Hanfeng He scite author profile

SUMMARYThe performance of photovoltaic/thermal (PV/T) solar collector had been studied theoretically and experimentally for some years. Air and water streams were used as the heat carriers for space heating or services hot water systems. The cooling effect allows the PV module to work at lower temperature and its PV efficiency is therefore improved. However, such an advantage diminishes when the solar irradiance is high. To improve the situation a new type of PV/T collector is proposed. It works as the evaporator of a heat pump, in that refrigerant evaporates in the tubing at the back of the flat-plate collector and the PV module is adhered to the front surface. Mathematical models were developed to simulate the complex energy conversion processes. Numerical analysis was then performed based on the distributed parameters approach. An experimental rig was also built to test its real performance. Our results showed that the PV/T evaporator had an overall efficiency in the range of 0.64-0.87, thermal efficiency 0.53-0.64 and PV efficiency 0.124-0.135. The simulation results were found in good agreement with the experiment measurements.

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Performance of the photovoltaic solar-assisted heat pump system with and without glass cover in winter: A comparative analysis

Pei

Chow

et al. 2008

Proceedings of the Institution of Mechanical Engineers, Part A:

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An application of photovoltaic/thermal (PV/T) technology in heat pump, known as the PV solar-assisted heat pump (PV-SAHP) system, is presented. Comparative performance tests were conducted through an experimental rig under two different working conditions of the PV/T collectors: with and without glass cover. The energy performance in terms of PV/ photothermic conversions and refrigeration cycle was compared in typical winter days of the temperate climate zone in China. It was found that with a single glass cover, the exergy efficiencies of PV/photothermic conversions and overall PV/T conversion were, respectively, 12.83, 5.26, and 18.09 per cent, and the heat pump coefficient of performance (COP) was 4.85. Without the glass cover, the exergy efficiencies and COP were 13.36, 3.04, and 16.40 per cent, and 3.41, respectively. The results imply that although the presence of the glass cover leads to a small reduction in the PV exergy efficiency, it is able to improve considerably the photothermic exergy efficiency, the overall PV/T exergy efficiency, and the COP of the PV-SAHP system in winter.

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Hanfeng He

Distributed dynamic modeling and experimental study of PV evaporator in a PV/T solar-assisted heat pump

Experimental study of photovoltaic solar assisted heat pump system

Performance analysis of a photovoltaic heat pump

Thermal analysis of PV/T evaporator of a solar-assisted heat pump

Performance of the photovoltaic solar-assisted heat pump system with and without glass cover in winter: A comparative analysis

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