doi:10.1007/s11708-015-0369-3

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Frontiers in Energy ›› 2015, Vol. 9 ›› Issue (3) : 311-321. DOI: 10.1007/s11708-015-0369-3

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Theoretical prediction and validation of global horizontal solar irradiance for a tropical climate in India

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Abstract

This paper aims to propose monthly models responsible for the theoretical evaluation of the global horizontal irradiance of a tropical region in India which is Sivagangai situated in Tamilnadu. The actual measured global horizontal irradiance hails from a 5 MW solar power plant station located at Sivagangai in Tamilnadu. The data were monitored from May 2011 to April 2013. The theoretical assessment was conducted differently by employing a programming platform called Microsoft Visual Basic 2010 Express. A graphical user interface was created using Visual Basic 2010 Express, which provided the evaluation of empirical parameters for model formulation such as daily sunshine duration (S), maximum possible sunshine hour duration (S₀), extra terrestrial horizontal global irradiance (H₀) and extra terrestrial direct normal irradiance (G₀). The proposed regression models were validated by the significance of statistical indicators such as mean bias error, root mean square error and mean percentage error from the predicted and the actual values for the region considered. Comparison was made between the proposed monthly models and the existing normalized models for global horizontal irradiance evaluation.

Keywords

global horizontal irradiance (GHI) / mean bias error / root mean square error / mean percentage error / coefficient of regression / Visual Basic 2010 Express

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. . Frontiers in Energy. 2015, 9(3): 311-321 https://doi.org/10.1007/s11708-015-0369-3

