A Review of Parabolic Dish-Stirling Engine System Based on Concentrating Solar Power
Abstract
A solar thermal technology which is also known as concentrating solar power (CSP) uses thermal energy from the sun to generate electricity. The electricity generation from solar thermal can be produced with four technologies of concentrating solar systems which are parabolic trough, linear Fresnel reflector, solar tower, and parabolic dish-Stirling engine system. This paper reviews the parabolic dish-stirling based on CSP technology by taking into account the performance, the global performance, site for parabolic dish and levelized cost of energy (LCOE). Generally, the parabolic dish applications have barriers in terms of the technology and the high capital cost compared to the others CSP technologies.
Full Text:
PDFReferences
Dino. Renewable Green Energy Power. Solar Energy Facts, 2011–2014.
N. Noor and S. Muneer, “Concentrating solar power (CSP) and its prospect in Bangladesh,” in Developments in Renewable Energy Technology (ICDRET), 2009 1st International Conference on the, 2009, pp. 1–5..
Winter C. J., Sizmann R.L., Vant-Hull L.L., Solar Power Plants-Fundamental, Technology, Systems, Economics, Ed. Springer-Verlag, 1991.Yamin L, Wanming C. Implementation of Single Precision Floating Point Square Root on FPGAs. IEEE Symposium on FPGA for Custom Computing Machines. Napa. 2008: 226-232.
Andraka, Charles E. "Alignment Strategy Optimization Method for Dish Stirling Faceted Concentrators."Energy Sustainability 2007. Long Beach, CA, June 27-30.
National Renewable Energy Laboratory. Concentrating Solar Power Projects. November 25, 2013.
D. F. Howard, “Modeling, simulation, and analysis of grid connected dish-stirling solar power plants,” 2010.
Droher, J.J., and S.E. Squier. 1986. Performance of the Vanguard Solar Dish-Stirling Engine Module. EPRI AP- 4608. Palo Alto, CA: Electrical Power Research Insti tute. July 1986.
Washam, B.J., T. Hagen, D. Wells, and W. Wilcox. 1984. Vanguard I Solar Parabolic Dish-Stirling Engine Module, Final Report, May 28, 1982 - September 30, 1984. Advanco Report DOE-AL-16333-2. Advanco Corp., El Segundo, CA. September 1984.
Washam, B.J., T. Hagen, D. Wells, and W. Wilcox. 1984. Vanguard I Solar Parabolic Dish-Stirling Engine Module, Final Report, May 28, 1982 - September 30, 1984. Advanco Report DOE-AL-16333-2. Advanco Corp., El Segundo, CA. September 1984.
Schiel, W. (2007): „Dish Stirling Activities at Schlaich Bergermann und Partner“. SBP.Workshop at NREL March 7, 2007.
SBP (Schlaich Bergermann und Partner). 1991. Solar Power Plant with a Membrane Concave Mirror, SO kW, and Company brochure dated March 1991.
Schertz, D.C. Brown and A. Konnerth III. 1991. Facet Development for a Faceted Stretched-Membrane Dish by Solar Kinetics, Inc. SAND91-7009. Albuquerque, NM: Sandia National Laboratories. July 1991.
Lopez, C.W. and Stone, K.W. 1992. "Design and Performance of the Southern California Edison Stirling Dish," Proceedings of the 1992ASME International Solar Energy Conference, Maui, HI, April 1992. Vol. 2, 945- 952. Eds. W.B. Stine et al. American Society of Mechanical Engineers, New York.
Shaltens, R.K., and J.G. Schreiber. 1990. "Preliminary Designs for 25 kW Advanced Stirling Conversion Systems for Dish Electric Applications," Proceedings of 25th IECEC, Reno, NV, August 1990. Vol. 6, 310-316.
Stone Shaltens, R.K., and J.G. Schreiber. 1991. "Status of the Advanced Stirling Conversion System Project for 25 kW Dish Stirling Applications," Proceedings of 25th IECEC, Reno, NV, August 1990. Vol. 5, 388-394.
Grossman, J.W., R.M. Houser, and W.W. Erdman. 1992. Testing of the Single-Element Stretched-Membrane Dish. SAND91-2203. Albuquerque, NM: Sandia National Laboratories. February 1992.
Schiel, W. (of Schlaich Bergermann und Partner). 1992. Personal communication dated March 1992.
Holtz, R.E., and K.L. Uherka. 1988. A Study of the Reliability of Stirling Engines for Distributed Receiver Systems. SAND88-7028. Albuquerque, NM: Sandia National Laboratories. November 1988.
Kubo, R. (of Cummins Power Generation, Inc.). 1992. Personal communication dated March 1992.
Dussinger, P.M. 1991. "Design, Fabrication and Test of a Heat Pipe Receiver for the Cummins Power Genera tion 5 kW Dish Stirling System," Proceedings of 26th IECEC, Boston, MA, August 1991. Vol. 5, 171.
Stine, W.B. and Diver, R.B. (1994) ‘A compendium of solar dish/Stirling technology’, Report SAND93-7026. Sandia National Laboratories, Albuquerque, NM.
