Effects of grid disturbances on current source rectifier controlled by FCS-MPC algorithm

• Autorzy: Godlewska A.

Identyfikatory

DOI

10.2478/pead-2018-0019

• Języki publikacji: EN

Abstrakty

EN

Nowadays, the increasing number of non-linear loads influences the grid, causing grid voltage disturbances. These disturbances may be very dangerous for the equipment and can create faults in converter behaviour. However, the right control algorithm can improve the reliability of the work. For a current source rectifier, the finite control set model predictive control has been proposed. This method is very flexible because of the variety of the possible cost function forms. It has been examined under grid voltage disturbed by the higher harmonics and the voltage drop. Simulation results prove the ability to damp the distortions and to ensure the unity power factor. Summing up, the algorithm is a very good solution for use in applications such as battery charging, active power filtering and low-voltage direct current load feeding.

Słowa kluczowe

EN

active front end; current source rectifier; model predictive control; active damping

• Wydawca: De Gruyter
• Czasopismo: Power Electronics and Drives
• Rocznik: 2018
• Tom: Vol. 3 (38), No. 1
• Strony: 11--22
• Opis fizyczny: Bibliogr. 15 poz., rys., tab.

Twórcy

autor

Godlewska A.

• Department of Power Electronics and Electric Drives, Bialystok University of Technology, Białystok, Poland

Bibliografia

• Correa, P., Rodriguez, J., Lizama, I. and Andler, D. (2009). A Predictive Control Scheme for Current-Source Rectifiers, IEEE Transaction on Industrial Electronics, 56(5), pp. 1813-1815.
• Cortes, P., Kouro, S., La Rocca, B., Vargas, R., Rodriguez, J., Leon, J., Vazquez, S.and Franquelo, L. (2009). Guidelines for weighting factors design in model predictive control of power converters and drives. In: IEEE International Conference on Industrial Technology (ICIT), February 2009, Gippsland, Australia, pp. 1-7.
• Falkowski, P., Kulikowski, K. and Grodzki, R. (2017). Predictive and Look-Up Table Control Methods of a Three-Level AC-DC Converter Under Distorted Grid Voltage. Bulletin of Polish Academy of Sciences Technical Sciences, 65(5), pp. 609-618.
• Falkowski, P. and Sikorski, A. (2016). Dead-time compensation in a new FCS-MPC of an AC/DC converter with a LCL filter. In: 13th Selected Issues of Electrical Engineering and Electronics (WZEE 2016), Rzeszow 2016, pp. 1-6.
• Feroura, H., Krim, F., Talbi, B., Laib, A. and Belaout, A. (2017). Finite-Set Model Predictive Direct Power Control of Grid Connected Current Source Inverter. Elektronika ir Elektrotechnika, 23(5), pp. 36-40.
• Godlewska, A., Grodzki, R., Falkowski, P., Korzeniewski, M., Kulikowski, K. and Sikorski, A. (2017). Advanced control methods of DC/AC and AC/DC power converters - look-up table and predictive algorithms. In: J. Kabziński, ed., Advanced Control of Electrical Drives and Power Electronic Converters. Cham: Springer International Publishing, pp. 221-302.
• Ibrahim, A. O. and EL-Fouly, T. H. M. (2009). A Control Method of Grid-Connected PWM Voltage Source Inverters to Mitigate Fast Voltage Disturbances. IEEE Transactions on Power Systems,24(1), pp. 489-491.
• Lammert, G., Heß, T., Schmidt, M., Schegner, P. and Braun, M. (2014). Dynamic grid support in low voltage grids — fault ride-through and reactive power/voltage support during grid disturbances. In: 2014 Power Systems Computation Conference, 18-22 August, Wroclaw, pp. 1-7.
• Li, Y. W., Wu, B., Zargari, N. R., Wiseman, J. C. and Xu, D. (2007). Damping of PWM Current-Source Rectifier Using a Hybrid Combination Approach. IEEE Transaction on Power Electronics, 22(4), pp. 1383-1393.
• Michalík, J., Peroutka, Z. and Šmídl, V. (2016). Finite control set MPC of active current-source rectifier with full state space model. In: Industrial Electronics Society IECON 2015 - 42nd Annual Conference of the IEEE, November 2016, Yokohama, pp. 4121-4126.
• Naguib, M. F. and Lopes, L. A. C. (2009). Minimize Low-Order Harmonics in Low-Switching-Frequency Space-Vector-Modulated Current Source Converters With Minimum Harmonic Tracking Technique. IEEE Transaction on Power Electronics, 24(4), pp. 881-893.
• Noguchi, T. and Sano, K. (2007). Specific harmonic power suppression of direct-power-controlled current-source PWM rectifier. In: 7th International Conference on Power Electronics and Drive Systems (PEDS), 2007, pp. 1436-1441.
• Salo, M. and Tuusa, H. (2000). A Vector Controlled Current-Source PWM Rectifier with a Novel Current Damping Method. IEEE Transaction on Industrial Electronics, 15(3), pp. 464-470.
• Yuan, Z., Zhang, H., Shi, F., Ma, Ch. and Liu, G. (2017). Coupling characteristics and mechanism of the dynamic behaviors of high and low voltage power grid. In: 2nd International Conference on Power and Renewable Energy, 20-23 September 2017, Chengdu, pp. 1007-1012.
• Zavala, P., Rivera, M., Kouro, S., Rodriguez, J., Wu, B., Yaramasu, V., Baier, C., Munoz, J., Espinoza, J. and Melin, P. (2013). Predictive control of a current source rectifier with imposed sinusoidal input currents. In: IECON 2013 - 39th Annual Conference of the IEEE Industrial Electronics Society, 10-13 November 2013, pp. 5842-5847.