Prefeasibility Study of a Solar Power Plant Project and Optimization of a Meteorological Station Performance

Derouich, W.; Besbes, M.; Olivencia, J. D.

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Journal of applied research and technology

versão On-line ISSN 2448-6736versão impressa ISSN 1665-6423

J. appl. res. technol vol.12 no.1 Ciudad de México Fev. 2014

Prefeasibility Study of a Solar Power Plant Project and Optimization of a Meteorological Station Performance

W. Derouich^1,2 , M. Besbes*¹, J. D. Olivencia²

¹ High School of Technology and Computer Science, University of Carthage 45 rue des entrepreneurs, Charguia 2, Tunis Carthage 2035 Tunisia. *mongi.besbes@gmail.com

² International Business Development Department, ABENGOA SOLAR, Spain.

Abstract

A prefeasibility study of a solar power plant project was carried out in order to study and search the best location to install a concentrated solar power plant according to a tender with the Algerian electricity company "SPE" following a specific criteria and methodology in order to obtain a site with a maximum possible irradiation along with other economic constraints. Normally, eleven years of solar irradiation data from an on-ground weather station is needed for site assessment, such data are not available, hence the typical meteorological year irradiation based on satellite imagery results is needed in order to have the accurate value, therefore we can give the right evaluation for the site candidate. Additionally, an analysis of a weather measurement station was carried out to ensure the proper functioning of the weather data reception and analysis processes, and thus to optimize the algorithm of a data logger in order to get the right measurement with a minimum error. The correction algorithm was developed by weather scientists and was added to the data logger main program.

Keywords: Site assessment, satellite imagery, direct normal irradiation, data logger, correction algorithm, meteorological station, pyranometer.

Resumen

Un estudio de prefactibilidad de un proyecto de planta solar se lleva a cabo para estudiar y buscar la mejor ubicación, esto es para instalar una planta de energía solar concentrada, de acuerdo con un petición de oferta a la compañía eléctrica Argelina SPE, siguiendo los criterios y la metodología específica para obtener un sitio con un máximo posible de irradiación. Normalmente, se necesitan once años de datos de irradiación solar de la estación meteorológica para la evaluación del sitio. Estos datos no están disponibles, por lo que necesitamos la TMY basado en los resultados de las imágenes de satélite para tener el valor preciso. Por lo tanto, podemos dar a la evaluación correcta para el sitio. Un análisis de medición de una estación meteorológico se efectuó por asegurar el buen funcionamiento de la recepción de datos de la estación meteorológica, y consecuentemente lleva a optimizar el algoritmo de la data logger para obtener la medida correcta con un error mínimo posible. El algoritmo de corrección fue creado por meteorólogos y fue agregado al programa principal de data logger.

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References

[1] Batlles FJ et al. "On shadowband correction methods for diffuse irradiance measurements". Solar Energy 1995;54(2):105-14. [ Links ]

[2] Batlles FJ et al., "Empirical modeling of hourly direct irradiance by means of hourly global irradiance". Energy 2000;25(7):675-88. [ Links ]

[3] Behdashti, et al., "Field Experiments and Technical Evaluation of an Optimized Media Evaporative Cooler for Gas Turbine Power Augmentation", Journal Applied of Research and Technology (JART), Vol. 10, pp. 458-471, 2012. [ Links ]

[4] Camps J, and Soler MR. "Estimation of diffuse solar-irradiance on a horizontal surface for cloudless days: a new approach". Solar Energy 1992;49(1):53-63. [ Links ]

[5] Carroll JJ. "Global transmissivity and diffuse fraction of solar radiation for clear and cloudy skies as measured and as predicted by bulk transmissivity models". Solar Energy 1985;35(2):105-18. [ Links ]

[6] Cartwright TJ. "Here comes the Sun: solar energy from a flat-plate collector. In: Modeling the world in a spreadsheet-environmental simulation on a microcomputer. London": The Johns Hopkins University Press, 1993. p. 121-44. [ Links ]

[7] Chendo MAC and Maduekwe AAL. "Hourly global and diffuse radiation of Lagos, Nigeria-correlation with some atmospheric parameters". Solar Energy 1994;52(3):247-51. [ Links ]

[8] David L. King and Daryl R. Myers, "Silicon Photodiode Pyranometers: Operational Characteristics, Historical Experiences, and New Calibration" Procedures, 26th IEEE Photovoltaic Specialists Conference, 1997. [ Links ]

[9] David L. King et al. "Measuring Solar Spectral and Angle-of-Incidence Effects on Photovoltaic Modules and Solar Irradiance Sensors", 26th IEEE Photovoltaic Specialists Conference, September 29-October 3, 1997, Anaheim, California. [ Links ]

[10] Davies JA and McKay DC. "Estimating solar irradiance and components". Solar Energy 1982;29(1):55-64. [ Links ]

[11] Elagib NA et al. "New empirical models for global solar radiation over Bahrain". Energy Conversion Management 1998; 39(8):827-35. [ Links ]

