Power Quality Improvement in Variable Speed Drive Systems VSDS with 12-Pulse Rectifier Topology for Industrial Applications
Keywords:
Four-Quadrant Chopper, Variable Speed Drive System VSDS, 12-Pulse Rectifier, Power Quality, Industrial Facilities, Dc-Link.
Abstract
This paper discusses improving the qualifying conditions for feeding grids using four-quadrant chopper in dc-link for a 12-pulse diode bridge rectifier variable speed drive system VSDS. This includes reducing the ripple and crest factors for voltage and current waves in dc-link.
Variable speed drive system with a 12-pulse diode bridge rectifier has been modeled and simulated; the results demonstrating the ability of the proposed chopper to improve power quality in modern industrial facilities were discussed.
KEYWORDS: Four-Quadrant Chopper, Variable Speed Drive System VSDS, 12-Pulse Rectifier, Power Quality, Industrial Facilities, Dc-Link.
References
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[2]. Ertl, H., & Kolar, W., (2005), A constant output current three-phase diode bridge rectifier employing a novel Electronic Smoothing Inductor, Industrial Electronics, IEEE Transactions on, 2005. 52(2): p. 454-461.
[3]. Galea. C., Asiminoaei. L., (2011), New topology of electronic smoothing inductor used in three phase electric drives, Electrical Power Quality and Utilization (EPQU), 2011 11th International Conference on , vol., no., pp.1,6, 17-19 Oct. 2011.
[4]. Gamit. B., Vyas. S, (2018), Harmonic Elimination In Three Phase System By Means Of A Shunt Active Filter, International Research Journal of Engineering and Technology (IRJET).
[5]. Hernadi. Arie., & Anwari. M., (2008), Modeling and Simulation of 6-Pulse and 12-Pulse Rectifiers under Balanced and Unbalanced Conditions with Impacts to Input Current Harmonics, c 2008 IEEE, Second Asia International Conference on Modelling & Simulation
[6]. IEEE, Recommended Practices and Requirements for Harmonic Control in Electrical Power Systems, IEEE Std 519 – 1992.
[7]. Ortiz.A , Hoang. M & Lavoie.C, Modeling and Simulation of a 24-pulse Transformer Rectifier Unit
for More Electric Aircraft Power System ,
[8]. Karuppasamy. I., (2014), Design of Series Active Filter for Power Quality Improvement, research gate 2014.
[9]. Lockley. W., Paes. R., (2014), What's New In Medium Voltage Drives, IEEE Northern Canada & Southern Alberta Sections ;PES/IAS Joint Chapter Technical Seminar What's New with MV Drives & IEEE 1566 - IEEE SAS & NCS 2014.
[10]. Martins. J., Afonso.k., (2014), Shunt active filter for power quality improvement, research gate 2014.
[11]. Modarresi. J., Fallah, M., (2016), Performance improvement of shunt active power filter by a new wavelet-based low-pass filter, Theory and implementation; Sage journals.
[12]. Moyer. T., Harmonics Mandatory Requirements and Premises, Measurement & Analysis of Harmonics & Flicker.
[13]. Nikhil. B., Suhas. M., (2016), Power quality improvement using dual topology of UPQC, IEEE Xplore Digital Library.
[14]. Sar´en. H., Pyrh¨onen. O., & Rauma. K., (2005), Overmodulation in voltage source inverter with small dc-link capacitor, in Proc. IEEE PESC’05, Recife, Brazil, June 2005.
[2]. Ertl, H., & Kolar, W., (2005), A constant output current three-phase diode bridge rectifier employing a novel Electronic Smoothing Inductor, Industrial Electronics, IEEE Transactions on, 2005. 52(2): p. 454-461.
[3]. Galea. C., Asiminoaei. L., (2011), New topology of electronic smoothing inductor used in three phase electric drives, Electrical Power Quality and Utilization (EPQU), 2011 11th International Conference on , vol., no., pp.1,6, 17-19 Oct. 2011.
[4]. Gamit. B., Vyas. S, (2018), Harmonic Elimination In Three Phase System By Means Of A Shunt Active Filter, International Research Journal of Engineering and Technology (IRJET).
[5]. Hernadi. Arie., & Anwari. M., (2008), Modeling and Simulation of 6-Pulse and 12-Pulse Rectifiers under Balanced and Unbalanced Conditions with Impacts to Input Current Harmonics, c 2008 IEEE, Second Asia International Conference on Modelling & Simulation
[6]. IEEE, Recommended Practices and Requirements for Harmonic Control in Electrical Power Systems, IEEE Std 519 – 1992.
[7]. Ortiz.A , Hoang. M & Lavoie.C, Modeling and Simulation of a 24-pulse Transformer Rectifier Unit
for More Electric Aircraft Power System ,
[8]. Karuppasamy. I., (2014), Design of Series Active Filter for Power Quality Improvement, research gate 2014.
[9]. Lockley. W., Paes. R., (2014), What's New In Medium Voltage Drives, IEEE Northern Canada & Southern Alberta Sections ;PES/IAS Joint Chapter Technical Seminar What's New with MV Drives & IEEE 1566 - IEEE SAS & NCS 2014.
[10]. Martins. J., Afonso.k., (2014), Shunt active filter for power quality improvement, research gate 2014.
[11]. Modarresi. J., Fallah, M., (2016), Performance improvement of shunt active power filter by a new wavelet-based low-pass filter, Theory and implementation; Sage journals.
[12]. Moyer. T., Harmonics Mandatory Requirements and Premises, Measurement & Analysis of Harmonics & Flicker.
[13]. Nikhil. B., Suhas. M., (2016), Power quality improvement using dual topology of UPQC, IEEE Xplore Digital Library.
[14]. Sar´en. H., Pyrh¨onen. O., & Rauma. K., (2005), Overmodulation in voltage source inverter with small dc-link capacitor, in Proc. IEEE PESC’05, Recife, Brazil, June 2005.
Published
2019-06-01
How to Cite
Nadweh, S., Hayek, G., & Atieh, B. (2019). Power Quality Improvement in Variable Speed Drive Systems VSDS with 12-Pulse Rectifier Topology for Industrial Applications. Majlesi Journal of Mechatronic Systems, 8(2), 1-6. Retrieved from https://ms.majlesi.info/index.php/ms/article/view/396
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