TY - JOUR
T1 - Design and testing of concentrated photovoltaic arrays for retrofitting of solar thermal parabolic trough collectors
AU - Felsberger, Richard
AU - Buchroithner, Armin
AU - Gerl, Bernhard
AU - Schweighofer, Bernhard
AU - Wegleiter, Hannes
PY - 2021/10/15
Y1 - 2021/10/15
N2 - A new design and retrofit approach for a concentrated photovoltaic thermal (CPV-T) system based on a parabolic trough collector is presented. The design differs from previous hybrid architectures, employing a significantly simplified topology in order to reduce costs while keeping electrical efficiency high. To achieve this ambitious goal, the absorber tube of a conventional parabolic trough collector used in thermal systems is replaced by a newly developed hybrid absorber equipped with multi-junction solar cells. This offers the advantage that existing solar thermal parabolic trough facilities can be easily retrofitted, making the system scalable and cost-effective. A scaled prototype of the system was designed and tested in Graz, Austria. During on-sun tests an average electrical system efficiency of 26.8 % with a simultaneous thermal efficiency of 48.8 % was measured using a geometric concentration ratio of 150 (DNI based). This leads to an overall average system efficiency of 75.5 %. Moreover, a solar cell peak efficiency of 30 % was achieved, one of the highest measured solar-to-DC efficiencies for a parabolic trough-based solar collector. Special attention was paid to the temperature difference between the solar cells and the heat transfer fluid in order to ensure sufficient cooling of the cells and maximize thermal efficiency. The electrical, thermal and overall efficiencies at different heat transfer fluid temperatures were measured (17 C - 90 C) and their coefficients were derived. This work serves as an experimental proof-of-concept for the application of solar cells in parabolic trough collectors, thereby opening up new possibilities for cost reduction of CPV-T systems.
AB - A new design and retrofit approach for a concentrated photovoltaic thermal (CPV-T) system based on a parabolic trough collector is presented. The design differs from previous hybrid architectures, employing a significantly simplified topology in order to reduce costs while keeping electrical efficiency high. To achieve this ambitious goal, the absorber tube of a conventional parabolic trough collector used in thermal systems is replaced by a newly developed hybrid absorber equipped with multi-junction solar cells. This offers the advantage that existing solar thermal parabolic trough facilities can be easily retrofitted, making the system scalable and cost-effective. A scaled prototype of the system was designed and tested in Graz, Austria. During on-sun tests an average electrical system efficiency of 26.8 % with a simultaneous thermal efficiency of 48.8 % was measured using a geometric concentration ratio of 150 (DNI based). This leads to an overall average system efficiency of 75.5 %. Moreover, a solar cell peak efficiency of 30 % was achieved, one of the highest measured solar-to-DC efficiencies for a parabolic trough-based solar collector. Special attention was paid to the temperature difference between the solar cells and the heat transfer fluid in order to ensure sufficient cooling of the cells and maximize thermal efficiency. The electrical, thermal and overall efficiencies at different heat transfer fluid temperatures were measured (17 C - 90 C) and their coefficients were derived. This work serves as an experimental proof-of-concept for the application of solar cells in parabolic trough collectors, thereby opening up new possibilities for cost reduction of CPV-T systems.
KW - Solar energy
KW - Concentrated photovoltaic thermal system (CPV-T)
KW - Concentrated photovoltaic (CPV)
KW - Parabolic trough
KW - Concentrated solar power (CSP)
KW - Hybrid absorber
KW - Multi-junction cell
UR - http://www.scopus.com/inward/record.url?scp=85110299903&partnerID=8YFLogxK
U2 - 10.1016/j.apenergy.2021.117427
DO - 10.1016/j.apenergy.2021.117427
M3 - Article
SN - 0306-2619
VL - 300
JO - Applied Energy
JF - Applied Energy
M1 - 117427
ER -