Abstract
The purpose of this article is to compare two different control structures which are direct power control (DPC) and sliding mode control based on direct power control with space vector Modulation (DPC-SMC-SVM) for two-levels conversion applications. Finally, we present a study of the robustness of the (SMC-DPC-SVM) in three-phase power supply systems.
The first approach DPC approach has developed to control the active and reactive power from switching table by selecting the optimum value of commutation state.
The second strategy (SMC-DPC-SVM) has been studied widely used applications due to its insensitivity to parameter variations, and robustness against external disturbances. It is shown that DPC-SMC-SVM has several advantaged; good dynamic response, constant chopping frequency.
According to that reason, we will focus on the first-order sliding mode control with a suitable parameter slip surface, which is presented in this paper to control the converter with infinite load. The active filter has the role of compensating for the main types of current disturbances in the power supply systems, it is also recognized that they generate undesirable components, caused by the switching frequency of the converter. Moreover, the variation of the active line filter aims to verify the robustness and efficiency of our order. The main objective of the active filter variation of line, is to check the robustness and the efficiency of our order. However, the performance of this control is verified by the simulation results with the software MATLAB/SIMULINK.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Burlaka, V.V., Gulakov, S.V., Podnebennaya, S.K.: A three-phase high-frequency AC/DC converter with power-factor correction. Elektrotekhnika 4, 43–47 (2017)
Kim, J.-H., Jou, S.-T., Choi, D.-K., Lee, K.-B.: Direct Power Control of Three-Phase Boost Rectifiers by using a Sliding-Mode Scheme, JPE 13-6-9 ISSN(Print): 1598-2092. ISSN(Online): 2093-471
Izanlo, A., Asghar Gholamian, S., Verij Kazemi, M.: Using of four-switch three-phase converter in the structure DPC of DFIG under unbalanced grid voltage condition. Electr. Eng. 100(3), 1925–1938 (2018)
Bouzid, A.M., Guerrero, J.M., Cheriti, A., Bouhamida, M., Sicard, P., Benghanem, M.A.: Survey on control of electric power distributed generation systems for microgrid applications. J. Renew. Sustain. Energy Rev 44, 751–766 (2015) (Elsiever)
Ohnishi, T.: Three phase PWM converter/inverter by means of instantaneous active and reactive power control. In: Proceedings of the International Industrial Electronics and Control Instrumentation, pp. 819–824, Oct/Nov 1991
Hu, J., Zhu, Z.Q.: Investigation on switching patterns of direct power control strategies for grid-connected DC–AC converters based on power variation rates. IEEE Trans. Power Electron. 26(12), 3582–3598 (2011)
Pande, V.N., Mate, U.M., Kurode, S.: Discrete sliding mode control strategy for direct real and reactive power regulation of wind driven DFIG. Electric Power Syst. Res. (2013)
Zoghlami, M., Bacha, F.: Implementation of different strategies of direct power control. In: Proceedings of the 6th International Renewable Energy Congress (IREC 2015), Sousse, Tunisia, 24–26 Mar 2015
Šabanović, A., Fridman, L., Spurgeon, S. (eds.): Variable Structure Systems: From Principles to Implementation. IET Press (2004)
Pinto, S.F., Silva, J.F.: Constant-frequency sliding-mode and PI linear controllers for power rectifiers: a comparison. IEEE Trans. Ind. Electron. 46(1), 39–51 (1999)
Huseinbegovié, S., Peruniþiü-Draženoviü, B.: Discrete-time sliding mode direct power control for three-phase grid connected multilevel inverter. In: 4th International Conference on Power Engineering, Energy and Electrical Drives, Istanbul, Turkey, 13–17 May 2013
Barkat, S., Tlemçani, A., Nouri, H.: Direct power control of the PWM rectifier using sliding mode control. Int. J. Power Energy Convers. 2(4) (2011)
Elnady, A., Al-Shabi, M.: Operation of direct power control scheme in grid-connected mode using improved sliding mode observer and controller. Int. J. Emerg. Electric Power Syst. 20180041 (2018)
Zaimeddine, R., Undeland, T.: Direct power control strategies of a grid-connected three-level voltage source converter VSI-NPC. In: Proceedings of 14th European Conference on Power Electronics and Applications, EPE, pp. 1–6 (2011)
Wong, M.-C., Dai, N.-Y., Lam, C.-S.: Parallel Power Electronics Filters in Three-Phase Four-Wire Systems. Electronics & Electrical Engineering
Zoghlami, M., Bacha, F.: Implementation of different strategies of direct power control. In: 6th International Renewable Energy Congress (IREC’2015). IEEE 978-1-4799-7947-9/15 (IEEE Explore)
Zoghlami, M., Kadri, A., Bacha, F.: Analysis and application of the sliding mode control approach in the variable-wind speed conversion system for the utility of grid connection. Energies 11(4), 720 (2018). ISSN: 1996-1073, Impact Factor: 2.676
Zeng, B., Zou, J.X., Li, K., Xin, X.S.: A novel sliding mode control based low voltage ride through strategy for wind turbine. In Applied Mechanics and Materials, vol. 548–549, pp. 890–894. Trans Tech Publications, Zürich, Switzerland (2014)
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2019 Springer Nature Switzerland AG
About this paper
Cite this paper
Zoghlami, M., Bacha, F. (2019). A Comparative Analysis of DPC and SMC-DPC-SVM Control Approaches in Three-Phase Electrical Power Systems. In: Benavente-Peces, C., Slama, S., Zafar, B. (eds) Proceedings of the 1st International Conference on Smart Innovation, Ergonomics and Applied Human Factors (SEAHF). SEAHF 2019. Smart Innovation, Systems and Technologies, vol 150. Springer, Cham. https://doi.org/10.1007/978-3-030-22964-1_45
Download citation
DOI: https://doi.org/10.1007/978-3-030-22964-1_45
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-22963-4
Online ISBN: 978-3-030-22964-1
eBook Packages: Intelligent Technologies and RoboticsIntelligent Technologies and Robotics (R0)