Page 52 - Renewable Energy Devices and System with Simulations in MATLAB and ANSYS
P. 52

Solar Power Sources: PV, Concentrated PV, and Concentrated Solar Power       39


              19.  C. B. Jones, J. S. Stein, S. Gonzalez, and B. H. King, Photovoltaic system fault detection and diagnos-
                tics using Laterally Primed Adaptive Resonance Theory neural network, in Proceedings of IEEE PVSC,
                pp. 1–6, New Orleans, LA, June 2015.
              20.  M. K. Alam, F. Khan, J. Johnson, and J. Flicker, A comprehensive review of catastrophic faults in PV arrays:
                Types, detection, and mitigation techniques, IEEE Journal of Photovoltaics, 5(3), 982–997, May 2015.
              21.  K. A. Kim, G.-S. Seo, B.-H. Cho, and P. T. Krein, Photovoltaic hot-spot detection for solar panel sub-
                strings using AC parameter characterization, IEEE Transactions on Power Electronics, 31(2), 1121–1130,
                February 2016.
              22.  L. M. Fraas and L. D. Partain, Solar Cells and Their Applications, 2nd edn., Hoboken, NJ: Wiley, 2010.
              23.  S. Kurtz, Opportunities and challenges for development of a mature concentrating photovoltaic power
                industry, Technical Report, NREL/TP-5200-43208, National Renewable Energy Laboratory, 2012.
              24.  L. J. Young, Concentrator photovoltaics: The next step towards better solar power,  IEEE Spectrum,
                Online  available:  http://spectrum.ieee.org/energywise/green-tech/solar/concentrator-photovoltaics-the-
                next-step-towards-better-solar-power, August 31, 2015.
              25.  N. Hayashi, A. Matsushita, D. Inoue, M. Matsumoto, T. Nagata, H. Higuchi, Y. Aya, and T. Nakagawa,
                Nonuniformity  sunlight-irradiation  effect  on  photovoltaic  performance  of  concentrating  photovoltaic
                using microsolar cells without secondary optics, IEEE Journal of Photovoltaics, 6(1), 350–357, January
                2016.
              26.  R. J. Linderman, Z. S. Judkins, M. Shoecraft, and M. J. Dawson, Thermal performance of the SunPower
                Alpha-2 PV concentrator, IEEE Journal of Photovoltaics, 2(2), 196–201, April 2012.
              27.  H. Müller-Steinhagen and F. Trieb, Concentrating solar power. A review of the technology, Institute
                of Technical Thermodynamics, German Aerospace Centre, Stuttgart, Germany, February/March 2004.
                Online available, Retrieved on April 13, 2016 at http://www.trec-uk.org.uk/resources/ingenia_18_Feb_
                March_2004.pdf.
              28.  M. Mertins, 2009, Technische und wirtschaftliche Analyse von horizontalen Fresnel-Kollektoren, PhD
                thesis, Universitat Karlsruhe, Karlsruhe, Germany, October 2013, Online, Retrieved on April 13, 2016 at
                http://digbib.ubka.uni-karlsruhe.de/volltexte/documents/1067166.
              29.  M. Bolinger and S. Weaver, 2013, Utility-scale solar 2012: An empirical analysis of project cost, perfor-
                mance, and pricing trends in the United States, Technical Report, Environmental Energy Technologies
                Division, Lawrence Berkeley National Laboratory, Berkeley, CA.
              30.  M. Atif and F. A. Al-Sulaiman, Performance analysis of supercritical CO  Brayton cycles integrated with
                                                                    2
                solar central receiver system, in Proceedings of IEEE IREC, pp. 1–6, Hammamet, Tunisia, 2014.
              31.  C. K. Ho and B. D. Iverson, Review of high-temperature central receiver designs for concentrating solar
                power, Renewable and Sustainable Energy Reviews, 29, 835–846, January 2014.
              32.  Y. Chu, Review and Comparison of Different Solar Energy Technologies, San Diego, CA: Global Energy
                Network Institute, August 2011.
              33.  S. A. Kalogirou, Solar thermal collectors and applications, Progress in Energy and Combustion Science,
                30(3), 231–295, 2004.
              34.  P. Breeze et al., Renewable Energy Focus Handbook, Oxford, U.K.: Academic Press, Elsevier, pp. 333–
                401, 2009.
              35.  D. Laing, W. D. Steinmann, R. Tamme, and C. Richter, Solid media thermal storage for parabolic trough
                power plants, Solar Energy, 80(10), 1283–1289, 2006.
              36.  S. Relloso and Y. Gutierrez, Real application of molten salt thermal storage to obtain high capacity fac-
                tors in parabolic trough plants, in Proceedings of SolarPACES, Las Vegas, NV, 2008.
              37.  M. J. Hale, Subcontractor report: Survey of thermal storage for parabolic trough power plants, Technical
                Report, NREL, National Renewable Energy Laboratory, Golden, CO, 2000.
              38.  A. M. Mohamad, N. Hashim, N. Hamzah, N. F. Nik Ismail, and M. F. Abdul Latip, Transient stability
                analysis on Sarawak’s grid using power system simulator for engineering (PSS/E), in Proceedings of
                IEEE ISIEA, pp. 521–526, Langkawi, Malaysia, September 2011.
              39.  I. D. Margaris et al., Methods for evaluating penetration levels of wind generation in autonomous sys-
                tems, in Proceedings of IEEE Bucharest PowerTech Conference, Bucharest, Romania, June 28–July 2,
                2009.
              40.  N. Hemdan and M. Kurrat, Influence of distributed generation on different loadability aspects of elec-
                tric distributions systems, in Proceedings of 20th International Conference on Electricity Distribution
                (CIRED), Prague, Czech Republic, June 8–11, 2009.
              41.  M. Emranjeet and I. Syed, Stability considerations of distributed power systems with low inertia genera-
                tors, in Proceedings of International Conference on Communication, Conference and Power (ICCCP’07),
                Muscat, Oman, February 19–21, 2007.
   47   48   49   50   51   52   53   54   55   56   57