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Tytuł artykułu

Experimental Study of Temperature Influence on the Performance of PV/T Cell under Jordan Climate Conditions

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The electrical performance and the productivity of PV module depend on two main parameters, i.e. the radiation intensity and the cell operating temperature. The module electrical efficiency and productivity are significantly reduced as its temperature increases. Accordingly, cooling of PV modules is one of the most effective techniques to obtain higher efficiency and productivity as well as to reduce the degradation modes of PV modules due to high temperatures. This research work presents an experimental study carried out to investigate the effect of PV module cooling on the performance of PV module under Irbid city (Jordan) climate conditions. It was found that the electrical efficiency and the productivity of the PV modules were approximately enhanced by 14%. Therefore, water cooling of the PV modules is essential to enhance their performance.
Rocznik
Strony
80--88
Opis fizyczny
Bibliogr. 27 poz., rys., tab.
Twórcy
  • Mechanical Engineering Department, Al-Huson University College, Al-Balqa’ Applied University, Irbid Al-Huson, Jordan
Bibliografia
  • 1. Ale T.O., Rotipin K.J. 2019. Cooling effects on photovoltaic module performance in the tropical region. Nigerian Journal of Technology, 38(3), 702–706.
  • 2. Khalil A., Abdelgaied M., Hamdy M. 2019. Performance improvement of PV panel using watercooling technology under Egyptian conditions. Engineering Research Journal, 242–247.
  • 3. Salem M.., Mohamed A., Maghrabie H.M. 2018. Performance evaluation of combined photovoltaic thermal water cooling system for hot climate regions. Journal of Solar Energy Engineering, 141(4).
  • 4. Anbarasan I., Sentilkumar P., Sivakumar R., Madhusudhan V. 2019. Improving the efficiency of solar panel by water cooling technique. International Journal of Scientific Research and Review, 7( 10), 191–204.
  • 5. Barbu, M., Darie G., Sirou M. 2019. Analysis of a residential photovoltaic-thermal (PVT) system in two similar climate conditions. Energies, 12, 3595.
  • 6. Dash P.K., Gupta N.C. 2015. Effect of temperature on power output from different commercially available photovoltaic modules. Int. Journal of Engineering Research and Applications, 5(1), 148–151.
  • 7. Dattatray D., Rajesh S. 2018. Experimental analysis of solar PV panel cooling by using back water tube array to improve efficiency. International Journal of Engineering Research & Technology (IJERT), 7( 2), 45–48.
  • 8. Colţ G. 2016. Performance evaluation of a PV panel by rear surface water active cooling. International Conference on Applied and Theoretical Electricity’ 2016, 1–5.
  • 9. Hachicha A.A., Ghenai C., Hamid A.K. 2015. Enhancing the performance of a photovoltaic module using different cooling methods. International Journal of Energy and Power Engineering, 9(9), 1106–1109.
  • 10. Hosseini R., Hosseini N., Khorasanizadeh H. 2011. An experimental study of combining a photovoltaic system with a heating system. World Renewable Congress, 2993–3000.
  • 11. Hussien H.A., Numan A.H., Abdulmunem R.A. 2015. Improving of the photovoltaic / thermal system performance using water cooling technique. IOP Conf. Ser.: Mater. Sci. Eng. 78.
  • 12. Indugowda C.S., Ranjith P. 2016. Cooling methods for increasing efficiency of PV panel. IJSDR, 1(6), 359–362.
  • 13. Iqbal S., Afzal S., Mazhar A.U., Anjumd H., Diyyan A. 2016. Effect of water cooling on the energy conversion efficiency of PV cell. American Scientific Research Journal for Engineering, Technology, and Sciences, 20(1), 122–128.
  • 14. Lubon W., Pełka G., Janowski M., Pająk L., Stefaniuk M., Kotyza J., Reczek P. 2020. Assessing the impact of water cooling on PV modules efficiency. Energies, 13(10), 1–13.
  • 15. Milind N., Antony M., Francis F., Francis J., Varghese J., Sajith U. 2017. Enhancing the efficiency of solar panel using cooling systems. Int. Journal of Engineering Research and Application, 7(3(4)), 5–7.
  • 16. Moharram K.A., Abd-Elhady M.S., Kandil H.A., El-Sherif H. 2013. Enhancing the performance of photovoltaic panels by water cooling. Ain Shams Engineering Journal, 4(4), 869–877.
  • 17. Musthafa M.M. 2015. Enhancing photoelectric conversion efficiency of solar panel by water cooling. Journal of Fundamentals of Renewable Energy and Applications, 5(4), 166.
  • 18. Odeh S., Behnia M. 2010. Improving photovoltaic module efficiency using water cooling. Heat Transfer Engineering, 30(6), 499–505.
  • 19. Peng Z., Herfatmanes M.R., Liu Y. 2017. Cooled solar PV panels for output energy efficiency optimization. Energy Conversion and Management, 150(15), 949–955.
  • 20. Prajapati S., Fernande E., Saxena R. 2017. Experimental investigations on the performance of PV modules with/without module cooling. IJRECE, 5 (4). 92–96.
  • 21. Reteri A., Saib H., Chib Z. 2018. Experimental study of temperature influence on the electrical performance of polycrystalline photovoltaic cell. Mechanics and Mechanical Engineering, 22(4), 1111–1119.
  • 22. Shah J., Chowdhary A., Patel D., Thakker D., Talaviya U., Shah P. 2022. Cooling techniques of solar photovoltaic panels: A critical review. International Journal of Engineering Research & Technology, 11(1), 449–460.
  • 23. Shalaby S.M., Elfakharany M.K., Moharram B.M., Abosheiash H.F. 2022. Experimental study on the performance of PV with water cooling. Energy Reports, 8, 957–961.
  • 24. Tiwari M.K., Mishra V., Manik M.K. 2022. Increase the efficiency of solar panel by surface cooling – A review. International Journal of Creative Research Thoughts, 10(1), 57–69.
  • 25. Verma S., Mohapatra S., Chowdhury S., Dwived G. 2021. Cooling techniques of the PV module: A review. Materials Today: Proceedings, 38, 253–258.
  • 26. Yildirim M.A., Cebula A., Sułowic M. 2022. A cooling design for photovoltaic panels water-based PV/T system. Energy, 256(1), 124654.
  • 27. Zondag H.A.,. Vries D.W.D.E., Van Helden W.G.J., Van Zolingen R.J.C., Van Steenhoven, A.A. 2002. The thermal and electrical yield of a PV-thermal collector, Solar Energy, 72, 113–128.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-7b386b78-3c00-4692-b083-522bb852904a
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