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Effect of Using Fins on Cell Temperature at Air-Based PVT

Year 2020, Volume: 10 Issue: 1, 477 - 488, 01.03.2020

Ahmet Numan Özakın Ferhat Kaya

https://doi.org/10.21597/jist.656173

Abstract

In this study, the effect of addition of fins in air-based PVT system on cell temperature investigated. Experimental tests were performed with frequent and sparse fins configurations and also empty(non-finned) state. Also, thermal camera images of cells were investigated and compared to images obtained by Fluent Ansys. Cell temperatures for all status of both polycrystal and monocrystal panel decreased between 8-20 °C. Panel surface was observed to have a uniform temperature distribution. Finally, temperature distribution images obtained with ANSYS Fluent were found to be quite compatible with thermal camera images.

Keywords

air-based PVT system copper fins Ansys Fluent cell temperature thermal camera

Supporting Institution

Atatürk University Scientific Research Project Unit

Project Number

BAP/2015-147

References

  • Al-Waeli AHA, Sopian K, Kazem HA, Chaichan MT, 2017. Photovoltaic/Thermal (PV/T) systems: Status and future prospects. Renewable and Sustainable Energy Reviews. 77: p. 109-130.
  • Bahaidarah HMS, Subhan, A, Gandhidasan P, Rehman S, 2013. Performance evaluation of a PV (photovoltaic) module by back surface water cooling for hot climatic conditions. Energy. 59: p. 445-453.
  • Bahaidarah HMS, Baloch AAB, Gandhidasan P, 2016. Uniform cooling of photovoltaic panels: A review. Renewable and Sustainable Energy Reviews. 57: p. 1520-1544.
  • Baloch AAB., Bahaidarah HMS., Gandhidasan P, Al-Sulaiman FA, 2015. Experimental and numerical performance analysis of a converging channel heat exchanger for PV cooling. Energy Conversion and Management. 103: p. 14-27.
  • Bayrak F, Hamdeh NA, Alnefaie KA, Öztop HF, 2017. A review on exergy analysis of solar electricity production. Renewable and Sustainable Energy Reviews, . 74: p. 755-770.
  • Bora B, Kumar R, Sastry OS, Prasad B, Mondal S, 2018. Energy rating estimation of PV module technologies for different climatic conditions. Solar Energy. 174: p. 901-911.
  • Ceylan, İ, Yilmaz S, İnanç Ö, Ergün A, Gürel AE, Acar B, 2019. Determination of the heat transfer coefficient of PV panels. Energy. 175: p. 978-985.
  • Chandel SS, Agarwal T, 2017. Review of cooling techniques using phase change materials for enhancing efficiency of photovoltaic power systems. Renewable & Sustainable Energy Reviews. 73: p. 1342-1351.
  • Chauhan A, Tyagi V, Anand S, 2018. Futuristic approach for thermal management in solar PV/thermal systems with possible applications. Energy Conversion and Management. 163: p. 314-354.
  • Cuce E, Cuce PM, Bali T, 2013. An experimental analysis of illumination intensity and temperature dependency of photovoltaic cell parameters. Applied Energy,. 111: p. 374-382.
  • Dubey S, Tay AAO, 2013. Testing of two different types of photovoltaic–thermal (PVT) modules with heat flow pattern under tropical climatic conditions. Energy for Sustainable Development. 17(1): p. 1-12.
  • Dubey S, Tiwari GN, 2008. Thermal modeling of a combined system of photovoltaic thermal (PV/T) solar water heater. Solar Energy. 82(7): p. 602-612.
  • Fayaz H, Rahim NA, Hasanuzzaman M, 2019. A Rivai Numerical and outdoor real time experimental investigation of performance of PCM based PVT system. Solar Energy. 179: p. 135-150.
  • Gang P, Huide F, Tao Z, Jie J. 2011. A numerical and experimental study on a heat pipe PV/T system. Solar Energy. 85(5): p. 911-921.
