Analysis of Control Strategy of Three-phase Bridge Fully Controlled Rectifier Circuit Based on PID Control

Zhao Yao

doi:10.54097/hset.v17i.2623

Authors

Zhao Yao

DOI:

https://doi.org/10.54097/hset.v17i.2623

Keywords:

Three-phase bridge fully controlled rectifier circuit; PID controller; IGBT; Trigger angle; Closed-loop control

Abstract

At the present stage of industrial production in China, rectifier circuits still have an important position, and their safe, reliable, and efficient operation is still a necessary issue to be explored in the development of power electronics technology. Therefore, this paper will build an improved three-phase bridge rectifier circuit based on the traditional three-phase bridge fully controlled rectifier circuit, replacing the thyristor with an insulated gate bipolar transistor (IGBT) under the same basic principle, so that it can be more easily controlled by industrial intelligence. The PID controller is introduced to make the output voltage of the rectifier circuit gradually converge to a certain value by continuously correcting the calculation of the trigger angle α and the calculation of the voltage and current values. The simulation results show that the PI-controlled three-phase bridge fully controlled rectifier circuit model established in the paper makes the output of the circuit eventually stabilize under the influence of the closed-loop control, and the simulation results reach the expected value and show strong robust stability. For industrial applications, improving the safety, reliability, efficiency, and flexibility of bridge rectifier circuits is of good reference in practical engineering applications.

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References

Yin Zhaosheng. Application of time-optimal PID control algorithm in power regulation of hydropower plant monitoring system [J]. Wireless Interconnection Technology, 2022,5(3):108-110.

Wu Xuhui, Lai Jinglin, Guo Rui-Kun, et al. Application of motor PID closed-loop system on intelligent trolley[J]. Physics Bulletin,2019(11):123-125+128.

Liu Xiaoxia,Sun Kangbo. Application of automation process control to PID control method and its parameter adjustment strategy[J]. Electrical Switching,2015,53(01):86-87+91.

Guan X, Nanhai P, Wang Y. Application of PI-PD control in wind and water microgrid [J]. High Voltage Technology,2019,45(07):2177-2184.

Cui JRS, Li QING, Zhang B, et al. Adaptive fuzzy PID control of permanent magnet synchronous motor with variable theory domain[J]. Chinese Journal of Electrical Engineering,2013,33(S1):190-194.

Geng Xefeng, He Eddie Ze, Li Mengchuan, et al. Overview of IGBT multi-physics field modeling techniques and application research [J]. Chinese Journal of Electrical Engineering,2022,42(01):271-290.

Meng Zhuo, Chai Yu. Simulation study of three-phase bridge fully controlled rectifier circuit based on Matlab/Simulink[J]. Electronic Testing,2018(Z1):56-57.

Niu Huifang,Meng Qing,Pang Liying. Fault diagnosis of three-phase bridge fully controlled rectifier circuit based on RBF network[J]. Journal of Inner Mongolia University (Natural Science Edition),2019,50(02):212-217.

Wen, Cambridge. Research on the design of power factor correction control strategy for three-phase rectifier circuit [D]. Harbin Engineering University,2020.

Zhang Hongyong,Fang Jun. Analysis of three-phase bridge fully controlled rectifier DC power supply control circuit design[J]. Power Technology,2014,38(11):2171-2173+2187.

Sun Xiuhua. Working principle, characteristics, and precautions of IGBT module [J]. Agricultural Science and Technology and Equipment,2009(05):54-55+58.

Wang ZAOAN, Liu JIN. Power Electronics Technology [M].5th ed. Beijing: Machinery Industry Press, 2009.