Experimental study on cooling performance of solar cells with atmospheric plate thermosyphon

•Atmospheric plate thermosyphon (APT) cooling solar cells was first proposed.•APT can reduce the temperature of PV panels without parasitic energy consumption.•The maximum temperature difference was less than 6 °C.•The heat transfer resistance at the evaporator is between 0.00486 and 0.02368 K/W. Si...

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Bibliographic Details
Published inEnergy conversion and management Vol. 178; pp. 226 - 234
Main Authors Wang, Yiping, Hu, Guohao, Cui, Yong, Huang, Qunwu
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 15.12.2018
Elsevier Science Ltd
Subjects
Atmospheric plate thermosyphon
Cooling
Cooling systems
Energy consumption
Ethanol
Evaporators
Flux density
Heat
Heat flux
Heat pipes
Heat transfer
Heat transfer performance
Inlet temperature
Non-condensable gas
Parasitic energy
Photovoltaic cells
Photovoltaics
Porous media
Solar cells
Temperature effects
Temperature gradients
Thermal resistance
Thermosyphons
Parasitic energy
Heat transfer performance
Non-condensable gas
Atmospheric plate thermosyphon
Photovoltaics
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Summary:•Atmospheric plate thermosyphon (APT) cooling solar cells was first proposed.•APT can reduce the temperature of PV panels without parasitic energy consumption.•The maximum temperature difference was less than 6 °C.•The heat transfer resistance at the evaporator is between 0.00486 and 0.02368 K/W. Since the heat pipe has no parasitic energy consumption, it is an important method for cooling the photovoltaic. In this paper, a novel type of atmospheric plate thermosyphon (APT) cooling system has been designed, which can be used for the heat dissipation of the single or low concentrated solar cells. In the experiments, the non-condensable gas (NCG) was collected by a gas reservoir. The coolant, ethanol, formed a liquid film on the porous medium and directly cooled the photovoltaic panel. The effect of various parameters such as heat flux density, tilt angle and inlet temperature have been studied. The results demonstrated that APT cooling system could effectively reduce the temperature of PV cells, and the higher heat flux density was, the shorter start-up time. The temperature of evaporator was uniform, and the larger inclined angle was, the greater surface temperature difference which maximumly was 5.6 °C. The thermal resistance at the evaporator was between 0.00486 and 0.02368 K/W.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2018.10.039