Outdoor test of a hybrid jet impingement/micro-channel cooling device for densely packed concentrated photovoltaic cells

•A hybrid jet impingement/microchannel cooling device is designed for CPV receivers.•The device is tested under real sun in outdoor conditions.•Local thermal resistance vary between 6 and 7.6×10−5Km2/W.•Nearly uniform temperature on the receiver surface is obtained.•The cooling scheme design can be...

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Bibliographic Details
Published in:Solar energy 2014-09, Vol.107, p.113-121
Main Authors: Barrau, J., Perona, A., Dollet, A., Rosell, J.
Format: Article
Language:English
Subjects:
Applied sciences
Concentrated photovoltaic systems
Cooling device
Direct energy conversion and energy accumulation
Electrical engineering. Electrical power engineering
Electrical power engineering
Energy
Engineering Sciences
Equipments, installations and applications
Exact sciences and technology
Jet impingement
Micro-channel
Natural energy
Photoelectric conversion
Photovoltaic cells
Photovoltaic conversion
Reliability
Solar cells. Photoelectrochemical cells
Solar energy
Temperature distribution
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Summary:•A hybrid jet impingement/microchannel cooling device is designed for CPV receivers.•The device is tested under real sun in outdoor conditions.•Local thermal resistance vary between 6 and 7.6×10−5Km2/W.•Nearly uniform temperature on the receiver surface is obtained.•The cooling scheme design can be tailored to the irradiation profile. Densely packed concentrated photovoltaic (CPV) receivers require efficient active cooling in order to maintain the photovoltaic cells within their nominal operating temperature range. The cooling device must have low thermal resistance coefficients and also provide good cell temperature uniformity in order to maximize the efficiency and the reliability of the whole system. A hybrid jet impingement/microchannel cooling device designed for CPV receivers is experimentally tested under real sun in outdoor conditions. The measurements include the irradiation profile at the outlet of the secondary optics and the temperature distribution of the receiver. The experimental results show that the thermal resistance coefficient and the temperature uniformity provided by the cooling device met the requirements for CPV receivers. This work also emphasizes that the internal geometry of the cooling device must be tailored, at the design stage, to the irradiation profile provided by the optics, which is generally nonperfectly uniform in CPV systems based on densely packed receivers. The impact of the solar concentration ratio and flow rate on the electrical output of the receiver is also assessed.
ISSN:0038-092X
0165-1633
1471-1257
DOI:10.1016/j.solener.2014.05.040