[12] Frank Vignola, "Solar Cell Based Pyranometers: Evaluation of Diffuse Responsivity", Proceedings of the 1999. Annual Conference American Solar Energy Society, June 1999. [ Links ]

[13] Garrison JD. "A study of the division of global irradiance into direct and diffuse irradiances at thirty three US sites". Solar Energy 1985;35(4):341-51. [ Links ]

[14] Gueymard C. et al. "A critical look at recent interpretations of the Angstrom approach and its future in global solar radiation prediction". Solar Energy 1995; 54(5):357-63. [ Links ]

[15] Gueymard C. "Critical analysis and performance assessment of clear-sky solar-irradiance models using theoretical and measured data". Solar Energy 1993;51(2):121-38. [ Links ]

[16] Gueymard C. "Mathematically integrable parametrization of clear-sky beam and global irradiances and its use in daily irradiation applications". Solar Energy 1993;50(5):385-97. [ Links ]

[17] Iqbal M. "An introduction to solar radiation". Toronto: Academic press, 1983. [ Links ]

[18] Iqbal M. "Estimation of the monthly average of the diffuse component of total insolation on a horizontal surface". Solar Energy 1978;20(1):101-5. [ Links ]

[19] J. Augustyn, et al. "Update of Algorithm to Correct Direct Normal Irradiance Measurements Made with a Rotating Shadow Band Pyranometer", Proc. Solar 2004, American Solar Energy Society, 2004. [ Links ]

[20] Jeter SM, Balaras CA. "Development of improved solar radiation models for predicting beam transmittance". Solar Energy 1990;44(3):149-56. [ Links ]

[21] Kasten, F. and Young, "A. Revised Optical Air Mass Tables and Approximation Formula", Applied Optics 28, 4735 (1989). [ Links ]

[22] King David L et al. "Improved Accuracy for Low-Cost Solar Irradiance Sensors", Presented at 2nd World Conference and Exhibition on Photovoltaic Solar Energy Conversion, July 6-10, 1998. [ Links ]

[23] Lam JC and Li DHW. "Correlation between global solar-radiation and its direct and diffuse components". Building and Environment 1996;31(6):527-35. [ Links ]

[24] Li DHW and Lam JC. "Solar heat gain factors and the implications for building designs in subtropical regions". Energy and Buildings 2000;32(1):47-55. [ Links ]

[25] Louche A et al. "Correlations for direct normal and global horizontal irradiations on a French Mediterranean site". Solar Energy 1991;46(4):261-6. [ Links ]

[26] Machler MA and Iqbal M. "A modification of the ASHRAE clear-sky irradiation model". ASHRAE Transactions 1985;91(1a):106-15. [ Links ]

[27] Mohandes M. et al., "TO. Use of radial basis functions for estimating monthly mean daily solar-radiation". Solar Energy 2000;68(2):161-8. [ Links ]

[28] Rao CRN et al. "The diffuse component of the daily global solar-irradiation at Corvallis, Oregon (USA)". Solar Energy 1984;32(5):637-41. [ Links ]

[29] Reindl DT and Beckman WA, Duffie JA. "Diffuse fraction corrections". Solar Energy 1990;45(1):1-7. [ Links ]

[30] Sen Z. "Fuzzy algorithm for estimation of solar irradiation from sunshine duration". Solar Energy 1998;63(1):39-49. [ Links ]

[31] Sherry JE and Justus CG. "A simple hourly all-sky solar-radiation model based on meteorological parameters". Solar Energy 1984;32(2):195-204. [ Links ]

[32] Srivastava SK et al. "Estimation of global solar-radiation in Uttar Pradesh (India) and comparison of some existing correlations". Solar Energy 1993;51(1):27-9. [ Links ]

[33] Thamir K. Ibrahim and M.M. Rahman, "Thermal Impact of Operating Conditions on the Performance of a Combined Cycle Gas Turbine", Journal Applied of Research and Technology (JART),Vol. 10, pp. 567-578, 2012. [ Links ]

[34] Tovar J et al. "One-minute global irradiance probability density distributions conditioned to the optical air-mass". Solar Energy 1998;62(6):387-93. (1998). [ Links ]

[35] Trujillo JHS. "Solar performance and shadow behaviour in buildings — case study with computer modelling of a building in Loranca, Spain". Building and Environment 1998;33(2-3):117-30. [ Links ]

[36] Vignola F and McDaniels DK. "Beam-global correlations in the Northwest Pacific". Solar Energy 1986;36(5):409-18. [ Links ]

[37] J.J. Michalsky et al. "Cosine response characteristics of some radiometric and photometric sensors", Solar Energy, Volume 54, issue 6, 397-402. [ Links ]

[38] Vignola, F. "Solar Cell Based Pyronometers: Evaluation of the Diffuse Response", Proceedings of the 1999 Annual Conference, American Solar Energy Society, 260, June 1999. [ Links ]