参考文献

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[1]	Salmi M, Chegaar M, Mialhe P. A collection of models for the estimation of global solar radiation in Algeria. Energy Sources, Part B: Economics, Planning, and Policy, 2011, 6(2): 187–191 CrossRef ADS Google scholar
[2]	Besharat F, Dehghan A A, Faghih A R. Empirical models for estimating global solar radiation: a review and case study. Renewable & Sustainable Energy Reviews, 2013, 21: 798–821 CrossRef ADS Google scholar
[3]	Angstrom A S. Solar and terrestrial radiation. Report to the international commission for solar research on actinometric investigations of solar and atmospheric radiation. Quarterly Journal of the Royal Meteorological Society, 1924, 50(210): 121–126 CrossRef ADS Google scholar
[4]	Prescott J A. Evaporation from water surface in relation to solar radiation. Transactions of the Royal Society of South Australia, 1940, 64: 114–118
[5]	Ögelman H, Ecevit A, Tasdemiroglu E. A new method for estimating solar radiation from bright sunshine data. Solar Energy, 1984, 33(6): 619–625 CrossRef ADS Google scholar
[6]	Samuel T D M A. Estimation of global radiation for Sri Lanka. Solar Energy, 1991, 47(5): 333–337 CrossRef ADS Google scholar
[7]	Paltridge G W, Proctor D. Monthly mean solar radiation statistics for Australia. Solar Energy, 1976, 18(3): 235–243 CrossRef ADS Google scholar
[8]	Daneshyar M. Solar radiation statistics for Iran. Solar Energy, 1978, 21(4): 345–349 CrossRef ADS Google scholar
[9]	Samimi J. Estimation of height-dependent solar radiation and application to the solar climate of Iran. Solar Energy, 1994, 52(5): 401–409 CrossRef ADS Google scholar
[10]	Badescu V. Correlations to estimate monthly mean daily solar global irradiation: application to Romania. Energy, 1999, 24(10): 883–893 CrossRef ADS Google scholar
[11]	Sabziparvar A A. A simple formula for estimating global solar radiation in central arid deserts of Iran. Renewable Energy, 2008, 33(5): 1002–1010 CrossRef ADS Google scholar
[12]	Bristow K L, Campbell G S. On the relationship between incoming solar radiation and daily maximum and minimum temperature. Agricultural and Forest Meteorology, 1984, 31(2): 159–166 CrossRef ADS Google scholar
[13]	Allen R. Self-calibrating method for estimating solar radiation from air temperature. Journal of Hydrologic Engineering, 1997, 2(2): 56–67 CrossRef ADS Google scholar
[14]	Thornton P E, Running S W. An improved algorithm for estimating incident daily solar radiation from measurements of air temperature, humidity and precipitation. Agricultural and Forest Meteorology, 1999, 93(4): 211–228 CrossRef ADS Google scholar
[15]	Almorox J, Hontoria C, Benito M. Models for obtaining daily global solar radiation with measured air temperature data in Madrid (Spain). Applied Energy, 2011, 88(5): 1703–1709 CrossRef ADS Google scholar
[16]	Swartman R K, Ogunlade O. Solar radiation estimates from common parameters. Solar Energy, 1967, 11(3-4): 170–172 CrossRef ADS Google scholar
[17]	Glover J, McCulloch J S G. The empirical relation between solar radiation and hours of sunshine. Quarterly Journal of the Royal Meteorological Society, 1958, 84(360): 172–175 CrossRef ADS Google scholar
[18]	Gopinathan K K. A general formula for computing the coefficients of the correlation connecting global solar radiation to sunshine duration. Solar Energy, 1988, 41(6): 499–502 CrossRef ADS Google scholar
[19]	Chen R, Ersi K, Yang J, Lu S, Zhao W. Validation of five global radiation models with measured daily data in China. Energy Conversion and Management, 2004, 45(11-12): 1759–1769 CrossRef ADS Google scholar
[20]	AI-Alawi S M, AI- Hinai H A. An ANN-based approach for predicting global radiation in locations with no direct measurement instrumentation. Renewable Energy, 1998, 14(1-4): 199–204 CrossRef ADS Google scholar
[21]	Mohandes M, Rehman S, Halawani T O. Estimation of global solar radiation using artificial neural networks. Renewable Energy, 1998, 14(1-4): 179–184 CrossRef ADS Google scholar
[22]	Mubiru J, Banda E J K B. Estimation of monthly average daily global solar irradiation using artificial neural networks. Solar Energy, 2008, 82(2): 181–187 CrossRef ADS Google scholar
[23]	Perez R, Lorenz E, Pelland S, Beauharnois M, Van Knowe G, Hemker K Jr, Heinemann D, Remund J, Müller S C, Traunmüller W, Steinmauer G, Pozo D, Ruiz-Arias J A, Lara-Fanego V, Ramirez-Santigosa L, Gaston-Romero M, Pomares L M. Comparison of numerical weather prediction solar irradiance forecasts in the US, Canada and Europe. Solar Energy, 2013, 94: 305–326 CrossRef ADS Google scholar
[24]	Benghanem M, Mellit A, Alamri S N. ANN-based modelling and estimation of daily global solar radiation data: a case study. Energy Conservation and Management, 2009, 50(7): 1644–1655 CrossRef ADS Google scholar
[25]	Newland F J. A study of solar radiation models for the coastal region of South China. Solar Energy, 1988, 31: 227–235
[26]	Srivastava R C, Pandey H. Estimating Angstrom-Prescott coefficients for India and developing a correlation between sunshine hours and global solar radiation for India, ISRN Renewable Energy, 2013, Article ID 403742
[27]	Taylor W. Sunshine. 1996-<month>07</month>, www.taylormade.com.au/billspages/sunshine/sunshine.html
[28]	Katiyar A K, Pandey C K. Simple correlation for estimating the global solar radiation on horizontal surfaces in India. Energy, 2010, 35(12): 5043–5048 CrossRef ADS Google scholar
[29]	Driesse A, Thevenard D A. Test of Suehrcke’s sunshine radiation relationship using a global data set. Solar Energy, 2002, 72(2): 167–175 CrossRef ADS Google scholar
[30]	Elagib N A, Mansell M G. New approaches for estimating global solar radiation across Sudan. Energy Conversion and Management, 2000, 41(5): 419–434 CrossRef ADS Google scholar
[31]	Tiba C, de Aguiar R, Fraidenraich N. Analysis of a new relationship between monthly global irradiation and sunshine hours from a database of Brazil. Renewable Energy, 2005, 30(6): 957–966 CrossRef ADS Google scholar
[32]	Mustafa Omer A. Diffuse solar radiation over Shambat, Khartoum North. Renewable Energy, 1994, 4(2): 227–233 CrossRef ADS Google scholar
[33]	Tarhan S, Sar&inodot; A. Model selection for global and diffuse radiation over the Central Black Sea (CBS) region of Turkey. Energy Conversion and Management, 2005, 46(4): 605–613 CrossRef ADS Google scholar
[34]	YaoW, LiZ, WangY, JiangF, HuL. Evaluation of global solar radiation models for Shanghai, China. Energy Conversion and Management, 2014, 84: 597–612 CrossRef ADS Google scholar
[35]	Veeran P K, Kumar S. Analysis of monthly average daily global radiation and monthly average sunshine duration at two tropical locations. Renewable Energy, 1993, 3(8): 935–939 CrossRef ADS Google scholar
[36]	Zawilska E, Brooks M J. An assessment of the solar resource for Durban, South Africa. Renewable Energy, 2011, 36(12): 3433–3438 CrossRef ADS Google scholar
[37]	Sudhakar K, Tulika S. Energy and exergy analysis of 36W solar photovoltaic module. International Journal of Ambient Energy. 2013, 35: 51–57
[38]	Yousif C, Quecedo G O, Santos J B. Comparison of solar radiation in Marsaxlokk, Malta and Valladolid, Spain. Renewable Energy, 2013, 49: 203–206 CrossRef ADS Google scholar
[39]	Almorox J, Benito M, Hontoria C. Estimation of monthly Angström-Prescott equation coefficients from measured daily data in Toledo, Spain. Renewable Energy, 2005, 30(6): 931–936 CrossRef ADS Google scholar
[40]	Toğrul I T, Toğrul H, Evin D. Estimation of monthly global solar radiation from sunshine duration measurement in Elaziğ. Renewable Energy, 2000, 19(4): 587–595 CrossRef ADS Google scholar
[41]	Hussain M, Rahman L, Rahman M M. Technical note: techniques to obtain improved predictions of global radiation from sunshine duration. Renewable Energy, 1999, 18(2): 263–275 CrossRef ADS Google scholar
[42]	Chegaar M, Chibani A. Global solar radiation estimation in Algeria. Energy Conversion and Management, 2001, 42(8): 967–973 CrossRef ADS Google scholar
[43]	Kholagli A. Solar radiation over Sudan—comparison of measured and predicted data. Solar Energy, 1983, 31(1): 45–53 CrossRef ADS Google scholar
[44]	Ulgen K, Hepbasli A. Comparison of diffuse fraction of daily and monthly global radiation for Izmir, Turkey. Energy Sources, 2003, 25(7): 637–649 CrossRef ADS Google scholar

Acknowledgments

The data of global solar radiation were obtained from 5 MW solar plant farm Sivagangai. Hence the authors thank the organization for their contribution of data set.