Back-stepping adaptive sliding mode control for flexible self-excitation cage asynchronous generation system

被引：0

作者：

Gu Z.-F. ^{[1
]}

Sun X.-Y. ^{[1
]}

Zhu C.-Q. ^{[2
]}

Liu W.-K. ^{[1
]}

Ge M.-C. ^{[1
]}

Shan S.-L. ^{[1
]}

机构：

[1] School of Electrical and Electronics Engineering, Shijiazhuang Tiedao University, Shijiazhuang, 050043, Hebei

[2] Vehicles and Electrical Engineering Department, Ordnance Engineering College, Shijiazhuang, 050003, Hebei

来源：

Sun, Xiao-Yun (sunxy72@163.com) | 1600年 / South China University of Technology卷 / 37期

基金：

中国国家自然科学基金;

关键词：

Adaptive sliding mode control; Asynchronous generation; Back-stepping adaptive control; Direct power control; EKF orientation; Flexible self-excitation;

D O I：

10.7641/CTA.2019.90021

中图分类号：

学科分类号：

摘要：

In order to suppress the harmonic influence on the voltage orientation of flexible self-excitation cage asynchronous generation system (FS-CAGS), improve the stability control ability and realize the fast power tracking, with extended Kalman filter (EKF) voltage orientation and back-stepping adaptive sliding mode control method, a new EKF voltage oriented back-stepping adaptive sliding mode direct power control method is proposed. Simulation results of FS-CAGS in the military chassis integrated direct current (DC) micro-grid show, comparing with the traditional direct voltage oriented precision feedback linearized robust control method, under the condition of impulse load disturbance and the velocity mutation, the DC output voltage stable speed is fastened and overshoot is reduced, the power tracking speed is improved, current harmonics suppression and robust stability of the FS-CAGS are enhanced. © 2020, Editorial Department of Control Theory & Applications South China University of Technology. All right reserved.

引用

页码：809 / 817

页数：8

共 20 条

[1] Wei S.G., Ma X.J., Ke R.S., Et al., Research on hybrid power system with dual stator-winding and its decoupled control strategy, Journal of China Ordance, 8, 4, pp. 193-199, (2012)
[2] Mesemanolis A., Mademlis C., Kioske Ridis I., Highefficiency control for a wind energy conversion system with induction generator, IEEE Transactions on Energy Conversion, 27, 4, pp. 958-967, (2012)
[3] Zahedi B., Norum L.E., Modeling and simulation of all-electric ships with low-voltage DC hybrid power systems, IEEE Transactions on Power Electronics, 28, 10, pp. 4525-4537, (2013)
[4] Zhuang S., Huang W., Bu F., Et al., Low carrier ratio control of dual-stator winding induction generator for variable frequency AC system, Acta Aeronautica et Astronautica Sinica, 38, 12, pp. 249-259, (2017)
[5] Wei Y., Kang L., Huang Z., Et al., SVC-MERS based voltage control of asynchronous generator set in wind power generation system, Journal of South China University of Technology (Natural Science Edition), 43, 4, pp. 95-103, (2015)
[6] Zhang Y., Wu X., Huang C., Steady-state analysis for isolated three-phase induction generator system with asymmetric loads, Electric Power Automation Equipment, 37, 2, pp. 171-175, (2017)
[7] Gu Z., Zhu C., Shao T., Et al., Backstepping optimal L2-gain control with rapid adaptation of uncertain parameters, Systems Engineering and Electronics, 38, 8, pp. 1909-1916, (2016)
[8] Karimi G.M., Ali K.S., Piraveen K.J., Et al., Problems of startup and phase jumps in PLL systems, IEEE Transactions on Power Electronics, 27, 4, pp. 1830-1838, (2012)
[9] Zheng X., Xiao L., Tian Y., Et al., A control strategy of bidirectional three-phase AC/DC converters without PLL, Proceedings of the CSEE, 33, 36, pp. 79-87, (2013)
[10] Yin C., Wang F., Shi L., Et al., A novel compensation current detection method for APF based on transient voltage space vector orientation, Transactions of China Electrotechnical Society, 32, 7, pp. 112-118, (2017)

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