Abstract
High-frequency switching is used to minimize the size and to improve the system performance. Most of the power supplies derived from ac mains source. The rectifier based PWM inverter has front end bridge rectifier with smoothing capacitor. As a result, the input has distorted line current and poor factor. The square wave inverter has non-sinusoidal output current. It affects the system performance and increases the switching loss and reduces the efficiency. All these problems affect the Ozone production and system efficiency. These problems are solved through proposed method. This paper presents the Power Factor Corrected (PFC) converter with parallel resonant inverter based power supply for ozone generator system. The proposed system has active power factor correction converter and Parallel resonant inverter which are used to achieve sinusoidal current and improve the supply power factor and zero-voltage switching across all switches. The active PFC converter with parallel resonant inverter fed ozone generator generates more ozone output compared to the conventional inverter. Thus the proposed system has less switching loss, less current harmonics, and better input power factor compared to the conventional system. The performance of the both inverters are compared and analyzed with the help of simulation results presented in this paper.
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References
Dascalescu L. An introduction to ionized gases. theory and applications. Toyohashi University of Technology; 1993.
Dimitriou MA. Design guidance manual for ozone systems. In: International ozone association (IOA). Pan American Committee; 1990.
Chang JS, Kelly AJ, Crowley JM. Handbook of Electrostatic processes. Marcel Dekker, Inc. 1995.
Alonso JM, Rico-Secades M, Corominas E, Cardesín J, García J. Low-power high-voltage high-frequency power supply for ozone generation.
Kinnares V, Potivejkul S, Rattanavichien P. Design of ozone generator using solar energy. In: IEEE Asia-Pacific conference on circuits and systems; 1998. p. 217–20.
Marcos Alonso J, García J. Analysis, design, experimentation of a high-voltage power supply for ozone generation based on current- fed parallel-resonant push–pull inverter. IEEE Trans Ind Appl. 2005;41:5.
Koudriavtsev O, Wang S, Konishi Y, Nakaoka M. A novel pulse-density modulated high-frequency inverter for silent discharge-type ozonizer. IEEE Trans Ind Appl. 2002;38(2):369–78.
Marcos Alonso J, Cardesin J, Lopez Corominas E, Rico-Secedes M, Garcia J. Low-power high-voltage high-frequency power supply for ozone generation. IEEE Trans Ind Appl. 2004;40(2):414–421.
Hothongkham P, Kinnares V. Performance evaluation of an ozone generator using a phase shift PWM full bridge inverter. In: ECTICON2008; 2008.
Athab HS, Shadhu Khan PK. A cost effective method of reducing total harmonic distortion (THD) in single-phase boost rectifier. In: IEEE Power Electronics and Drive Systems Conference Proceedings, 2007; p. 669–74.
Singh S, Bhuvaneswari G, Singh B, Khas H. Multiple output SMPS with improved input power quality. In: IEEE industrial and information systems (ICIIS) conference proceedings; 2010. p. 382–387. 2010.
Zhu L, Wang K, Lee FC, Lai JS. New start-up schemes for isolated full-bridge boost converters. IEEE Trans Power Electron. 2003;18:946–51.
Cha H, Choi J, Enjeti PN. A three-phase current-fed DC/DC converter with active clamp for low-DC renewable energy sources. IEEE Trans Power Electron. 2008;23:2784–2793.
Adib E, Farzanehfard H. Zero-voltage transition current-fed full-bridge PWM converter. IEEE Trans Power Electron. 2009;24:1041–1047.
Jang Y, Jovanovic MM. A new family of full-bridge ZVS converters. IEEE Trans Power Electron. 2004;19:701–708.
Divan DM, Skibinski GL. Zero switching loss inverters for high power applications. Conf Rec IEEE Ind Appl Soc 1987;1:627–634.
Li H-H, Kutkut NH, Divan DM. Design considerations of IGBT’s in resonant converter applications. IEEE J Solid-State Circuits. 1996;31(1):97–105.
Hothongkham P, Kongkachatand S, Thodsaporn N. Performance comparison of PWM and phase-shifted PWM inverter fed high-voltage high-frequency ozone generator. In: TENCON 2011, IEEE region 10 conference proceedings; 2011. p. 976–80.
Ekemezie PN. Design of a power factor correction AC-DC converter. In: IEEE AFRICON 2007 conference proceedings; 2007. p. 1–8.
Udhayakumar G, Rashmi MR, Patel K, Ramesh GP, Suresh A. High-frequency high-voltage power supply for ozone generator system. Int J Appl Eng Res. 2014;9(23):18913–30.
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Udhayakumar, G., Rashmi, M.R., Patel, K., Suresh, A. (2016). High Efficient Power Supply for Ozone Generator System with Input Power Factor Correction Converter. In: Dash, S., Bhaskar, M., Panigrahi, B., Das, S. (eds) Artificial Intelligence and Evolutionary Computations in Engineering Systems. Advances in Intelligent Systems and Computing, vol 394. Springer, New Delhi. https://doi.org/10.1007/978-81-322-2656-7_111
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DOI: https://doi.org/10.1007/978-81-322-2656-7_111
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