Research and Development Status of Magnetic Bearing Technology on Magnetically Suspended Gimballing Flywheel

被引：0

作者：

Liu Q. ^{[1
]}

Zhao M.-S. ^{[1
]}

Han B.-C. ^{[2
]}

Zhang J.-Y. ^{[3
]}

Sun J.-J. ^{[2
]}

Fan Y.-H. ^{[3
]}

机构：

[1] Institute of Precision Electromagnetic Equipment and Advanced Measurement Technology, Beijing Institute of Petrochemical Technology, Beijing

[2] Key Laboratory of Inertial Technology, Beihang University, Beijing

[3] Science and Technology on Space Intelligent Control Laboratory, Beijing Institute of Control Engineering, Beijing

来源：

Yuhang Xuebao/Journal of Astronautics | 2019年 / 40卷 / 11期

关键词：

Inertial actuator; Lorentz force; Magnetic bearing; Magnetic resistance force; Magnetically suspended gimballing flywheel (MSGFW);

D O I：

10.3873/j.issn.1000-1328.2019.11.001

中图分类号：

学科分类号：

摘要：

The current research and future development of the magnetically suspended gimballing flywheel (MSGFW) and high-precision magnetic bearing are expounded. According to the rotor levitation force, MSGFW can be classified as the magnetic resistance force configuration, Lorentz force configuration and hybrid force configuration. Based on the three types of the flywheel configurations above, the development process of MSGFW is discussed. On the basis, the spherical magnetic resistance magnetic bearing and Lorentz magnetic bearing are introduced in detail. Their operating principles are analyzed through using the magnetic circuit maps. The advantages and disadvantages of the magnetic bearings of the same type are compared. Finally, the developing prospect of MSGFW and high-precision magnetic bearing are expected. It points out that the high dynamic response translation spherical magnetic bearing with collocation between detection and control, the standard magnetically suspended momentum sphere and the magnetically suspended control & sensitive sphere will be the primary research directions of MSGFW. © 2019, Editorial Dept. of JA. All right reserved.

引用

页码：1251 / 1261

页数：10

共 34 条

[11] Seddon J., Pechev A., 3-D wheel: a single actuator providing 3-axis control of satellites, Journal of Spacecraft and Rockets, 49, 3, pp. 553-556, (2012)
[12] Yasushi H., Masao I., Norio S., Et al., Development of magnetic bearing momentum wheel for ultra-precision spacecraft attitude control, The 7th International Symposium on Magnetic Bearings, (2000)
[13] Xia Y.-J., Development of magenetic suspended flywheel for satellite, The 11th Nation Conference on Space and Sports Control Technology, (2004)
[14] Wen T., Fang J.C., A feedback linearization control for the nonlinear 5-DOF flywheel suspended by the permanent magnet biased hybrid magnetic bearings, Acta Astronautica, 79, pp. 131-139, (2012)
[15] Zhang J.-Y., Chen Z.-J., Liu H., Active control of multi-frequency vibration caused by displacement sensor runout in magnetic suspension flywheel, Journal of Astronautics, 36, 11, pp. 1289-1295, (2015)
[16] Carabelli S., Genta G., Silyagni M., Et al., Inertia wheel on low-noise active magnetic suspension, Space Technology, 23, 2-3, pp. 105-117, (2003)
[17] Xie Y.C., Sawada H., Hashimoto T., Et al., Actively controlled magnetic bearing momentum wheel and its application to satellite attitude control, (2001)
[18] Saito M., Fukushima K., Sato N., Et al., Development of low disturbance magnetic bearing wheel (MBW) with inclined magnetic poles, Journal of Space Technology and Science, 25, 1, pp. 48-68, (2009)
[19] Chassoulier D., Chillet C., Delamare J., Et al., Ball joint type magnetic bearing for tilting body, (2002)
[20] Gerlach B., Ehinger M., Raue H.K., Et al., Gimballing magnetic bearing reaction wheel with digital controller, The 6th International ESA Conference on Guidance, Navigation and Control Systems, (2005)

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