  • Ghosh S, Yadav, VK, Mukherjee V, 2019. Impact of environmental factors on photovoltaic performance and their mitigation strategies–A holistic review. Renewable Energy Focus. 28: p. 153-172.
  • Gökmen N, Hu W, Hou P, Chen Z, Sera D, Spataru S, 2016. Investigation of wind speed cooling effect on PV panels in windy locations. Renewable Energy. 90: p. 283-290.
  • Kaiser AS, Zamora B, Mazón R, García JR, Vera F, 2014. Experimental study of cooling BIPV modules by forced convection in the air channel. Applied Energy. 135: p. 88-97.
  • Kaldellis JK, M Kapsali, Kavadias KA, 2014. Temperature and wind speed impact on the efficiency of PV installations. Experience obtained from outdoor measurements in Greece. Renewable Energy. 66: p. 612-624.
  • Kalogirou SA, 2001. Use of TRNSYS for modelling and simulation of a hybrid pv–thermal solar system for Cyprus. Renewable Energy. 23(2): p. 247-260.
  • Kazemian A, Hosseinzadeh M, Sardarabadi M, 2018. Effect of glass cover and working fluid on the performance of photovoltaic thermal (PVT) system: An experimental study. Solar Energy. 173: p. 1002-1010.
  • Kumar, R. Rosen MA, 2011a. A critical review of photovoltaic–thermal solar collectors for air heating. Applied Energy. 88(11): p. 3603-3614.
  • Kumar R, Rosen MA, 2011b. Performance evaluation of a double pass PV/T solar air heater with and without fins. Applied Thermal Engineering. 31(8): p. 1402-1410.
  • Lamnatou C, Chemisana D, 2017. Photovoltaic/thermal (PVT) systems: A review with emphasis on environmental issues. Renewable Energy. 105: p. 270-287.
  • Omer KA, Zala AM, 2018. Experimental investigation of PV/thermal collector with theoretical analysis. Renewable Energy Focus. 27: p. 67-77.
  • Özakin AN, Kaya F, 2019. Effect on the exergy of the PVT system of fins added to an air-cooled channel: A study on temperature and air velocity with ANSYS Fluent. Solar Energy. 184: p. 561-569.
  • Özakin AN, Kaya F, 2020. Experimental thermodynamic analysis of air-based PVT system using fins in different materials: Optimization of control parameters by Taguchi method and ANOVA. Solar Energy. 197: p. 199-211.
  • Saidur R, Jazi GB, Mekhlif S, Jameel M, 2012.Exergy analysis of solar energy applications. Renewable and Sustainable Energy Reviews. 16(1): p. 350-356.
  • Shukla A, Kanta K, Sharmaa A, Biwole PH, 2017. Cooling methodologies of photovoltaic module for enhancing electrical efficiency: A review. Solar Energy Materials and Solar Cells. 160: p. 275-286.
  • Tonui JK, Tripanagnostopoulos Y, 2008. Performance improvement of PV/T solar collectors with natural air flow operation. Solar Energy. 82(1): p. 1-12.
  • Ustun TS, Nakamura Y, Hashimoto J, Otani K, 2019.Performance analysis of PV panels based on different technologies after two years of outdoor exposure in Fukushima, Japan. Renewable Energy. 136: p. 159-178.
  • Venkateswari R, Sreejith S, 2019. Factors influencing the efficiency of photovoltaic system. Renewable and Sustainable Energy Reviews. 101: p. 376-394.
  • Wu SY, Wang T, Xiao L, Shen ZG, 2019. Effect of cooling channel position on heat transfer characteristics and thermoelectric performance of air-cooled PV/T system. Solar Energy. 180: p. 489-500.
  • Yang T, Athienitis AK, 2014. A study of design options for a building integrated photovoltaic/thermal (BIPV/T) system with glazed air collector and multiple inlets. Solar Energy. 104: p. 82-92.
  • Yang T, Athienitis AK, 2015. Experimental investigation of a two-inlet air-based building integrated photovoltaic/thermal (BIPV/T) system. Applied Energy. 159: p. 70-79.

