IMPLEMENTATION OF VIENNA RECTIFIER WITH SLIDING MODE CONTROL FOR ELECTRIC VEHICLE CHARGING STATIONS

Authors

  • BANUMALAR KOODALSAMY Department of EEE, Mepco Schlenk Engineering College, Sivakasi, India. Author
  • VANAJA NARAYANASWAMY Department of EEE, Mepco Schlenk Engineering College, Sivakasi, India. Author
  • KARTHIKEYAN KRISHNAMOORTHY Department of EEE, Ramco Institute of Technology, Rajapalayam, India. Author
  • BHUVANESH ANANTHAN Department of EEE, PSN College of Engineering and Technology, Tirunelveli, India. Author

DOI:

https://doi.org/10.59277/RRST-EE.2024.69.4.10

Keywords:

Electric vehicle, Charging station, Sliding mode control (SMC), Power factor, Harmonics

Abstract

This work recommends using an electric vehicle (EV) charging station employing a Vienna rectifier (VR) with sliding mode control. The Vienna rectifier is preferred for high-power applications due to its reduced harmonic distortion and improved power factor correction. Sliding mode control is used to regulate the rectifier's output voltage and current, allowing for reliable and efficient charging of EVs. The suggested system is modeled, and the simulation outcomes are presented to demonstrate the value of the recommended approach concerning stability, strength, and unexpected responsiveness. The proposed technology is expected to contribute to developing more dependable and effective EV charging stations.

References

(1) M.H. Islam. M.A. Razzak, Power factor correction for single phase loads using modified Vienna rectifier, 3rd International Conference on Electrical Engineering and Information Communication Technology (ICEEICT), pp. 1–6 (2016).

(2) H. Komurcugil, S. Ozdemir, I. Sefa, N. Altin, O. Kukrer, Sliding-mode control for single-phase grid-connected $mbox{LCL}$-filtered VSI With double-band hysteresis scheme, IEEE Transactions on Industrial Electronics, 63, pp. 864–873 (2016).

(3) G. Rubio-Astorga, J.D. Sánchez-Torres, J. Cañedo, A.G. Loukianov, High-order sliding mode block control of single-phase induction motor, IEEE Transactions on Control Systems Technology, 22, pp. 1828–1836 (2014).

(4) A. Mallik, J. Lu, A. Khaligh, Sliding mode control of single-phase interleaved totem-pole PFC for electric vehicle onboard chargers, IEEE Transactions on Vehicular Technology, 67, pp. 8100–8109 (2018).

(5) A.N. Arvindan, D.K. Akshay, E. Siby, K.M. Keerthana, Efficacy of hysteresis current control in the single-phase Vienna rectifier topologies for improved power quality, International Conference on Power and Embedded Drive Control (ICPEDC), pp. 318–325 (2017).

(6) S. A. Shaon, K.M.A. Salam, Study of Vienna rectifier and a highly efficient single phase two stage inverter with low THD, 8th International Conference on Electrical and Computer Engineering, pp. 619–622 (2014).

(7) U.K. Shinde, S.G. Kadwane, S.P. Gawande, M.J.B. Reddy, D.K. Mohanta, Sliding mode control of single-phase grid-connected quasi-Z-Source Inverter, IEEE Access, 5, pp. 10232–10240 (2017).

(8) S. Hou, J. Fei, Y. Chu, C. Chen, Experimental investigation of adaptive fuzzy global sliding mode control of single-phase shunt active power filters, IEEE Access, 7, pp. 64442-64449 (2019).

(9) B. Guo, M. Su, Y. Sun, H. Wang, H. Dan, Z. Tang, B. Cheng, A robust second order sliding mode control for single-phase photovoltaic grid-connected voltage source inverter, IEEE Access, 7, pp. 53202–53212 (2019).

(10) U.K. Kalla, B. Singh, S.S. Murthy, C. Jain, K. Kant, adaptive sliding mode control of standalone single-phase microgrid using hydro, wind, and solar PV array-based generation, IEEE Transactions on Smart Grid, 9, pp. 6806–6814 (2018).

(11) A. Kumar, D. Sarkar, P.K. Sadhu, power quality improvement in induction heating system using Vienna rectifier based on hysteresis controller, Electric Power Components and Systems, 48, pp. 892–905 (2020).

(12) J. Fei, Y. Chen, Fuzzy double hidden layer recurrent neural terminal sliding mode control of single-phase active power filter, IEEE Transactions on Fuzzy Systems, 29, pp. 3067–3081 (2021).

(13) A. Arpadžić, A. Bosović, A. Merzić, M. Musić, Impacts of deregulated and regulated electric vehicle charging in a distribution network, Rev. Roum. Sci. Techn. – Électrotechn. Et Énerg., 67, 4, pp. 451-456 (2022).

(14) D. Ziane, A. Azib, A. Oubelaid, N. Taib, T. Rekioua, D. Rekioua, Proposed power factor correction circuit based on the single-ended primary-inductor converter controlled by sliding mode control strategy used in an electric vehicle charging station, Rev. Roum. Sci. Techn. – Électrotechn. Et Énerg., 67, 3, pp. 241–245 (2022).

Y. Yuan, Z. Zhang, A single-phase Vienna rectifier with wide output Voltage Range, IEEE Transactions on Transportation Electrification, 8, pp. 3884–3895 (2022).

Downloads

Published

05.11.2024

Issue

Vol. 69 No. 4 (2024): RRST-EE

Section

Électronique et transmission de l’information | Electronics & Information Technology

License

Copyright (c) 2024 REVUE ROUMAINE DES SCIENCES TECHNIQUES — SÉRIE ÉLECTROTECHNIQUE ET ÉNERGÉTIQUE

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

How to Cite

IMPLEMENTATION OF VIENNA RECTIFIER WITH SLIDING MODE CONTROL FOR ELECTRIC VEHICLE CHARGING STATIONS. (2024). REVUE ROUMAINE DES SCIENCES TECHNIQUES — SÉRIE ÉLECTROTECHNIQUE ET ÉNERGÉTIQUE, 69(4), 425-430. https://doi.org/10.59277/RRST-EE.2024.69.4.10