Abstract
The aim of this paper is to review and evaluate the performances of a solar tower gas turbine central with a capacity of 11.5 MWe, then we assess the potential to improve the capacity of the installation by adding a combined steam cycle with electrical production equal to 3.5.The numerical study of the installation will be done by calculating the solar fields’ effectiveness, and then we simulate the different components of the installation by the TRNSYS 16 software.
The aim of this paper is to review and evaluate the performances of a solar tower gas turbine central with a capacity of 11.5 MWe, then we assess the potential to improve the capacity of the installation by adding a combined steam cycle with electrical production equal to 3.5.The numerical study of the installation will be done by calculating the solar fields’ effectiveness, and then we simulate the different components of the installation by the TRNSYS 16 software.
References
A. Ferrière. “Centrales solaires thermodynamiques. Edition Techniques de l’Ingénieur”, BE 8 903, pp 1-20, 2007.
S.Bonnet, M. Alaphilippe, P. Stouffs. “Thermodynamic solar energy conversion: Reflections on the optimal solar concentration ratio”. International Journal of Energy, Environment and Economics,vol12, pp141-152., 2006.
G. Barigozzi, G. Bonetti, G. Franchini, A. Perdichizzi, S. Ravelli. “Thermal performance prediction of a solar hybrid gas turbine. Solar Energy”, vol 86, pp2116–2127, 2012.
European Commission. SOLGATE Solar hybrid gas turbine electric power system – final publishable report, 2002. http://ec.europa.eu/ research/energy/pdf /solgate.
Pirre Garcia, Alain Ferrier, G. Flamant, P. Costerg et al. “Solar field efficiency and electricity generation estimations for a hybrid solar gas turbine project in France”. Journal of Solar Energy Engineering, vol 130, pp 145021‐145023, 2008.
Peter Schwarzbözl, M .Schmitz, R .Pitz-Paal, R. Buck. Analysis of “Solar Gas Turbine Systems with Pressurized Air Receivers (REFOS)”, 11th International Symposium on Concentrated Solar Power and Chemical Energy Technologies. Zürich, Switzerland, September 4-6, 2002.
A. Boudghene Stambouli, Z.Khiat, S.Flazi, Y.Kitamura. “A review on the renewable energy development in Algeria: Current perspective, energy scenario and sustainability issues”. Renewable and Sustainable Energy Reviews, vol 16, pp 4445–4460, 2012.
Michael Geyer. START Mission to Algeria edited by IEA. Report on the Solar PACES; Start Report September 2003.
F. Trieb, C. Schillings, M. O’Sullivan, T. Pregger, C. Hoyer-Klick. Global potential of concentrating solar power. German Aerospace Centre (DLR) 2009.
G. Barigozzi, G. Bonetti, G. Franchini, A. Perdichizzi, S. Ravelli. “Thermal performance prediction of a solar hybrid gas turbine”. Solar Energy, 86, pp 2116–2127, 2012.
Robert Pitz-Paal, Nicolas Bayer Botero, Aldo Steinfeld. “Heliostat field layout optimization for high-temperature solar thermo-chemical processing”. Solar Energy, vol 85; pp 334–343, 2011.
Pierre Garcia, Alain Ferriere, Jean-Jacques Bezian. “Codes for solar flux calculation dedicated to central receiver system applications”. Solar Energy, vol 82, pp 189–197, 2008.
Xiudong Wei, Zhenwu Lu, “A new method for the design of the heliostat field layout for solar tower power plan”t. Renewable Energy, vol 35, pp 1970–1975, 2010.
Matthias russ. Elaboration of thermo-economic models of solar-turbine power plants. Master thesis. Institut für thermische Strömungsmaschinen, May 2011.
John. A. Duffie and William. A. Beckman. Solar engineering of thermal processes, 2nd edition, New York: Wiley (1991).
Chao Xu, Zhifeng Wang, Xin Li, Feihu Sun. “Energy and exergy analysis of solar power tower plants”. Applied Thermal Engineering, vol 31, pp 3904-3913, 2011.
Pouria Ahmadi, Ibrahim Dincer, Marc A. Rosen. “Exergy, exergo-economic and environmental analyses and evolutionary algorithm based multi-objective optimization of combined cycle power plants”. Energy, vol 36, pp 5886-5898, 2011.
V. Siva Reddy, S.C. Kaushik, S.K. Tyagi. “Exergetic analysis of solar concentrator aided natural gas fired combined cycle power plant”. Renewable Energy, vol 39, pp114-125, 2012.
Lukas Feierabend, Thermal model development and simulation of cavity-type solar central receiver systems. Master These. University of Wisconsin Madison, United States., 2009.
TRNSYS16 Tutorial & application; operation guides. TRNSYS STEC 3.0 and TESS available from: http://sel.me.wisc.edu /trnsys/trnlib/ tees/stec.htm.
GE Energy, Gas Turbine Performances Data, 2007.
James Spelling, Thermo-Economic Optimisation of Solar Tower Thermal Power Plants, Ecole Polytechnique Fédérale de Lausanne, Master Thesis 2009
Climatic Condition METEONORM V 7.0.
R. Pitz-Paal, J. Dersch, B. Milow , European Concentrated Solar Thermal Road-Mapping (ECOSTAR), Deutsches Zentrum für Luftund Raumfahrt, Köln, 2004.
K. Lovegrove, W. Stein, Concentrating Solar Power Technology: Principles, Developments and Applications, Woodhead Publishing,Cambridge, 2012.
C.FRANGOPOULOS, “Introduction to Environomics” ASME, AES, vol 191, pp 49-54, 1991.
Peter Schwarzbözl, Reiner Buck, “ Chemi Sugarmen. Solar gas turbine systems: Design, cost and perspectives”. Solar Energy, vol80, pp1231–1240, 2006.
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