Robust Sliding Mode Current–Voltage Control Strategy for Single-Phase PWM Rectifiers for Electric Vehicles (EVs)

被引:0
作者
Khalid Sina
Oussama Esfouna
Karim El Khadiri
Ahmed Tahiri
机构
[1] Sidi Mohamed Ben Abdellah University,Laboratory of Computer Science and Interdisciplinary Physics (L.I.P.I), Normal Superior School Fez (E.N.S.F)
[2] Sidi Mohamed Ben Abdellah University,Laboratory of Computer Science, Signals, Automatic and Cognitivism (L.I.S.A.C), Department of Physics, Faculty of Sciences Dhar El Mahraz
来源
Arabian Journal for Science and Engineering | 2023年 / 48卷
关键词
Sliding mode current–voltage control (SMCVC); Rectifier; Power factor (PF); Pulse width modulation (PWM); Active power converter;
D O I
暂无
中图分类号
学科分类号
摘要
Traditional current and voltage strategies proposed for the single-phase rectifier with pulse width modulation (PWM) used in the AC charging system for electric vehicles, have a large response time and the percentage of total harmonic distortion (THD) of the line current is more than 2%, which causes a reduction of the power factor (PF). The present paper focuses on the robust sliding mode current–voltage control (SMCVC) design for the single-phase rectifier with PWM. This SMCVC strategy used the grid current directly without any rotating coordinate transformations and reduced the complexity computational of the implementation algorithm and allows to satisfy the following desired performances, low THD of the input current and the PF is around one in a faster response time. In this paper, the proposed control strategy is compared and verified with proportional integral (PI) control and proportional integral sliding mode current control (PI-SMCC) by Matlab/Simulink. At the end of this paper, simulation examples are given to illustrate our approach and to show that our proposed method provides very good results with respect to some literature results.
引用
收藏
页码:14493 / 14500
页数:7
相关论文
共 62 条
[1]  
Ozdemir S(2014)Single stage three level grid interactive MPPT inverter for PV systems Energy Convers. Manag. 80 561-572
[2]  
Altin N(2012)Comprehensive topological analysis of conductive and inductive charging solutions for plug-in electric vehicles IEEE Trans. Veh. Technol. 61 3475-3489
[3]  
Sefa I(2014)Vehicle-to-grid reactive power operation using plug-in electric vehicle bidirectional offboard charger IEEE Trans. Ind. Electron. 61 6778-6784
[4]  
Khaligh A(2017)Model predictive control of a single-phase PWM rectifier for electric vehicle charger Energy Procedia. 105 4027-4033
[5]  
Dusmez S(2018)Control of a single-phase cascaded H-bridge active rectifier under unbalanced load IEEE Trans. Power Electron. 33 5519-5527
[6]  
Kesler M(2013)Active power decoupling for high-power single-phase PWM rectifiers IEEE Trans. Power Electron. 28 1308-1319
[7]  
Kisacikoglu MC(2021)Model predictive current control with fixed switching frequency and dead-time compensation for single-phase PWM rectifier Electronics 10 426-9681
[8]  
Tolbert LM(2012)Constrained model predictive control strategy for single-phase switch-mode rectifiers IET Power Electron. 5 31-2651
[9]  
Pan L(2015)A simple model predictive power control strategy for single-phase PWM converters with modulation function optimization IEEE Trans. Power Electron. 68 9672-45060
[10]  
Zhang C(2019)An improved deadbeat control method for single-phase PWM rectifiers in charging system for EVs IEEE Trans. Veh. Technol. 68 2640-1191
1234567