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Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System

Year 2013, Volume: 3 Issue: 2, 412 - 419, 01.06.2013

Abstract

The rising cost of the utility electricity has been on the steady rise recently thereby making electricity unaffordable for households within the low income category in the African continent. The global move from the fossil-based energy generation to the cleaner, renewable energy sources has ignited intensive research in the solar energy resources.In this paper, we discuss the computer simulation of the technical and economic model of a 2.5kW grid-tie residential photovoltaic system. The physical circuit model is built with Matlab/ Simulink software. The details of the internal electrical components that make up the solar panel and the external circuits that eventually connect it the grid are modeled here. The hourly electrical output, efficiency and the cash flow are modeled with System Advisory Model (SAM).

References

  • R. Williams, “Becquerel Photovoltaic Effect in Binary Compounds,” The journal of Chemical physics, vol.32, pp. 1505-1514, 1960.
  • A.C. Melissinos, Principles of modern technology. Department of Physics, University of Rochester, Press Syndicate of the University of Cambridge, 1990
  • N. Pandiarajan and R. Muthu, “Mathematical Modeling of Photovoltaic Module with Simulink,” IEEE Is t International Conference on Electrical energy Systems, pp. 257-263, 2011
  • M.G. Villalva, J.R. Gazoli, and J.R. Filho, “Modeling and circuit-based simulation of photovoltaic arrays,” IEEE, pp. 1244-1254, 2009
  • Seok-II Go; Seon-Ju Ahn; et al, “Simulation and analysis of existing MPPT control methods in a PV generation system,” Journal of International Council on Electrical Engineering vol. 1, no 4, pp. 446-451, 2011
  • Systems Advisor Model Help Files, National Renewable Energy laboratory (NREL), USA, 2009
  • National Energy Regulator of South Africa (NERSA), “Review of Renewable Energy feed-in Tariffs”, NERSA Consultation Paper 2011
  • Statistics South Africa; ‘Monetary Policy Review,” South Africa Reserve Bank; pp. 3, May 2012 [9] City of Cape Town, www.capetown.gov.za/en/electricity/Pages/ElectricityTar iff.aspx, Apr 28, 2013 “Electricity Tariff”,
Year 2013, Volume: 3 Issue: 2, 412 - 419, 01.06.2013

Abstract

References

  • R. Williams, “Becquerel Photovoltaic Effect in Binary Compounds,” The journal of Chemical physics, vol.32, pp. 1505-1514, 1960.
  • A.C. Melissinos, Principles of modern technology. Department of Physics, University of Rochester, Press Syndicate of the University of Cambridge, 1990
  • N. Pandiarajan and R. Muthu, “Mathematical Modeling of Photovoltaic Module with Simulink,” IEEE Is t International Conference on Electrical energy Systems, pp. 257-263, 2011
  • M.G. Villalva, J.R. Gazoli, and J.R. Filho, “Modeling and circuit-based simulation of photovoltaic arrays,” IEEE, pp. 1244-1254, 2009
  • Seok-II Go; Seon-Ju Ahn; et al, “Simulation and analysis of existing MPPT control methods in a PV generation system,” Journal of International Council on Electrical Engineering vol. 1, no 4, pp. 446-451, 2011
  • Systems Advisor Model Help Files, National Renewable Energy laboratory (NREL), USA, 2009
  • National Energy Regulator of South Africa (NERSA), “Review of Renewable Energy feed-in Tariffs”, NERSA Consultation Paper 2011
  • Statistics South Africa; ‘Monetary Policy Review,” South Africa Reserve Bank; pp. 3, May 2012 [9] City of Cape Town, www.capetown.gov.za/en/electricity/Pages/ElectricityTar iff.aspx, Apr 28, 2013 “Electricity Tariff”,
There are 8 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Chukwubuikem Chukwuka This is me

K. A. Folly This is me

Publication Date June 1, 2013
Published in Issue Year 2013 Volume: 3 Issue: 2

Cite

APA Chukwuka, C., & Folly, K. A. (2013). Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System. International Journal Of Renewable Energy Research, 3(2), 412-419.
AMA Chukwuka C, Folly KA. Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System. International Journal Of Renewable Energy Research. June 2013;3(2):412-419.
Chicago Chukwuka, Chukwubuikem, and K. A. Folly. “Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System”. International Journal Of Renewable Energy Research 3, no. 2 (June 2013): 412-19.
EndNote Chukwuka C, Folly KA (June 1, 2013) Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System. International Journal Of Renewable Energy Research 3 2 412–419.
IEEE C. Chukwuka and K. A. Folly, “Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System”, International Journal Of Renewable Energy Research, vol. 3, no. 2, pp. 412–419, 2013.
ISNAD Chukwuka, Chukwubuikem - Folly, K. A. “Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System”. International Journal Of Renewable Energy Research 3/2 (June 2013), 412-419.
JAMA Chukwuka C, Folly KA. Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System. International Journal Of Renewable Energy Research. 2013;3:412–419.
MLA Chukwuka, Chukwubuikem and K. A. Folly. “Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System”. International Journal Of Renewable Energy Research, vol. 3, no. 2, 2013, pp. 412-9.
Vancouver Chukwuka C, Folly KA. Technical and Economic Modeling of the 2.5kW Grid-Tie Residential Photovoltaic System. International Journal Of Renewable Energy Research. 2013;3(2):412-9.