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Prediction of Solar Radiation for the Major Climates of Jordan: A Regression Model

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Multiple regression models were developed for calculating the regression coefficients a and b of the Angström-type equation for estimating the monthly average daily global radiation on a horizontal surface for six major climates in Jordan. The equations for a and b were developed from the available values of these constants reported in the literature for locations across the country, along with the sunshine duration and the values of ground albedo (ρ_g). The developed correlations were tested for their applicability by estimating the regression constants and the solar radiation for six locations spread over the country, which were Irbid, Amman, Azraq, Al-Shawbak, Ma’an and Aqaba. The remarkable agreement between the estimated and experimental data of solar radiation in those locations suggests a wide applicability of the method for the locations with sunshine duration ranging from 0.7 to 0.8. The maximum and minimum percentages of error for those locations were found to be 6.3, 0.05%, respectively.
Słowa kluczowe
Rocznik
Strony
24--38
Opis fizyczny
Bibliogr. 38 poz., tab., rys.
Twórcy
autor
  • Department of Mechanical Engineering, Philadelphia University, Amman, Jordan
  • Deparrtment of Mechanical Engineering, Energy Management Program, University of Jordan, Amman, Jordan
Bibliografia
  • 1. Ababsa, 2013. Atlas of Jordan, http://books. openedition.org/ifpo/4560.
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  • 4. AL-Eisawi, D.M. 1996. Vegetation of Jordan. Book published By UNESCO (ROSTAS), Cairo Office. Cairo.
  • 5. Al-Muhtaseb, 2012. Development of a regression model for solar radiation in Jordanian site and assessment of related solar energy.
  • 6. Alsaad M.A., 1990. Characteristic distribution of global solar radiation for Amman, Jordan, Solar and Wind Technology, 7(2/3), 261–266.
  • 7. Alsaad M.A., 1990. Improved correlation for predicting global radiation for deferent location in Jordan, Int, J. Solar Energy, Vol. 8, 97–107.
  • 8. Alsaad M.A., 1990. Solar radiation map for Jordan Solar, Solar and Wind Technology, 7(2/3), 267–275.
  • 9. Alsaad M.A., 1990. The applicability of hourly solar radiation models to Amman, Jordan, Solar and wind technology, 7(4), 473–480.
  • 10. Alsaad M.A., 1991. Correlations for predicting average Global solar radiation incident on a horizontal surface in Amman, Jordan, J. King Saud Univ., Eng. Sci., 3(1), 121–134.
  • 11. Andrews, Rob W.; Pearce, Joshua M. 2013. The effect of spectral Albedo on amorphous silicon and crystalline silicon solar photovoltaic device performance, Solar Energy, 91, 233–241.
  • 12. Angström, 1924. Solar and Terrestrial Radiation, Quarterly Journal of the Royal Meteorological Society, Vol. 50, No. 210.
  • 13. Assi A. and Jama M., 2009. Estimating Global Solar Radiation on Horizontal from Sunshine Hours in Abu Dhabi – UAE.
  • 14. Duffie, J. and Beckman, W. 2013. Solar Engineering of Thermal Processes. John Wiley and sons INC., New York.
  • 15. El-Sebaii and Trabea A.A. 2005. Estimation of Global Solar Radiation on Horizontal Surfaces Over Egypt. Egypt. J. Solids, 28(1), 163–175.
  • 16. Gariepy J., 1980. Estimation of global solar radiation. International Report, Service of Meteorology, Government of Quebec, Canada.
  • 17. Gopinathan K.K., 1988. A general formula for computing the coefficients of the correlations connecting global solar radiation to sunshine duration. Solar Energy, 41, 499–502.
  • 18. Hamdan M.A. and N. Gazzawi, 1993. The effect of clouds on solar radiation, Energy Convers. Manage., 34(1), 29–32.
  • 19. Hamdan M.A., 1994. Solar Radiation Data for Amman, Applied Energy, pp. 87–96.
  • 20. Hammad M.A. and Al-Sayeh A.I., 1991. Diffuse and Global solar radiation correlations for Jordan, Int. J. Solar Energy, Vol. 10, 145–154.
  • 21. Hay J.E., 1979. Calculation of monthly mean solar radiation for horizontal and inclined surfaces, Solar Energy, 23, 4, 301–307.
  • 22. Iqbal, M., 1983. Introduction to solar radiation. New York: Academic
  • 23. Jain P.C., 1988. Estimation of monthly average hourly global and diffuse irradiation. Solar Wind Technol. 5, 7.
  • 24. Jain S., Jain P.C., 1988. A comparison of the Angström-type correlations and the estimation of monthly average daily global irradiation. Solar Energy.
  • 25. Jamil Ahmad M., Tiwari G.N., 2010. Solar radiation models – review. International journal of energy and environment, 1(3), 513–532.
  • 26. Liu B.Y. and Jordan R.C., 1960. The Interrelationship and Characteristic Distribution of Direct, Diffuse, and Total Radiation, Solar Energy, 4(3), 1–19.
  • 27. Liu B.Y. and Jordan R.C. 1940. The interrelationship and characteristic distribution of direct, defuse, and total solar radiation. Solar Energy, 4(1).
  • 28. Long, G., 1957. The bioclimatology and vegetation of East Jordan. Rome, UNESCO/ FAO.
  • 29. Markvart T. and Castazer L., 2003. Practical Handbook of Photovoltaics: Fundamentals and Applications.
  • 30. Page J.K., 1961. The estimation of monthly mean values of daily total short wave radiation on vertical and inclined surface from sunshine records for latitudes 40N–40S. Proceedings of UN Conference on New Sources of Energy, 4(598), 378–390.
  • 31. Rietveld M. 1978. A new method for estimating the regression coefficients in the formula relating solar radiation to sunshine. Agricultural Meteorology 19, 243–252.
  • 32. Starr M.R., Palz W., 1983. Photovoltaic power for Europe: an assessment study, Commission of the European Communities. (http://www.ftexploring. com/solar-energy/direct-and-diffuse-radiation. htm#fn2)
  • 33. Stone, R.J., 1993. Improved statistical procedure for the evaluation of solar radiation estimation models. Solar Energy Vol. 51, 289.
  • 34. Tetzlaff, G., 1983. Albedo of the Sahara. Cologne University Satellite Measurement of Radiation Budget Parameters. pp. 60–63.
  • 35. Tiwari, R.F and Sangeeta, T.H. 1997. Solar Energy, 24(6) 89–95.
  • 36. Togrul, I.T., 1998. Comparison of statistical performance of seven sunshine-based models for Elazig, Turkey, Chemica Acta Turuca, 26, 37.
  • 37. Zabara K., 1986. Estimation of the global solar radiation in Greece. Solar and Wind Technology, 3(4), 267–272.
  • 38. Zaid Jibril, 1991. Estimation of solar radiation over Jordan-Predicted tables, Renewable Energy, Vol. 2, 277–291.
Uwagi
PL
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-84ba1e3e-84f4-4fa8-82f4-c47de97f5459
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