Article ID Journal Published Year Pages File Type
647590 Applied Thermal Engineering 2011 7 Pages PDF
Abstract

A novel low-concentrating solar photovoltaic/thermal integrated heat pump system (LCPV/T-HP) with both electricity and heat outputs has been developed. A solar photovoltaic/thermal collector with fixed truncated parabolic concentrators reflecting the incident sunlight onto the surface of PV cells also as the evaporator of the heat pump system. Refrigerant, R134a, flows inside the multi-port flat extruded aluminum tubes placed underneath the PV cells, absorbing solar heat and evaporating. Refrigerant’s condensing heat is used to heat water in condenser. Experiments on the novel LCPV/T-HP system were carried out in Nanjing, China, and its operating characteristics evaluated using an LCPV system without being cooled as a benchmark. Experimental results showed that the LCPV/T-HP system achieved an averaged COP of 4.8 for heating water from 30 °C to 70 °C on a sunny summer day, with an output electrical efficiency of 17.5%, 1.36 times higher than that of the LCPV system. Furthermore, the experimental results suggested that flux concentrating rate of the fixed parabolic concentrators was 1.6. Finally, the influences of PV cells’ operating temperature on the photovoltaic output characteristics were analyzed, and an optimized control method to achieve a higher power output and electrical efficiency was further discussed.

► A novel solar LCPV/T-HP system with electricity and heat outputs was experimented. ► Flux concentrating rate of the fixed parabolic concentrators was 1.6. ► Averaged COP for heating water from 30 °C to 70 °C was 4.8 on a sunny summer day. ► PV cells can maintain operating at a lower temperature. ► Output electrical efficiency was 1.36 times that of LCPV without being cooled.

Related Topics
Physical Sciences and Engineering Chemical Engineering Fluid Flow and Transfer Processes
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