Implementation of PFC Converter fed DC Drive

R. Anushya *, Raja Prabu**
* Research Scholar, Sathyabama University, Chennai, India.
** Professor & Head, EEE Department. BSA Crescent University, Chennai, India.
Periodicity:April - June'2011
DOI : https://doi.org/10.26634/jee.4.4.1461

Abstract

In this paper, a systematic review of bridgeless power factor correction (PFC) boost rectifiers, also called dual boost PFC rectifiers, is presented. Simulation and analysis of bridgeless converter with motor load with its various performance characteristics are provided.

Keywords

Power Factor Correction,Diode, Rectifier, Boost Converter

How to Cite this Article?

R. Anushya and Raja Prabu (2011). Implementation of PFC Converter Fed DC Drive. i-manager’s Journal on Electrical Engineering, 4(4), 31-36. https://doi.org/10.26634/jee.4.4.1461

References

[1]. D.M. Mitchell, (1983). "AC-DC Converter having an improved power factor ",U.S. Patent ,412,277, Oct. 25,
[2]. A. F. Souza and I. Barbi, (1999). “High power factor rectifier with reduced conduction and commutation losses,” in Proc. Int. Telecommunication Energy Conf., Jun. pp. 8.1.1–8.1.5.
[3]. T. Ernö and M. Frisch, (2004). “Second generation of PFC solutions,” in Proc. Power Electronics Europe, No. 7, pp. 33–35.
[4]. D. Tollik and A. Pietkiewicz, (1992). “Comparative analysis of 1-phase active power factor correction topologies,” in Proc. Int. Telecommunication Energy Conf., Oct. pp. 517–523.
[5]. J. Liu, W. Chen, J. Zhang, D. Xu, and F. C.Lee, (2001). “Evaluation of power losses in different CCM mode singlephase boost PFC converters via simulation tool,” in Rec. IEEE Industry Applications Conf., Sep, pp.2455–2459.
[6]. H. Ye, Z. Yang, J. Dai, C. Yan, X. Xin, and J. Ying, (2004). “Common mode noise modeling and analysis of dual boost PFC circuit,” in Proc. Int. Telecommunication Energy Conf., Sep., pp. 575–582.
[7]. B. Lu, R. Brown, and M. Soldano, (2005). “Bridgeless PFC implementation using one cycle control technique,” in Proc. IEEE Applied Power Electronics Conf., Mar., pp. 812–817.
[8]. P. Kong, S.Wang, and F.C. Lee, (2006). “Common mode EMI noise suppression in bridgeless boost PFC converter,” in Proc. CPES Power Electronics Conf., Apr., pp. 65–70.
[9]. J.C. Salmon, (1992). “Circuit topologies for singlephase voltage-doubler boost rectifiers,” in Proc. IEEE Applied Power Electronics Conf.,Mar., pp. 549–556.
[10]. P. N. Enjeti and R. Martinez, (1993). “A high performance single phase AC to DC rectifier with input power factor correction,” in Proc. IEEE Applied Power Electronics Conf., Mar., pp. 190–195.
[11]. A.F. Souza and I. Barbi, (1995). “A new ZCS quasiresonant unity power factor rectifier with reduced conduction losses,” in Proc. IEEE Power Electronics Specialists Conf., Jun., pp. 1171–1177.
[12] A.F. Souza and I. Barbi, (1995). “A new ZVSPWM unity power factor rectifier with reduced conduction losses,” IEEE Trans. Power Electron.,Vol. 10, No. 6, pp. 746–752, Nov.
[13] R. Martinez and P.N. Enjeti, (1996). “A high performance single phase AC to DC rectifier with input power factor correction,” IEEE Trans. Power Electron., Vol. 11, No. 2, pp. 311–317, Mar.
[14] A.F. Souza and I. Barbi, (1999). “A new ZVS semiresonant high power factor rectifier with reduced conduction losses,” IEEE Trans. Ind. Electron., Vol. 46, No. 1, pp. 82–90, Feb.
[15]. J.-W. Lim and B.-H. Kwon, (1999). “A powerfactor controller for singlephase PWM rectifiers,” IEEE Trans. Ind. Electron., Vol. 46, No. 5, pp.1035–1037, Oct.
[16]. U. Moriconi, (2002). “A bridgeless PFC configuration based on L4981 PFC controller,” Application Note AN 1606, STMicroelectronics 1/18–18/18 Nov.
[17]. C.M. Wang, (2003). “A novel zero-voltage switching PWM boost rectifier with high power factor and low conduction losses,” in Proc. Int. Telecommunication Energy Conf., Oct., pp. 224–229.
[18]. F.K.A. Lima, C.M.T. Cruz, and F.L.M. Antunes, (2004). “A family of turn-on and turn-off nondissipative passive snubbers for soft-switchingsingle-phase rectifier with reduced conduction losses,” in Proc. IEEE Power Electronics Specialists, Jun. ,pp. 3745–3750.
[19]. C. M. Wang, (2005). “A novel ZCS PWM power factor preregulator with reduced conduction losses,” IEEE Trans. Ind. Electron., Vol. 52,No. 3,pp. 689–700, Jun.
[20] W.-Y. Choi, J.-M. Kwon, E.-H. Kim, J.-J.Lee, and B.-H. Kwon, (2007). “Bridgeless boost rectifier with low conduction losses and reduced diode reverse-recovery problems,” IEEE Trans. Ind. Electron., Vol. 54, No. 2, pp. 769–780, Apr.
[21]. J.C. Salmon, (1995). “Circuit topologies for PWM boost rectifiers operated from 1-phase and 3-phase ac supplies and using either single or split dc rail voltage outputs,” in Proc. IEEE Applied Power Electronics Conf.,Mar.,pp. 473–479.
[22]. A. F. Souza and I. Barbi, (1999). “High power factor rectifier with reduced conduction and commutation losses,” in Proc. Int. Telecommunication Energy Conf., Jun., pp. 8.1.1–8.1.5.
[23]. T. Ernö and M. Frisch, (2004). “Second generation of PFC solutions,” in Proc. Power Electronics Europe,, No. 7, pp. 33–35.
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