Numerical study on optical and electric-thermal performance for solar concentrating PV/T air system 被引量：5

Numerical study on optical and electric-thermal performance for solar concentrating PV/T air system

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摘要 Hybrid photovoltaic/thermal(PV/T)system with solar concentrator is an effective way to improve solar energy conversion efficiency.In this work,a single-pass PV/T air system with a three-trough compound parabolic concentrator(CPC)of concentration ratio 2.0 is designed and the solar incident distributions at the solar cell surface are calculated by ray tracing method.Based on energy balance,the heat transfer models of all main components in this system are developed.The effects of some main designing and operational parameters on the electric-thermal performance of the system are analyzed. The results show that the solar radiation intensity can be higher than 1200 W/m 2 at most area of the cell surface.The temperature of the air and cell surface increases along the length of the system.Thus the system efficiency of the CPC is higher than that of the system without the CPC.The thermal efficiency, exergy and electrical efficiency of this CPC system increase with increasing of the air mass flow rate and the length of the system.With increasing packing fraction the electrical efficiency increases,but the thermal efficiency decreases.The exergy efficiency increases slightly with the packing fraction rising.The data obtained in this work are valuable for the design and operation for this kind of solar concentrating PV/T systems. Hybrid photovoltaic/thermal (PV/T) system with solar concentrator is an effective way to improve solar energy conversion efficiency. In this work, a single-pass PV/T air system with a three-trough compound parabolic concentrator (CPC) of concentration ratio 2.0 is designed and the solar incident distributions at the solar cell surface are calculated by ray tracing method. Based on energy balance, the heat transfer models of all main components in this system are developed. The effects of some main designing and operational parameters on the electric-thermal performance of the system are analyzed. The results show that the solar radiation intensity can be higher than 1200 W/m2 at most area of the cell surface. The temperature of the air and cell surface increases along the length of the system. Thus the system efficiency of the CPC is higher than that of the system without the CPC. The thermal efficiency, exergy and electrical efficiency of this CPC system increase with increasing of the air mass flow rate and the length of the system. With increasing packing fraction the electrical efficiency increases, but the thermal efficiency decreases. The exergy efficiency increases slightly with the packing fraction rising. The data obtained in this work are valuable for the design and operation for this kind of solar concentrating PV/T systems.

作者 SUN Jian 1,2 &SHI MingHeng 1 1School of Energy and Environment,Southeast University,Nanjing 210096,China 2Department of Thermal Energy Engineering,Jingdezhen Ceramic Institute,Jingdezhen 333001,China

出处《Science China(Technological Sciences)》 SCIE EI CAS 2009年第12期3514-3520,共7页 中国科学（技术科学英文版）

基金 Supported by the National Natural Science Foundation of China(Grant No.50276013)

关键词 photovoltaic/thermal system CPC EXERGY efficiency THERMAL and ELECTRICITY performance OPTICAL photovoltaic/thermal system CPC exergy efficiency thermal and electricity performance optical

分类号 TK513 [动力工程及工程热物理—热能工程]

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