COMPARATIVE STUDY OF SINGLE-PHASE PWM RECTIFIER CONTROL TECHNIQUES

Year 2021, Volume: 7 Issue: 1, 44 - 51, 29.06.2021

Evren İşen

https://doi.org/10.22531/muglajsci.870989

Abstract

In this study, 2.5 kW single-phase pulse-width modulated rectifier is simulated with three different control techniques to investigate the performance of controllers. Rectifier simulation is performed in Matlab / Simulink environment by using hysteresis current control, sinusoidal pulse width modulation and voltage oriented control techniques. In the performance comparison of the control techniques, considering the switching frequencies, the total harmonic content of the current drawn from the grid, the phase difference between the grid voltage and the grid current, and the DC bus voltage regulation at the output are considered as comparison criteria. The switching frequency is set to 35 kHz in sinusoidal pulse width modulation and voltage oriented control techniques. Since the switching frequency is variable in the hysteresis current control technique, the average and instantaneous switching frequency are calculated for different hysteresis band values. In the results with the technique, the switching frequency varies between 18.52 kHz and 47.6 kHz, while the average switching frequency is 34.6 kHz. As a result, the total harmonic distortion of the grid current with hysteresis current control, sinusoidal pulse width modulation and voltage oriented control techniques is 3.69%, 1.12% and 1.82%, respectively. The synchronization with the grid voltage is achieved with all techniques, and the DC voltage is regulated with active power.

Keywords

hysteresis current control, Sinusoidal PWM, Rectifier

References

• Pichan, M., Abrishamifar, A., Ahmad, A.A. and Fazeli, M., “Simple and Efficient Design and Control of the Single Phase PWM Rectifier for UPS Applications”, 8th Power Electronics, Drive Systems & Technologies Conference, 2017, 383-388.
• Mansour, M., Mansouri, M.N., Bendoukha, S. and Mimouni, M.F., “A grid-connected variable-speed wind generator driving a fuzzy-controlled PMSG and associated to a fly Wheel energy storage system”, Electric Power Systems Research, Vol. 180, 1-13, 2020.
• Pan, L. and Zhang, C., “Model Predictive Control of a Single-Phase PWM Rectifier for Electric Vehicle Charger”, Energy Procedia, Vol. 105, 4027-4033, 2017.
• Tawfeeq, O.T., Ibrahim, A.Y. and Alabbawi, A.A.M., “Study of a Five-Level PWM Rectifier Fed DC Motor Drive”, 7th International Conference on Electrical and Electronics Engineering, 2020, 126-129.
• Afghoul, H., Krim, F., Chikouche, D. and Beddar, A., “Design and real time implementation of fuzzy switched controller for single phase active power filter”, ISA Transactions, Vol. 58, 614-621, 2015.
• Ilonciak, J., Struharnansky, L. and Kuchta, J., “Modular concept of auxiliary converters for diesel electric locomotives”, Procedia Engineering, Vol. 192, 359-364, 2017.
• Mengi, O., Yanmaz, K. and Altaş, I.H., “STATCOM application with FLC and voltage control on the load in the hybrid model of fuel cell/solar panels system”, Mugla Journal of Science and Technology, Vol. 3 No. 1, 45-50, 2017.
• Kolar, J.W. and Friedli, T., “The Essence of Three-Phase PFC Rectifier Systems-Part I”, IEEE Transactions on Power Electronics, Vol. 28, No. 1, 176-198, 2013.
• Mohan, N. Undeland, T. and Robbins, W., Power Electronics-Converters, Application, and Design. 2nd Edition, John Wiley & Sons, Inc., Canada, 1995.
• McCarty, M., Taufik, T., Pratama, A. and Anwari, M., “Harmonic analysis of input current of single- phase controlled bridge rectifier”, IEEE Symposium on Industrial Electronics & Applications, 2009, 520-524.
• Frisfelds, K. and Krievs, O., “Design of a three-phase bidirectional PWM rectifier with simple control algorithm”, Latvian Journal of Physics and Technical Sciences, Vol. 16, No. 3, 3-12, 2019.
• Cho, Y., Han, Y., Madhusoodhanan, S., Ha, J.I. and Bhattacharya, S., “Synchronous Frame Full-Order Observer Design for Three-Phase Buck-Type PWM Rectifier”, 42nd Annual Conference of the IEEE Industrial Electronics Society, 2016, 3618-3622.
• Sawachan, H., Liutanakul, P. and Wiwatcharagoses, N., “A Simple Dead-Time Compensation Technique for Single-Phase Full-Bridge PWM Rectifier”, 5th International Electrical Engineering Congress, 2017, 1-4.
• Gomes, C. C., Cupertino, A. F. and Pereira H. A., “Damping techniques for grid-connected voltage source converters based on LCL filter: An overview”, Renewable and Sustainable Energy Reviews, Vol. 81, No. 1, 116-135, 2018.
• Pan, D., Ruan, X., Bao, C., Li, W. and Wang, X., “Capacitor-Current-Feedback Active Damping With Reduced Computation Delay for Improving Robustness of LCL-Type Grid-Connected Inverter”, IEEE Transactions on Power Electronics, Vol. 29, No. 7, 3414-3427, 2014.
• He, H., Li, Z., Si, T. and Sun, L., “Research on Digital Phase Locked Method in PWM Rectifier”, IEEE 8th Joint International Technology and Artificial Intelligence Conference, 2019, 1866-1870.
• Zhu, P., Wei, Y., Zheng, Z., Wang, X. and Ma, F., “Fractional Modeling and Simulation for Single-Phase PWM Rectifier”, The Journal of Engineering, Vo. 2019, No. 16, 1675-1688, 2019.
• Komurcugil, H., “Double-band hysteresis current-controlled single-phase shunt active filter for switching frequency mitigation”, Electrical Power and Energy System, Vol. 69, 131-140, 2015.
• Isen, E., “Modelling and Simulation of Hysteresis Current Controlled Single-Phase Grid-Connected Inverter”, International Conference on Electrical and Power Engineering, 2015, 322-326.
• Karafil, H. and Ozbay, H., “Power Control of Single Phase Active Rectifier”, Balkan Journal of Electrical & Computer Engineering, Vol. 7, No. 3, 332-336, 2019.
• Isen, E. and Bakan, F., “Highly efficient three-phase grid-connected parallel inverter system”, Journal of Modern Power Systems and Clean Energy, Vol. 6, 1079-1089, 2018.