TY - JOUR
T1 - A Review of Heat Batteries Based PV Module Cooling—Case Studies on Performance Enhancement of Large-Scale Solar PV System
AU - Velmurugan, Karthikeyan
AU - Elavarasan, Rajvikram Madurai
AU - Van De, Pham
AU - Karthikeyan, Vaithinathan
AU - Korukonda, Tulja Bhavani
AU - Dhanraj, Joshuva Arockia
AU - Emsaeng, Kanchanok
AU - Chowdhury, Md Shahariar
AU - Techato, Kuaanan
AU - El Khier, Bothaina Samih Abou
AU - Attia, El Awady
N1 - Publisher Copyright:
© 2022 by the authors. Licensee MDPI, Basel, Switzerland.
PY - 2022/2/1
Y1 - 2022/2/1
N2 - Several studies have concentrated on cooling the PV module temperature (TPV) to enhance the system’s electrical output power and efficiency in recent years. In this review study, PCM-based cooling techniques are reviewed majorly classified into three techniques: (i) incorporating raw/pure PCM behind the PV module is one of the most straightforward techniques; (ii) thermal additives such as inter-fin, nano-compound, expanded graphite (EG), and others are infused in PCM to enhance the heat transfer rate between PV module and PCM; and (iii) thermal collectors that are placed behind the PV module or inside the PCM container to minimize the PCM usage. Advantageously, these techniques favor reusing the waste heat from the PV module. Further, in this study, PCM thermophysical properties are straightforwardly discussed. It is found that the PCM melting temperature (Tmelt) and thermal conductivity (KPCM) become the major concerns in cooling the PV module. Based on the literature review, experimentally proven PV-PCM temperatures are analyzed over a year for UAE and Islamabad locations using typical meteorological year (TMY) data from the National Renewable Energy Laboratory (NREL) data source in 1 h frequency.
AB - Several studies have concentrated on cooling the PV module temperature (TPV) to enhance the system’s electrical output power and efficiency in recent years. In this review study, PCM-based cooling techniques are reviewed majorly classified into three techniques: (i) incorporating raw/pure PCM behind the PV module is one of the most straightforward techniques; (ii) thermal additives such as inter-fin, nano-compound, expanded graphite (EG), and others are infused in PCM to enhance the heat transfer rate between PV module and PCM; and (iii) thermal collectors that are placed behind the PV module or inside the PCM container to minimize the PCM usage. Advantageously, these techniques favor reusing the waste heat from the PV module. Further, in this study, PCM thermophysical properties are straightforwardly discussed. It is found that the PCM melting temperature (Tmelt) and thermal conductivity (KPCM) become the major concerns in cooling the PV module. Based on the literature review, experimentally proven PV-PCM temperatures are analyzed over a year for UAE and Islamabad locations using typical meteorological year (TMY) data from the National Renewable Energy Laboratory (NREL) data source in 1 h frequency.
KW - Composite PCM (heat battery)
KW - Heat battery
KW - PR improvement
KW - PV module cooling
KW - Power enhancement
KW - Thermal collector
KW - Thermal conduction barrier
UR - https://www.scopus.com/pages/publications/85124548561
U2 - 10.3390/su14041963
DO - 10.3390/su14041963
M3 - Review article
AN - SCOPUS:85124548561
VL - 14
JO - Sustainability (Switzerland)
JF - Sustainability (Switzerland)
IS - 4
M1 - 1963
ER -
