Browse > Article
http://dx.doi.org/10.4283/JMAG.2017.22.2.203

Design and Analysis of Lorentz Force-type Magnetic Bearing Based on High Precision and Low Power Consumption  

Xu, Guofeng (Equipment Academy)
Cai, Yuanwen (Equipment Academy)
Ren, Yuan (Equipment Academy)
Xin, Chaojun (Equipment Academy)
Fan, Yahong (Equipment Academy)
Hu, Dengliang (Equipment Academy)
Publication Information
Journal of Magnetics / v.22, no.2, 2017 , pp. 203-213 More about this Journal
Abstract
Magnetically suspended control & sensitive gyroscope (MSCSG) is a novel type of gyroscope with the integration of attitude control and attitude angular measurement. To improve the precision and reduce the power consumption of Lorentz Force-type Magnetic Bearing (LFMB), the air gap flux density distribution of LFMB has been studied. The uniformity of air gap flux density is defined to qualify the uniform degree of the air gap flux density distribution. Considering the consumption, the average value of flux density is defined as well. Some optimal designs and analyses of LFMB are carried out by finite element simulation. The strength of the permanent magnet is taken into consideration during the machining process. To verify the design and simulation, a high-precision instrument is employed to measure the 3-dimensional magnetic flux density of LFMB. After measurement and calculation, the uniform degree of magnetic flux density distribution reaches 0.978 and the average value of the flux density is 0.482T. Experimental results show that the optimal design is effective and some useful advice can be obtained for further research.
Keywords
Magnetically suspended control & sensitive gyroscope (MSCSG); Lorentz Force-type Magnetic Bearing (LFMB); electromagnetic torque; uniformity;
Citations & Related Records
연도 인용수 순위
  • Reference
1 G. Liu, J. Fang, and J. Liu, Aerospace Control 41, 88 (2008).
2 X. Chen and Y. Ren, Proc IMechE Part C :J. Mechanical Engineering Science 228, 2303 (2014).   DOI
3 J. C. Ji, C. H. Hansen, and A. C. Zander, J. Intell. Mater. Syst. Struct. 19, 1471 (2008).   DOI
4 T. Wei, J. Fang, and Z. Liu, Journal of Mechanical Engineering 46, 159 (2010).
5 J. Fang, S. Zheng, and B. Han, IEEE/ASME Trans. Mechatron. 18, 32 (2013).   DOI
6 Y. Ren and J. Fang, IEEE Trans. Ind. Electron. 59, 4590 (2012).   DOI
7 Y. Ren and J. Fang, IEEE Trans. Ind. Electron. 61, 1539 (2014).   DOI
8 J. Fang, J. Sun, and Y. Fan, Magnetically Suspended Inertial Momentum Wheel Technology, National Defense Industry Press, Beijing (2012) pp. 9-10.
9 Y. Maruyama, M. Takasaki, Y. Ishino, M. Takasaki, T. Ishigami, and H. Kameno, Japan Joint Automatic Control Conference (2006).
10 Y. Maruyama, T. Mizuno, M. Takasaki, Y. Ishino, T. Ishigami, and H. Kameno, Journal of System Design and Dynamics 2, 155 (2008).   DOI
11 S. H. Park and C. W Lee, IEEE/ASME Trans. Mechatron. 10, 618 (2004).
12 L. S. Stephens and D. G. Kim, IEEE Trans. Magn. 38, 1764 (2002).   DOI
13 H. Y. Kim, C. W. Lee, Mechatronics 16, 13 (2006).   DOI
14 B. Xiang and J. Tang, Mechatronics 28, 46 (2015).   DOI
15 N. Kurita, T. Ishikawa, and M. Matsunami, 2009 International Conference on Electrical Machines and Systems, 1 (2009).
16 Y. J. Yu, J. C. Fang, B. Xiang, and C. E. Wang, ISA Trans. 53, 1892 (2014).   DOI
17 J. Abrahamsson, J. Ogren, and M. Hedlund, IEEE Trans. Magn. 50, 1 (2013).
18 B. Liu and J. Fang, Hangkong Xuebao/acta Aeronautica Et Astronautica Sinica 32, 1478 (2011).
19 J. Tang, B. Liu, J. Fang, and S. S. Ge, J. Vib. Control. 19, 1962 (2013).   DOI