Energy Conversion and Management, Vol.106, 1201-1211, 2015
Thermal performances of ETFE cushion roof integrated amorphous silicon photovoltaic
Thermal performances of the ETFE cushion roof integrated amorphous silicon photovoltaic (a-Si PV) are essential to estimate building performances, such as temperature distribution and heat transfer coefficient. To investigate these thermal performances, an experimental mock-up composed of a-Si PV and a three-layer ETFE cushion roof was built and the experiment was carried out under summer sunny condition. Meanwhile, numerical model with real boundary conditions was performed in this paper. The experimental results show that the temperature sequence of the three layers was the middle, top and bottom layer and that the PV temperature caused by solar irradiance was 353.8 K. This gives evidence that the PV has a significant effect on the temperature distribution. The experimental temperature was in good agreement with the corresponding location of the numerical temperature since the maximum temperature difference was only 3.4 K. Therefore, the numerical results were justified and then used to analyze the airflow characteristics and calculate the thermal performances. For the airflow characteristics, it is found that the temperature distribution was not uniform and the main transport mechanisms in the upper and lower chambers formed by the three layers were the convection and conduction, respectively. For the thermal performances, the surface convective heat transfer coefficients were obtained, which have validated that thermal performances of the three-layer ETFE cushion integrated a-Si PV are better than those of conventional ETFE cushion roofs. This study provides a basic understanding of thermal performances, such as the temperature field and heat transfer coefficient; it is useful for calculation and analysis of ETFE cushion roof integrated a-Si PV. (C) 2015 Elsevier Ltd. All rights reserved.
Keywords:Amorphous silicon photovoltaic;ETFE cushion;Heat transfer coefficient;Solar energy;Temperature distribution;Thermal performance