Field study of various air based photovoltaic/thermal hybrid solar collectors
In the present work a comparative study for thermal and electrical performance of different hybrid photovoltaic/thermal collectors designs for Iraq climate conditions have been carried out. Four different types of air based hybrid PV/T collectors have been manufactured and tested. Three collectors c...
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| Vydáno v: | Renewable energy Ročník 63; s. 402 - 414 |
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| Hlavní autoři: | , |
| Médium: | Journal Article |
| Jazyk: | angličtina |
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Oxford
Elsevier Ltd
01.03.2014
Elsevier |
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| ISSN: | 0960-1481, 1879-0682 |
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| Abstract | In the present work a comparative study for thermal and electrical performance of different hybrid photovoltaic/thermal collectors designs for Iraq climate conditions have been carried out. Four different types of air based hybrid PV/T collectors have been manufactured and tested. Three collectors consist of four main parts namely, channel duct, glass cover, axial fan to circulate air and two PV panels in parallel connection. The measured parameters are, the temperature of the upper and the lower surfaces of the PV panels, air temperature along the collector, air flow rate, pressure drop, power produced by solar cell, and climate conditions such as wind speed, solar radiation and ambient temperature. The thermal and hydraulic performances of PV/T collector model IV have been analyzed theoretically based on energy balance. A Matlab computer program has been developed to solve the proposed mathematical model.
The obtained results show that the combined efficiency of collector model III (double duct, single pass) is higher than that of model II (single duct double pass) and model IV (single duct single pass). Model IV has the better electrical efficiency. The pressure drop of model III is lower than that of models II and IV. The root mean square of percentage deviations for PV outlet temperature, and thermal efficiency of model IV are found to be 3.22%, and 18.04% respectively. The calculated linear coefficients of correlation (r) are 0.977, 0.965 respectively.
•Different (PV/T) hybrid solar collectors were designed manufactured and outdoor tested in Iraq.•A theoretical model was developed to predict the performance of one of these models.•The overall thermal–electrical conversion performance has been evaluated.•A detailed parametric investigation has been carried out. |
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| AbstractList | In the present work a comparative study for thermal and electrical performance of different hybrid photovoltaic/thermal collectors designs for Iraq climate conditions have been carried out. Four different types of air based hybrid PV/T collectors have been manufactured and tested. Three collectors consist of four main parts namely, channel duct, glass cover, axial fan to circulate air and two PV panels in parallel connection. The measured parameters are, the temperature of the upper and the lower surfaces of the PV panels, air temperature along the collector, air flow rate, pressure drop, power produced by solar cell, and climate conditions such as wind speed, solar radiation and ambient temperature. The thermal and hydraulic performances of PV/T collector model IV have been analyzed theoretically based on energy balance. A Matlab computer program has been developed to solve the proposed mathematical model.
The obtained results show that the combined efficiency of collector model III (double duct, single pass) is higher than that of model II (single duct double pass) and model IV (single duct single pass). Model IV has the better electrical efficiency. The pressure drop of model III is lower than that of models II and IV. The root mean square of percentage deviations for PV outlet temperature, and thermal efficiency of model IV are found to be 3.22%, and 18.04% respectively. The calculated linear coefficients of correlation (r) are 0.977, 0.965 respectively.
•Different (PV/T) hybrid solar collectors were designed manufactured and outdoor tested in Iraq.•A theoretical model was developed to predict the performance of one of these models.•The overall thermal–electrical conversion performance has been evaluated.•A detailed parametric investigation has been carried out. In the present work a comparative study for thermal and electrical performance of different hybrid photovoltaic/thermal collectors designs for Iraq climate conditions have been carried out. Four different types of air based hybrid PV/T collectors have been manufactured and tested. Three collectors consist of four main parts namely, channel duct, glass cover, axial fan to circulate air and two PV panels in parallel connection. The measured parameters are, the temperature of the upper and the lower surfaces of the PV panels, air temperature along the collector, air flow rate, pressure drop, power produced by solar cell, and climate conditions such as wind speed, solar radiation and ambient temperature. The thermal and hydraulic performances of PV/T collector model IV have been analyzed theoretically based on energy balance. A Matlab computer program has been developed to solve the proposed mathematical model.The obtained results show that the combined efficiency of collector model III (double duct, single pass) is higher than that of model II (single duct double pass) and model IV (single duct single pass). Model IV has the better electrical efficiency. The pressure drop of model III is lower than that of models II and IV. The root mean square of percentage deviations for PV outlet temperature, and thermal efficiency of model IV are found to be 3.22%, and 18.04% respectively. The calculated linear coefficients of correlation (r) are 0.977, 0.965 respectively. In the present work a comparative study for thermal and electrical performance of different hybrid photovoltaic/thermal collectors designs for Iraq climate conditions have been carried out. Four different types of air based hybrid PV/T collectors have been manufactured and tested. Three collectors consist of four main parts namely, channel duct, glass cover, axial fan to circulate air and two PV panels in parallel connection. The measured parameters are, the temperature of the upper and the lower surfaces of the PV panels, air temperature along the collector, air flow rate, pressure drop, power produced by solar cell, and climate conditions such as wind speed, solar radiation and ambient temperature. The thermal and hydraulic performances of PV/T collector model IV have been analyzed theoretically based on energy balance. A Matlab computer program has been developed to solve the proposed mathematical model. |
| Author | Amori, Karima E. Abd-AlRaheem, Mustafa Adil |
| Author_xml | – sequence: 1 givenname: Karima E. surname: Amori fullname: Amori, Karima E. email: drkarimaa@yahoo.com – sequence: 2 givenname: Mustafa Adil surname: Abd-AlRaheem fullname: Abd-AlRaheem, Mustafa Adil |
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| Keywords | Hybrid collector Electrical Solar Performance PV/T Thermal Solar collector Renewable energy Solar energy Photovoltaic system Electric power production Photovoltaic cell |
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publication-title: Appl Therm Eng doi: 10.1016/j.applthermaleng.2011.02.019 |
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| SubjectTerms | Accumulators air air flow air temperature ambient temperature Applied sciences Climate Collectors computer software Electrical Energy energy balance Equipments, installations and applications Exact sciences and technology glass Hybrid collector Iraq Mathematical models Matlab Natural energy Panels Photovoltaic cells Photovoltaic conversion PV/T renewable energy sources Solar Solar cells Solar collectors Solar energy solar radiation Solar thermal conversion Thermal wind speed |
| Title | Field study of various air based photovoltaic/thermal hybrid solar collectors |
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