POSSIBILITIES OF THE SOLAR ENERGY USE FOR THE POWER SUPPLY OF INDEPENDENT CONSUMERS IN VENEZUELA

The paper analyzes the schedules of the electric load to the different consumers depending on their level of life, and the parameters of the elements of heat and power supply based on schemes of the solar energy use concerning the adopted Venezuela’s government program of development of power supply on the basis of solar energy. In addition, it stresses the importance of a problem of power supply of independent consumers in remote areas of Venezuela. Moreover the paper presents a comparison of the technical parameters of schemes of power supply using different types of solar modules for the conditions of the Alta Guajira area in the Bolivarian Republic of Venezuela and examines the use of vacuum solar collectors for hot water supply consumers.

1. Ministerio del Poder Popular para la Energía Eléctrica. Energías renovables en zonas aisladas, indígenas y fronterizas, Junio 2012 (in Span.).

2. La Fundación para el Desarrollo del Servicio Eléctrico. Available at: http://www.fundelec.gov.ve/ (in Span.).

3. Instituto Nacional de Estadísticas. Informe Geoambiental 2007 estado Zulia, Junio 2010 (in Span.).

4. República Bolivariana de Venezuela, Instituto Nacional de Estadísticas. XIV Censo Nacional de Población y Vivienda, Octubre 2013. Available at: http://www.ine.gov.ve (in Span.).

5. Kaldellis J., Kavadias K., Zafirakis D. Experimental validation of the optimum photovoltaic panels’ tilt angle for remote consumers. Renewable Energy, 2012, vol. 46, issue C, pp. 179–191 (in Eng.).

6. Vissarionov V.I., Deryugina G.V., Kuznetcova V.A, Malinin N.K. Solnečnaâ ènergetika: učebnoe posobie dlâ vuzov. Moscow: Izdatel’stvo dom MÈI Publ., 2008.

7. Chaniotakis E. Modelling and analysis of water cooled photovoltaics, MSc thesis, Faculty of Energy System and Environment, Department of Mechanical Engineering, University of Strathclyde, Scotland, 2001(in Eng.).

8. Bergene T. and. Lovvik O.M. Model calculations on a flat-plate solar heat collector with integrated solar cell. Solar Energy, 1995, vol. 55, no. 6, pp. 453–462 (in Eng.).

9. Croitoru A.M., Badea A. Water cooling of photo-voltaic panels from passive house located inside the University Politehnica of Bucharest. Scientific bulletin, series C: electrical engineering and computer science, 2013, vol. 75 (in Eng.).

10. Tripanagnostopoulos Y., Nousia Th., Souliotis M. and Yianoulis P. Hybrid photovoltaic/thermal solar systems, Solar Energy, 2002, no. 72(3), pp. 217–234 (in Eng.).

11. Iurevych O., Gubin S., Dudeck M. Combined re-ceiver of solar radiation with holographic planar concen-trator. 1st International Symposium on electrical Arc and Thermal Plasma in Africa, 17–22 October 2011 (in Eng.).

12. Castillo J.E., Russo J.M., Aspnes E., and Rosen-berg G. Low concentration planar holographic cigs, in Optics for Solar Energy. OSA Technical Digest, 2010, paper STuD3 (in Eng.).

13. Castillo-Aguilella J.E. Non imaging applications of volume diffractive optics, Ph.D thesis, Department of electrical and computer engineering, the university of Arizona, USA, 2012. (in Eng.).

14. Iurevych O., Gubin S., Dudeck M. Modelling of a Hybrid Solar Panel with Solar Concentration. Electrical Engineering Research (EER), April 2013, vol. 1, issue 2 (in Eng.).