Thermal modelling of low concentrator photovoltaic systems

Authors

  • J.D. Gerber University of Cape Town
  • M.A. Benecke
  • F.J. Vorster
  • E.E. van Dyk

DOI:

https://doi.org/10.17159/2413-3051/2013/v24i1a3007

Abstract

Efficient thermal management of low concentrator photovoltaic (LCPV) systems will allow maximizing of the power output and may also substantially prolong operating lifetime. For this reason, it is necessary to develop a thorough understanding of the thermal transfer and dissipation mechanisms associated with an LCPV system. The LCPV system under consideration uses a 7-facet reflector optical design, providing a geometric concentration ratio of approximately 4.85. The LCPV system succeeded in increasing the short circuit current from 1A to 5.6A, demonstrating an effective concentration ratio of approximately 4.75. LCPV system temperatures in excess of 80°C were recorded without a thermal management system. A basic thermal model was developed and assessed under various environmental conditions. The effectiveness of a heat-sink, which reduced the temperature difference between the LCPV receiver temperature and the ambient temperature by 37.5%, was also evaluated. The results discussed in this paper will assist the future development of techniques aimed at reducing the high temperatures associated with LCPV systems.

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Author Biography

  • J.D. Gerber, University of Cape Town
    Energy Research Centre Snr Research Officer

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Published

2013-02-01

Issue

Vol. 24 No. 1 (2013): Journal of Energy in Southern Africa. February

Section

Special Energy News

How to Cite

Thermal modelling of low concentrator photovoltaic systems. (2013). Journal of Energy in Southern Africa, 24(1), 51-55. https://doi.org/10.17159/2413-3051/2013/v24i1a3007