Comparative Control Strategy of Asymmetric Bridge Converter for Switched Reluctance Motor
Authors: 
Agus Adhi Nugroho, Bhakti Yudho Suprapto, Zainuddin Nawawi, Muhamad HaddinAuthors Info & Claims
Pages 127 - 131
Abstract
Switched Reluctance Motor has many advantages such as high efficiency, starting torque and reliability, simple construction, robustness, and low maintenance become the best achievement of this motor, but there is still major drawback like large torque ripple, acoustic noise and vibration. This paper present the comparative strategic in controlling of Switched Reluctance Motor using asymmetric bridge converter base on magnetizing-demagnetizing mode and magnetizing-freewheeling mode applied on 6/4 Switched Reluctance Motor using Matlab/Simulink. The comparison between the magnetizing demagnetizing and magnetizing freewheeling started with increasing the turn on angle while keep the turn off angle constant and run the simulation until the highest speed reached, then the turn on angle kept constant while the turn off angle increased until high speed reached. The result of the paper is that the asymmetric bridge converter under magnetization demagnetizing achieve better performance in reaching higher speed, and more efficient since draw the smaller current, and the top speed catch earlier compare to the magnetizing freewheeling mode.
References
[1]
A. Emadi, S. Member, Y. J. Lee, S. Member, and K. Rajashekara. 2008. Power Electronics and Motor Drives in Electric, Hybrid Electric, and Plug-In Hybrid Electric Vehicles. IEEE Trans. Ind. Electron., vol. 55, no. 6, pp. 2237--2245.
[2]
K. T. Chau. 2015. ELECTRIC VEHICLE MACHINES AND DRIVES. JohnWiley & Sons Singapore Pte. Ltd. Registered.
[3]
K. B. Porate. 2015. COMPARATIVE PERFORMANCE ANALYSIS OF SWITCHED RELUCTANCE. Int. J. Electr. Electron. Data Commun., no. June.
[4]
Y. Sozer and D. A. Torrey. 2015. Guidance in Selecting Advanced Control Techniques for Switched Reluctance Machine. IEEE Trans. Ind. Appl., vol. 9994, no. c.
[5]
J. L. Beniwal and S. Member. 2014. Speed Control of SRM Drives using a New Power Converter Configuration in Electric Vehicles. in Australasian Universities Power Engineering Conference, no. October, pp. 1--6.
[6]
S. Yao. 2016. Optimum design of 4 / 3 SRM for Fuel Pump in HEV Considering Output Torque and Vibration. IEEE, no. 2016.
[7]
A. P. Khedkar. 2017. Comparative Study of Asymmetric Bridge and Split AC Supply Converter for Switched Reluctance Motor. Int. Conf. Comput. Power, Energy, Inf. Commun. 522, pp. 522--526.
[8]
H. Eskandari and M. Mirsalim. 2013. An Improved 9 / 12 Two-Phase E-Core Switched. IEEE Trans. ENERGY CONVERSION, vol. 28, no. 4, pp. 951--958.
[9]
S. Riyadi. 2018. A Control Strategy for SRM Drive to Produce Higher Torque and Reduce Switching Losses.pdf. J. Electr. Syst.
[10]
anand. 2015. Analysis and Modeling of Different Types of Converter In Switched Reluctance Motor for Reducing the Torque Ripple. in IEEE Sponsored 2nd International Conference on Innovations in Information Embedded and Communication Systems ICIIECS'15 Analysis.
[11]
R. Krishnan, SWITCHED RELUCTANCE. 2001. Boca Raton London New York Washington, D.C.: CRC Press.
[12]
F. SOARES. 2001. Simulation of a 6 / 4 Switched Reluctance Motor Based on Matlab / Simulink Environment. IEEE Trans. Aerosp. Electron. Syst. VOL. 37, NO. 3 JULY 2001, vol. 37, no. 3, 2001.
[13]
P. Jin-Woo Ahn. 2011. Switched Reluctance Motor. in Intech open, vol. 8, p. 64.
Index Terms
- Comparative Control Strategy of Asymmetric Bridge Converter for Switched Reluctance Motor
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Published In
September 2019
160 pages
ISBN:9781450372145
DOI:10.1145/3362752
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Published: 25 September 2019
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EEET 2019
EEET 2019: 2019 2nd International Conference on Electronics and Electrical Engineering Technology
September 25 - 27, 2019
Penang, Malaysia
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