A NOVEL CURRENT-FED SWITCHED INVERTER WITH COUPLED INDUCTOR FOR LOW VOLTAGE PV APPLICATIONS
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Jun 24, 2018
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The Rеnеwablе Enеrgy Sourcеs such as Wind Energy, Fuel Cell, Uninterruptible Power Supply (UPS) and Solar Photovoltaic (PV) Systems produces DC output. By considering the above energy sources with DC, it is essential to analyze about DC-DC Converters. The DC-DC Boost Converter topologies have the demerits such as power from Renewable Sources are not transferred individually and simultaneously, Poor Electric Isolation, so not suitable for high power application, Complex construction due to more number of components and related gate driver circuits and asymmetrical structure will lead to difficult power flow control. Then, for conversion of low level DC input voltage to high level DC output voltage, Boost Converters are used. It possess continuous operation and better efficiency, due to existence of single switch. The output voltage can be stabilized by proper selection and design of input side Inductor and output side Capacitor. To optimize the performance and efficiency of the system, the correct Inverter has to be selected, for DC-AC Conversion. The coveted properties of an Inverter for efficient AC inversion are elevated Step-up and Step-down competencies and Shoot-through invulnerability. The Inverters are significantly characterized into Current Source Inverter (CSI) and Voltage Source Inverter (VSI). This paper deals with Currеnt Fеd Switchеd Invеrter (CFSI) topology, whereupon, it possess the property of elevated gain in Z-Source Inverter and enervated count o
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[2] Peng, F. Z, Z-source Inverter, In: IEEE Transactions on Industrial Applications (2003), Vol. 39, No. 2, March/April 2003, pp. 504–510.
[3] Kerekes, T., Liserre, M., Teodorescu, R., Klumpner, C. and Sumner, M, Evaluation of three-phase transformerless photovoltaic inverter topologies, In: IEEE Transactions on Power Electronics (2009), Vol. 24, No. 9, September 2009, pp. 2202–2211.
[4] Gonzalez, R., Gubia, E., Lopez, J., Marroyo, L, Transformerless single-phase multilevel-based photovoltaic inverter., In: IEEE Transactions on Industrial Electronics (2008), Vol. 55, No. 7, July 2008, pp. 2694–2702.
[5] Carrasco, J. M., Franquelo, L. G., Bialasiewicz, J. T., Galvan, E., Guisado, R. C. P., Prats, M. A. M., Leon, and N. Moreno-Alfonso J. I, Powerelectronic systems for the grid integration of renewable energy sources: A survey. , In: IEEE Transactions on Industrial Electronics (2006), Vol. 53, No. 4, June 2006, pp. 1002–1016.
[6] Anderson, J., Peng, F.Z, Four Quasi-Z Source Inverters, In: IEEE Power Electronics Specialists Conference, PESC 2008, pp. 2743 - 2749
[7] Mishra, S., Adda, R., Joshi, A, Inverse Watkins-Johnson Topology-Based Inverter., In: IEEE Transactions on Power Electronics (2012), Vol. 27, No. 3, 2012, pp. 1066 - 1070.
[8] Adda, R., Ray, O., Mishra, S., Joshi, A, Synchronous Reference Frame Based Control of Switched Boost Inverter for Standalone DC Nanogrid Applications, In: IEEE Transactions on Power Electronics (2013), Vol. 28, No. 3, 2013, pp. 1219 – 1233.
[9] Ravindranath, A., Mishra, S., Joshi, A, Analysis and PWM Control of Switched Boost Inverter, In: IEEE Transactions on Industrial Electronics (2013), Vol. 60, No. 12, December 2013, pp. 5593-5602.
[10] Wei Qian, Peng, F.Z., Cha, H, Trans-Z Source Inverters, In: IEEE Transactions on Power Electronics (2011), Vol. 26, No. 12, 2011, pp. 3453 - 3463
[11] Soumya Shubhra Nag, Santanu Mishra, Current fed Switched Inverter, In: IEEE Transactions on Industrial Electronics (2014), Vol. 61, No. 9,September 2014
[12] Soumya Shubhra Nag, Ravindranath Adda, Olive Ray, Santanu Mishra, Current-Fed Switched Inverter Based Hybrid Topology for DC Nanogrid Application, In 39th Annual Conference of IEEE Industrial Electronics Society, IECON, 2013, pp.7146-7151.
[13] Adda, R., Ray, O., Mishra, S., Joshi, A, DSP based PWM control of Switched Boost Inverter for DC nanogrid applications., In: Proceedings of the 38th Annual Conference of IEEE Industrial Electronics Society, IECON, 2012 , pp. 5285 – 5290
[14] Yang, S., Peng, F. Z., Lei, Q., Inoshita, R., Qian, Z, Current-fed quasi-z-source inverter with voltage buck-boost and regeneration capability., In: IEEE Transactions on Industrial Electronics (2011), Vol. 47, No. 2, March/April 2011, pp. 882–892.
[15] Qian, W., Peng, F. Z., Cha, H, Trans-Z-source inverters, In: IEEE Transactions on Power Electronics (2011), Vol. 26, No. 12, December 2011, pp. 3453–3463.
[16] Y. Tang, S. Xie, and C. Zhang, Single-phase Z-Source inverter, In: IEEE Transactions on Power Electronics (2011), Vol. 26, No. 12, December 2011, pp. 3869–3873.
[17] Cao, D., Jiang, S., Yu, X., Peng, F. Z, Low-cost semi-Z-source inverter for single-phase photovoltaic systems, In: IEEE Transactions on Power Electronics (2011), Vol. 26, No. 12, December 2011, pp. 3514–3523
[18] Rico, M., Uceda, J., Sebastian, J., Aldana, F, Static and dynamics modeling of tapped-inductor DC-to-DC converters., In: Proceedings of IEEE PESC, 1987, pp. 281–288.
[19] Witulski, A. F, Introduction to modeling of transformers and coupled inductors, In: IEEE Transactions on Power Electronics (1995), Vol. 10, No. 3, May 1995, pp. 349–357.
[20] Ahmed, F., Cha, H., Kim, S., Kim, H., Switched-Coupled-Inductor Quasi-Z-Source Inverter., In: IEEE Transactions on Power Electronics (2016), Vol. 31, No. 2, February 2016 , pp. 1241–1254.
[21] Huang, L., Zhang, M., Hang, L., Yao, W., Lu, Z, A Family of Three-Switch Three-State Single-Phase Z-Source Inverters, In: IEEE Transactions on Power Electronics (2013), Vol. 28, No. 5, May 2013, pp. 2317–2329.
[22] Shen, M., Peng, F. Z., Tolbert. L. M, Multilevel DC-DC power conversion system with multiple DC sources, In: IEEE Transactions on Power Electronics (2008), Vol. 23, No. 1, January 2008, pp. 420–426