Journal
ENERGY
Volume 253, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.energy.2022.124126
Keywords
Concentrating photovoltaic; Heat exchanger; Numerical analysis; Pump consumption; Electrical exergy efficiency
Categories
Funding
- National Natural Science Foundation of China [NSFC 52106268]
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This study comparatively studied CPV systems with air cooling, water cooling, and heat pipe cooling methods and conducted outdoor experiments. The results showed that the CPV cell with heat pipe cooling method had the highest output power. Additionally, a thermal-electrical coupling model was established to provide guidance for the design and application of practical CPV cooling systems.
Concentrating photovoltaic technology has been one of the important technologies among renewable energy technologies. Researchers have used one or more cooling methods to increase the output power by cooling the CPV cells. In this work, CPV systems with three typical cooling methods of air cooling, water cooling and heat pipe cooling have been comparatively studied. An Outdoor experiment was conducted under the same environmental conditions. The pump power loss factor was considered to evaluate the thermal and electrical performance of the three systems. The experimental results indicate that the average temperatures of the finned heatsink, water cooling module, and heat pipe during the test are 41 degrees C, 25.9 degrees C and 22.2 degrees C, respectively. The CPV cell with heat pipe cooling method exhibits the highest output power of 8.27 W. When the pump consumption is considered, the water-cooled CPV cell can provide the highest net electrical efficiency of 28.3% and electrical exergy efficiency of 30.4%. In addition, a thermal-electrical coupling model was established to investigate the effects of different parameters, such as inlet fluid temperature, mass flow rate and concentration ratio on CPV system. The results can provide some practical guidelines for the design and application of practical CPV cooling systems. (C) 2022 Published by Elsevier Ltd.
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