Effect of Using Fins on Cell Temperature at Air-Based PVT

Year 2020, Volume: 10 Issue: 1, 477 - 488, 01.03.2020

Ahmet Numan Özakın Ferhat Kaya

https://doi.org/10.21597/jist.656173

Abstract

In this study, the effect of addition of fins in air-based PVT system on cell temperature investigated. Experimental tests were performed with frequent and sparse fins configurations and also empty(non-finned) state. Also, thermal camera images of cells were investigated and compared to images obtained by Fluent Ansys. Cell temperatures for all status of both polycrystal and monocrystal panel decreased between 8-20 °C. Panel surface was observed to have a uniform temperature distribution. Finally, temperature distribution images obtained with ANSYS Fluent were found to be quite compatible with thermal camera images.

Keywords

air-based PVT system copper fins cell temperature Ansys Fluent thermal camera

Project Number

BAP/2015-147

References

  • Al-Waeli AHA, Sopian K, Kazem HA, Chaichan MT, 2017. Photovoltaic/Thermal (PV/T) systems: Status and future prospects. Renewable and Sustainable Energy Reviews. 77: p. 109-130.
  • Bahaidarah HMS, Subhan, A, Gandhidasan P, Rehman S, 2013. Performance evaluation of a PV (photovoltaic) module by back surface water cooling for hot climatic conditions. Energy. 59: p. 445-453.
  • Bahaidarah HMS, Baloch AAB, Gandhidasan P, 2016. Uniform cooling of photovoltaic panels: A review. Renewable and Sustainable Energy Reviews. 57: p. 1520-1544.
  • Baloch AAB., Bahaidarah HMS., Gandhidasan P, Al-Sulaiman FA, 2015. Experimental and numerical performance analysis of a converging channel heat exchanger for PV cooling. Energy Conversion and Management. 103: p. 14-27.
  • Bayrak F, Hamdeh NA, Alnefaie KA, Öztop HF, 2017. A review on exergy analysis of solar electricity production. Renewable and Sustainable Energy Reviews, . 74: p. 755-770.
  • Bora B, Kumar R, Sastry OS, Prasad B, Mondal S, 2018. Energy rating estimation of PV module technologies for different climatic conditions. Solar Energy. 174: p. 901-911.
  • Ceylan, İ, Yilmaz S, İnanç Ö, Ergün A, Gürel AE, Acar B, 2019. Determination of the heat transfer coefficient of PV panels. Energy. 175: p. 978-985.
  • Chandel SS, Agarwal T, 2017. Review of cooling techniques using phase change materials for enhancing efficiency of photovoltaic power systems. Renewable & Sustainable Energy Reviews. 73: p. 1342-1351.
  • Chauhan A, Tyagi V, Anand S, 2018. Futuristic approach for thermal management in solar PV/thermal systems with possible applications. Energy Conversion and Management. 163: p. 314-354.
  • Cuce E, Cuce PM, Bali T, 2013. An experimental analysis of illumination intensity and temperature dependency of photovoltaic cell parameters. Applied Energy,. 111: p. 374-382.
  • Dubey S, Tay AAO, 2013. Testing of two different types of photovoltaic–thermal (PVT) modules with heat flow pattern under tropical climatic conditions. Energy for Sustainable Development. 17(1): p. 1-12.
  • Dubey S, Tiwari GN, 2008. Thermal modeling of a combined system of photovoltaic thermal (PV/T) solar water heater. Solar Energy. 82(7): p. 602-612.
  • Fayaz H, Rahim NA, Hasanuzzaman M, 2019. A Rivai Numerical and outdoor real time experimental investigation of performance of PCM based PVT system. Solar Energy. 179: p. 135-150.
  • Gang P, Huide F, Tao Z, Jie J. 2011. A numerical and experimental study on a heat pipe PV/T system. Solar Energy. 85(5): p. 911-921.
  • Ghosh S, Yadav, VK, Mukherjee V, 2019. Impact of environmental factors on photovoltaic performance and their mitigation strategies–A holistic review. Renewable Energy Focus. 28: p. 153-172.
  • Gökmen N, Hu W, Hou P, Chen Z, Sera D, Spataru S, 2016. Investigation of wind speed cooling effect on PV panels in windy locations. Renewable Energy. 90: p. 283-290.
  • Kaiser AS, Zamora B, Mazón R, García JR, Vera F, 2014. Experimental study of cooling BIPV modules by forced convection in the air channel. Applied Energy. 135: p. 88-97.
  • Kaldellis JK, M Kapsali, Kavadias KA, 2014. Temperature and wind speed impact on the efficiency of PV installations. Experience obtained from outdoor measurements in Greece. Renewable Energy. 66: p. 612-624.
  • Kalogirou SA, 2001. Use of TRNSYS for modelling and simulation of a hybrid pv–thermal solar system for Cyprus. Renewable Energy. 23(2): p. 247-260.
  • Kazemian A, Hosseinzadeh M, Sardarabadi M, 2018. Effect of glass cover and working fluid on the performance of photovoltaic thermal (PVT) system: An experimental study. Solar Energy. 173: p. 1002-1010.
  • Kumar, R. Rosen MA, 2011a. A critical review of photovoltaic–thermal solar collectors for air heating. Applied Energy. 88(11): p. 3603-3614.
  • Kumar R, Rosen MA, 2011b. Performance evaluation of a double pass PV/T solar air heater with and without fins. Applied Thermal Engineering. 31(8): p. 1402-1410.
  • Lamnatou C, Chemisana D, 2017. Photovoltaic/thermal (PVT) systems: A review with emphasis on environmental issues. Renewable Energy. 105: p. 270-287.
  • Omer KA, Zala AM, 2018. Experimental investigation of PV/thermal collector with theoretical analysis. Renewable Energy Focus. 27: p. 67-77.
  • Özakin AN, Kaya F, 2019. Effect on the exergy of the PVT system of fins added to an air-cooled channel: A study on temperature and air velocity with ANSYS Fluent. Solar Energy. 184: p. 561-569.
  • Özakin AN, Kaya F, 2020. Experimental thermodynamic analysis of air-based PVT system using fins in different materials: Optimization of control parameters by Taguchi method and ANOVA. Solar Energy. 197: p. 199-211.
  • Saidur R, Jazi GB, Mekhlif S, Jameel M, 2012.Exergy analysis of solar energy applications. Renewable and Sustainable Energy Reviews. 16(1): p. 350-356.
  • Shukla A, Kanta K, Sharmaa A, Biwole PH, 2017. Cooling methodologies of photovoltaic module for enhancing electrical efficiency: A review. Solar Energy Materials and Solar Cells. 160: p. 275-286.
  • Tonui JK, Tripanagnostopoulos Y, 2008. Performance improvement of PV/T solar collectors with natural air flow operation. Solar Energy. 82(1): p. 1-12.
  • Ustun TS, Nakamura Y, Hashimoto J, Otani K, 2019.Performance analysis of PV panels based on different technologies after two years of outdoor exposure in Fukushima, Japan. Renewable Energy. 136: p. 159-178.
  • Venkateswari R, Sreejith S, 2019. Factors influencing the efficiency of photovoltaic system. Renewable and Sustainable Energy Reviews. 101: p. 376-394.
  • Wu SY, Wang T, Xiao L, Shen ZG, 2019. Effect of cooling channel position on heat transfer characteristics and thermoelectric performance of air-cooled PV/T system. Solar Energy. 180: p. 489-500.
  • Yang T, Athienitis AK, 2014. A study of design options for a building integrated photovoltaic/thermal (BIPV/T) system with glazed air collector and multiple inlets. Solar Energy. 104: p. 82-92.
  • Yang T, Athienitis AK, 2015. Experimental investigation of a two-inlet air-based building integrated photovoltaic/thermal (BIPV/T) system. Applied Energy. 159: p. 70-79.
There are 34 citations in total.

