Measurement of the Direct Flux of Solar Radiation During Operation of a Big Solar Furnace
International Journal of Sustainable and Green Energy
Volume 7, Issue 4, December 2018, Pages: 21-28
Received: Aug. 29, 2018;
Accepted: Sep. 13, 2018;
Published: Jan. 2, 2019
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Shavkat Fayziev, Laboratory of Big Solar Installations, Institute of Materials Science Scientific Production Association "Physics-Sun" Academy of Sciences Republic of Uzbekistan, Parkent, Uzbekistan
Yuldash Sobirov, Laboratory of Big Solar Installations, Institute of Materials Science Scientific Production Association "Physics-Sun" Academy of Sciences Republic of Uzbekistan, Parkent, Uzbekistan; Department of Alternative Energy Sources, Faculty of Energy, Tashkent State Technical University Named After Islam Karimov, Tashkent, Uzbekistan
Sirojiddin Makhmudov, Department of Alternative Energy Sources, Faculty of Energy, Tashkent State Technical University Named After Islam Karimov, Tashkent, Uzbekistan
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Methods for measuring solar radiation are considered and long-term data obtained by actinometric measurements of solar radiation at the location of the big solar furnace of the Academy of Sciences of Uzbekistan Institute of Materials Science Scientific Production Association "Physics-Sun", with a thermal power of 1 MW, are analyzed. Concentrators of solar radiation efficiently operate at high values of the direct flux of solar radiation, whereas photovoltaic stations operate on diffuse and total radiation, too. Therefore, the main attention is paid to the measurement of the direct flux of solar radiation. The first results until 2013 were obtained by a semi-automatic mode with the help of actinometers of the AT-50 type, after that an automated meteorological station of the MHP type with high-precision pyrheliometers CHP1, manufactured by Kipp & Zonen, was produced by the Netherlands, which is the leader in the production of solar sensors. During the operation of the Big Solar Furnace, a direct stream of solar radiation is continuously measured, since the power of the installation is directly proportional to this. The obtained long-term results of measuring the direct flux of solar radiation are processed in order to obtain average statistical data by years. To obtain reliable data on solar energy, solar sensors are annually calibrated. The last verification was carried out in January of 2018 at Kipp & Zonen.
Solar Furnace, Solar Radiation, Weather Station, Actinometer, Pyranometer, Pyrheliometer
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Measurement of the Direct Flux of Solar Radiation During Operation of a Big Solar Furnace, International Journal of Sustainable and Green Energy.
Vol. 7, No. 4,
2018, pp. 21-28.
Copyright © 2018 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/
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Yanishevsky Yu. D.: "Actinometric instruments and methods of observation." Leningrad, Gidrometeoizdat, 1959, p. 409.
Khodzhayeva G. K. Meteorological methods and instruments of observation. Tutorial. Publishing house of Nizhnevartovsk State University 2013. p. 190.
Solar radiation and radiation balance. (World Network), GGO them. Voyeikova, World Radiation Data Center of WMO, St. Petersburg p.70.
Fayziev Sh., Sobirov Yu., Mahmudov H., Gaziev G., Abdunabiev A. Means of measurement for actinometric observations. "UZSTANDART" Agency's Scientific-Technical Journal. No. 3. 2017. pp. 45-47.
ISO/IEC 17025. Pyranometer and Pyrheliometer Calibration Procedures. EKO Instruments Co. Ltd. 2014. p. 17.
Azimov. S. A.// Research and Production Complex "Sun". Two-mirror poligeliostat Solar furnace heat capacity of 1000 kW. Geliotexnika, 1987. №6. P.3.
Abdurakhmanov A. Mirror-concentrating systems of solar energy-power and process units and their effectiveness when using selective radiation absorbers: Diss. The competition is academic. Step. Dr. of Tech. sciences. - Moscow, 1992. -436p.
Abdurakhmanov A. A, Sobirov Yu. B., Paizullahonov M. S., Orlov S. A. Results of actinometric measurements at the location of the BSF with a thermal power of 1000 kW. Geliotexnika, 2012. №3. pp. 92-96.
Fayziev Sh., Göder N., Lupfert E. Preliminary results of the estimation of solar resources. Report of the ADB Project UZB TA 8008. Tashkent. 2013. 42 pp.
Fayziev Sh. A., Sobirov Yu. B. Measurements of Solar Resources in Uzbekistan. Applied Solar Energy, 2017, Vol. 1, pp. 57-60.