International Journal of Renewable Energy Research-IJRER

In order to obtain a high current efficiency a photovoltaic generator PV, it has been necessary to recuperate the heat dissipated by combination a PV to a thermal heating system. The heat exchanger is under the PV, thus cooling the cells back face. Such a system therefore improves the efficiency of the PV module while extracting useful heat calories heating. In this paper, a 3D model of a new PVT collector has been implemented using the Comsol environment. A (FEM) approach is used for the analysis of the thermal and electrical behavior of new absorber integrated for the PVT collector which has as an advantage of a simple realization and to use a material of galvanised steel for it low cost  compared to other configurations of PV/T hybrid collectors. Some results are presented the temperature of the PVT collector decreases with the increasing flow rate, For a flow rate of about 0.0016 kg/s and irradiation of 1000W/m² and ambient temperature equal to 20.15 °C, the temperature reaches a value equal to 55.96°C. The influence of mass flow rate in the PVT collector demonstrate that the PV cell temperature decreases with the increasing mass flow rate and the increases  until the flow rate reaches about 0.0256 m/s; it reaches a value equal to 23.845 °C and electrical power equal to 59.434 after these values will be maintained at a relatively constants values.

PV module; photovoltaic; Photovoltaic-thermal PVT; finite element method; COMSOL

Kalogirou, S.A., Tripanagnostopoulos, Y.: ‘Hybrid PV/T solar systems for domestic hot water and electricity production’, Energy Convers. Manage, 2006, 47, pp. 3368–3382.

Agrawal, S., Tiwari, G.N.: ‘Energy and exergy analysis of hybrid microchannel photovoltaic thermal module’, Sol. Energy, 2011, 85, pp. 356–370.

Agrawal, S., Tiwari, G.N.: ‘Overall energy, exergy and carbon credit analysis by different type of hybrid photovoltaic thermal air collectors’, Energy Convers. Manage, 2013, 65, pp. 628–636.

A. Kumar and al. Historical and recent development of photovoltaic thermal (PVT) technologies. Renewable and Sustainable Energy Reviews 42 (2015) 1428–1436.

Chow TT. A review on photovoltaic thermal hybrid solar technology. Appl Energy 2010;87:365–79

PV Catapult, EU 6th Framework. PV/T Roadmap. EU 6th Framework Programme. 2006.

Kalogirou, S.A. Photovoltaic thermal (PV/T) collectors: A review: Elsevier, 2006.

Ibrahim A, Fudholi A, Sopian K, Othman MY, Ruslan MH. Efficiencies and improvement potential of building integrated photovoltaic thermal (BIPVT) system. Energy Convers Manage 2014;77:527–34.

Touafek K, Mourad H, Malek A. Design and modeling of a photovoltaic thermal collector for domestic air heating and electricity production. Energy Build 2013; 59:21–8.

Li G, Pei G, Yang M, Ji J, Su Y. Optical evaluation of a novel static incorporated compound parabolic concentrator with photovoltaic/thermal system and preliminary experiment. Energy Convers Manage 2014; 85:204–11.

Huang BJ. Performance rating method of thermosyphon solar water heaters. Sol Energy 1993; 50:435–40.

Sopian KS, Yigit HT, Liu HT, Kakac S, Veziroglu TN. Performance analysis of photovoltaic thermal air heaters. Energy Convers Manage 1996; 37:1657–70.

Kalogirou SA. Use of TRYNSYS for modeling and simulation of a hybrid PV–thermal solar system for Cyprus. Renewable Energy 2001; 23:247–60.

Sandnes B, Rekstad J. A photovoltaic thermal (PVT) collector with a polymer absorber plate: experimental study and analytic model. Sol Energy2002; 72:63–73.

Tiwari A, Sodha MS. Performance evaluation of solar PVT system: an experimental validation. Sol Energy 2006; 80:751–9.

Duffie and Beckman, Solar Engineering of Thermal Processes, 2nd Ed. New York: Wiley, 1991.

H. Ben Cheikh el Hocine, K. Touafek, F. Kerrour « The development of empirical photovoltaic/Thermal collector », The Second International Conference on Electrical Engineering and Control Applications ICEECA’2014, Constantine, Algeria.

Florschuetz LW, on heat rejection from terrestrial solar cell arrays with sunlight concentration, IEEE Photovolt Spec Conf Rec Mater 1975:318–26.