Details

Primary Language English
Subjects Mechanical Engineering
Journal Section Makina Mühendisliği / Mechanical Engineering
Authors

Ahmet Numan Özakın 0000-0002-2083-8703

Ferhat Kaya

Project Number BAP/2015-147
Publication Date March 1, 2020
Submission Date December 6, 2019
Acceptance Date January 25, 2020
Published in Issue Year 2020 Volume: 10 Issue: 1

Cite

APA Özakın, A. N., & Kaya, F. (2020). Effect of Using Fins on Cell Temperature at Air-Based PVT. Journal of the Institute of Science and Technology, 10(1), 477-488. https://doi.org/10.21597/jist.656173
AMA Özakın AN, Kaya F. Effect of Using Fins on Cell Temperature at Air-Based PVT. J. Inst. Sci. and Tech. March 2020;10(1):477-488. doi:10.21597/jist.656173
Chicago Özakın, Ahmet Numan, and Ferhat Kaya. “Effect of Using Fins on Cell Temperature at Air-Based PVT”. Journal of the Institute of Science and Technology 10, no. 1 (March 2020): 477-88. https://doi.org/10.21597/jist.656173.
EndNote Özakın AN, Kaya F (March 1, 2020) Effect of Using Fins on Cell Temperature at Air-Based PVT. Journal of the Institute of Science and Technology 10 1 477–488.
IEEE A. N. Özakın and F. Kaya, “Effect of Using Fins on Cell Temperature at Air-Based PVT”, J. Inst. Sci. and Tech., vol. 10, no. 1, pp. 477–488, 2020, doi: 10.21597/jist.656173.
ISNAD Özakın, Ahmet Numan - Kaya, Ferhat. “Effect of Using Fins on Cell Temperature at Air-Based PVT”. Journal of the Institute of Science and Technology 10/1 (March 2020), 477-488. https://doi.org/10.21597/jist.656173.
JAMA Özakın AN, Kaya F. Effect of Using Fins on Cell Temperature at Air-Based PVT. J. Inst. Sci. and Tech. 2020;10:477–488.
MLA Özakın, Ahmet Numan and Ferhat Kaya. “Effect of Using Fins on Cell Temperature at Air-Based PVT”. Journal of the Institute of Science and Technology, vol. 10, no. 1, 2020, pp. 477-88, doi:10.21597/jist.656173.
Vancouver Özakın AN, Kaya F. Effect of Using Fins on Cell Temperature at Air-Based PVT. J. Inst. Sci. and Tech. 2020;10(1):477-88.
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