 V to 26.0 V for June. The fill-factor increased from 0.678 to 0.705 for January. Consequently, the electrical efficiency increased from 9.5% to 10.5% during noon. Daily electricity generation increased from 769 Wh/day to 817 Wh/day during January and 948 Wh/day to 1026 Wh/day during June. Thus, daily electricity generation increased by 6.2% for January and 8.3% for June using proposed approach.

Phase change material, Photovoltaic panel, Temperature regulation
0360-5442
Singh, Preeti
eba3a34d-0500-424e-8481-5ee3c5eb06a3
Mudgal, Vijay
66ba4093-ce27-4c83-a4b1-9457d22faf0a
Khanna, Sourav
107f4edb-7b07-4bea-bdfb-818d4f03bea9
Mallick, Tapas K.
cdd02dad-d40e-45ad-b72c-be0f44e9cddf
Reddy, K. S.
55fb2ce8-bf9c-47bd-b329-af40739b2131
Singh, Preeti
eba3a34d-0500-424e-8481-5ee3c5eb06a3
Mudgal, Vijay
66ba4093-ce27-4c83-a4b1-9457d22faf0a
Khanna, Sourav
107f4edb-7b07-4bea-bdfb-818d4f03bea9
Mallick, Tapas K.
cdd02dad-d40e-45ad-b72c-be0f44e9cddf
Reddy, K. S.
55fb2ce8-bf9c-47bd-b329-af40739b2131

Singh, Preeti, Mudgal, Vijay, Khanna, Sourav, Mallick, Tapas K. and Reddy, K. S. (2020) Experimental investigation of solar photovoltaic panel integrated with phase change material and multiple conductivity-enhancing-containers. Energy, 205, [118047]. (doi:10.1016/j.energy.2020.118047).

Record type: Article

Abstract

Among all passive methods for photovoltaics (PV) cooling, phase change material (PCM) can be highly effective due to high latent heat capacity. However, very low thermal-conductivity of PCM restricts its potential. The proposed work focuses on the enhancement of rate of heat transfer from PV to PCM by using conductivity-enhancing-containers. The proposed approach was experimented outdoor and compared with the reference panel for different seasons at Chennai, India. PV temperature, open circuit voltage, short circuit current, Current-Voltage (I–V) and Power-Voltage (P–V) curves, fill-factors, power outputs, efficiency and daily electricity generation are reported. The results show that the proposed heat sink was able to decrease the maximum PV temperature from 64.4 °C to 46.4 °C for January and 77.1 °C to 53.8 °C for June. It increased the open circuit voltage of PV from 24.3 V to 26.4 V for January and 23.6 V to 26.0 V for June. The fill-factor increased from 0.678 to 0.705 for January. Consequently, the electrical efficiency increased from 9.5% to 10.5% during noon. Daily electricity generation increased from 769 Wh/day to 817 Wh/day during January and 948 Wh/day to 1026 Wh/day during June. Thus, daily electricity generation increased by 6.2% for January and 8.3% for June using proposed approach.

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More information

Published date: 15 August 2020
Additional Information: Publisher Copyright: © 2020 Elsevier Ltd
Keywords: Phase change material, Photovoltaic panel, Temperature regulation

Identifiers

Local EPrints ID: 505892
URI: http://eprints.soton.ac.uk/id/eprint/505892
DOI: doi:10.1016/j.energy.2020.118047
ISSN: 0360-5442
PURE UUID: f3fa43fc-e1f3-4b38-932a-ba5a660405d9

Catalogue record

Date deposited: 22 Oct 2025 16:55
Last modified: 22 Oct 2025 16:55

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Contributors

Author: Preeti Singh
Author: Vijay Mudgal
Author: Sourav Khanna
Author: Tapas K. Mallick
Author: K. S. Reddy

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