Powell, M.A., and K S. Rawlinson. 1993. "Performance Mapping of the STM4-120 Kinematic Stirling Engine Using a Statistical Design of Experiments Method," Proceedings of 28th IECEC, Atlanta, Georgia, Paper 93282, August 1993. Vol. 2, 639.
SAIC (Science Applications International Corporation). 1991. Facet Development for a Faceted Stretched-Mem brane Dish bySAIC. SAND91-7008. Albuquerque, NM: Sandia National Laboratories. October 1991.
Benninga, K., R. Davenport, J. Sellars, D. Smith, and S. Johansson, Performance Results for the SAICISTM Prototype dish/Stirling System, ASME International Solar Energy Conference, Washington, D. C., 1997.
Tessera Solar, “SunCatcher. The Next Generation of CSP Electricity Generation Technology”.
Schlaich Bergermann und Partner:”EuroDish-Stirling System Description. A new decentralized Solar Power Technology”.
Keck, T. /Schiel, W.: “EnviroDish and EuroDish System and Status”. ISES 2003.
Keith Lovegrove and Wes Stein, “Concentrating solar power technology Principles, developments and applications”. Woodhead Publishing Series in Energy: Number 21.
Peter Brehm, “Concentrating Solar Power Systems Dish Innovation”, VP, Business Development & Government Relations.
Kaneff, S. (1991) The White Cliffs Project-Overview for the period 1979–89. NSW Office of Energy, Sydney, Australia.
Lovegrove, K., Burgess, G. and Pye, J. (2011) ‘A new 500 m2 paraboloidal dish solar concentrator’, Solar Energy, 85 (4), 620–626.
Buck, R., Heller, P. and Koch, H. (1996) ‘Receiver Development for a Dish-Brayton System’, Proc. ASME Int. Solar Energy Conference, San Antonio, TX.
“Concentrating Solar Power: Technologies , Cost , and Performance,” in SunShot Vision study, no. February, 2012, pp. 97–121.
IRENA, “RENEWABLE ENERGY TECHNOLOGIES: COST ANALYSIS SERIES,” 2012.
S. Ahmed, A. Jaber, R. Dixon, M. Eckhart, G. Thompson, and D. Hales, “REN21. 2012. Renewables 2012 Global Status Report,” 2012.
R. Affandi, C. K. Gan, and M. Ruddin Ab. Ghani, “Performance Comparison for Parabolic Dish Concentrating Solar Power in High Level DNI Locations with George Town , Malaysia,” in International Conference and Exhibition on Sustainable Energy and Advanced Material (ICE-SEAM 2013), 2013.
J. Clifton and B. J. Boruff, “Assessing the potential for concentrated solar power development in rural Australia,” Energy Policy, vol. 38, no. 9, pp. 5272–5280, Sep. 2010.
J. T. Hinkley, J. a. Hayward, B. Curtin, A. Wonhas, R. Boyd, C. Grima, A. Tadros, R. Hall, and K. Naicker, “An analysis of the costs and opportunities for concentrating solar power in Australia,” Renew. Energy, vol. 57, pp. 653–661, Sep. 2013.
N. and J. W. Kulichenko, Concentrating Solar Power in Developing Countries Regulatory and Financial Incentives for Scaling Up. Washington, DC: The World Bank, 2012, pp. 1–153.
J. Hinkley, B. Curtin, J. Hayward, A. W. Csiro, R. Boyd, C. Grima, A. Tadros, R. Hall, K. Naicker, A. M. Aurecon, and A. Wonhas, “Concentrating solar power-drivers and opportunities for cost-competitive electricity,” 2011.
N.Benz, “CSP COST ROADMAP,” 2010.
G. Simbolotti, “Concentrating Solar Power,” 2013.
T. Trainer, “Limits to solar thermal energy set by intermittency and low DNI: Implications from meteorological data,” Energy Policy, no. 2011, pp. 18, Sep. 2013.
P. Hearps, D. Mcconnell, and M. Sandiford, “Renewable Energy Technology Cost Review,” 2011.
N. R. Energy, “Grid parity solar : CSP gains on PV,” CSP Today USA 2012, pp. 3–5, 2012.
C. Y. Lau, C. K. Gan, and P. H. Tan, “Evaluation of Solar Photovoltaic Leverized Cost of Energy for PV Grid Parity Analysis in Malaysia,” vol. 4, pp. 28–34, 2014.
DOI: http://doi.org/10.12928/telkomnika.v12i4.1132
Refbacks
- There are currently no refbacks.
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
TELKOMNIKA Telecommunication, Computing, Electronics and Control
ISSN: 1693-6930, e-ISSN: 2302-9293
Universitas Ahmad Dahlan, 4th Campus
Jl. Ringroad Selatan, Kragilan, Tamanan, Banguntapan, Bantul, Yogyakarta, Indonesia 55191
Phone: +62 (274) 563515, 511830, 379418, 371120
Fax: +62 274 564604