A Novel Simple Method to Abstract the Entire Parameters of the Solar Cell

  • Park, Minwon (Center of Applied Superconductivity Center, Korea Electrotech nology Research Institute) ;
  • Yu, In-Keun (Dept. of Electrical Engineering, Changwon National Univrsity)
  • 발행 : 2004.06.01

초록

PV power generation, which directly converts solar radiation into electricity, contains numerous significant advantages. It is inexhaustible and pollution-free, silent, contains no rotating parts, and has size-independent electricity conversion efficiency. The positive environmental effect of photovoltaics is that it replaces the more polluting methods of electricity generation or that it provides electricity where none was available before. This paper highlights a novel simple method to abstract the entire parameters of the solar cell. In development, design and operation of PV power generation systems, a technique for constructing V-I curves under different levels of solar irradiance and cell temperature conditions using basic characteristic values of the PV module is required. Everyone who has performed manual acquisition and analysis of solar cell I versus V data would agree that the job is tedious and time-consuming. A better alternative is to use an automated curve tracer to print out the I versus V curves and compute the four major parameters; $V_{oc}$, $I_{sc}$, FF, and . Generally, the V-I curve tracer indicates only the commonly used solar cell parameters. However, with the conventional V-I curve tracer it is almost impossible to abstract the more detailed parameters of the solar cell; A, $R_{s}$ and $R_{sh}$ , which satisfies the user, who aims at the analysis of the development of the PV power generation system, that being advanced simulation. In this paper, the proposed method provides us with satisfactory results to enable us to abstract the detailed parameters of the solar cell; A, $R_s$ and $R_{sh}$.>.

키워드

참고문헌

  1. Martin A. Green, 'Solar Cells Operating Principles, Technology, and System Applications', 1982 by Prentice-Hall, Inc., Englewood Cliffs, N.J. 07632
  2. Richard C. Neville, 'Solar Energy Conversion: The Solar Cell', 1980 by Elsevier Scientific Publishing Company
  3. Monji G. Jaboori, Mohamed M. Saied, Adel A. R. Hanafy, 'A Contribution to the Simulation and Design Optimization of Photovoltaic Systems', IEEE Transactions on Energy Conversion, Vol. 6, No. 3, pp.401-406, September 1991
  4. Bogdan S. Borowy, Ziyad M. Salameh, 'Methodology for Optimally Sizing the Combination of a Battery Bank and PV Array in a Wind/PV Hybrid System', IEEE Transactions on Energy Conversion, Vol. 11, No.2, pp.367-373, June 1996 https://doi.org/10.1109/60.507648
  5. M. Muselli, G. Notton, P. Poggi, A. Louche, 'PV-hybrid power systems sizing incorporrating battery storage: an analysis via simulation calculations', Renewable Energy 20 (2000) 1-7
  6. Kame Khouzam, Keith Hoffman, 'Real-Time Simulation of Photovoltaic Modules', Solar Energy Vol. 56, No. 6, pp.521-526, 1996
  7. [MS-601, 601F Manual] EKO Co.
  8. Minwon Park, In-Keun Yu, A Novel Real-Time Simulation Technique of Photovoltaic Geeration System Using RTDS, IEEE Transactions of Energy Conversion, Vol. 19, No. 1, pp.164-169, March 2004
  9. Minwon Park, Kenji Matsuura, Hiroshi Yamashita, Masakazu Michihira, A Novel Simulation Method for PV Power Generation System using Real Field Weather Condition and its Application, T.IEE Japan-B, Vol. 121-B, No.11, 2001 pp.1499-1506
  10. Minwon Park, Bong-Tae Kim, In-Kuen Yu, 'A Novel simulation Scheme for Grid Connected Photovoltaic Generation Systems' KIEE International Transactions on EMECS, Vol. 11B-4, 169-174 (2001)
  11. Minwon Park, Nak-Gueon Seong, In-Kuen Yu, 'A Novel Photovoltaic Power Generation System including the Function of Shunt Active Filter' KIEE International Transactions on EMECS, Vol. 3B-2, 103-110 (2003)