[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.4283/JMAG.2013.18.3.302

Thrust Hybrid Magnetic Bearing using Axially Magnetized Ring Magnet

Park, Cheol Hoon (Advanced Manufacturing Systems Research Division, Korea Institute of Machinery and Materials)
Choi, Sang Kyu (Advanced Manufacturing Systems Research Division, Korea Institute of Machinery and Materials)
Ahn, Ji Hoon (Advanced Manufacturing Systems Research Division, Korea Institute of Machinery and Materials)
Ham, Sang Yong (Advanced Manufacturing Systems Research Division, Korea Institute of Machinery and Materials)
Kim, Soohyun (Department of Mechanical Engineering, Korea Advanced Institute of Science and Technology)

Publication Information

Journal of Magnetics / v.18, no.3, 2013 , pp. 302-307 More about this Journal

Abstract

Hybrid-type magnetic bearings using both permanent magnets and electromagnets have been used for rotating machinery. In the case of conventional thrust hybrid magnetic bearings supporting axial loads, radially magnetized permanent ring magnets, which have several demerits such as difficult magnetization and assembly, have been used to generate bias flux. In this study, a novel thrust hybrid magnetic bearing using an axially magnetized permanent ring magnet is presented. Because it is easy to magnetize a ring magnet in the axial direction, the segmentation of the ring magnet for magnetization is not required and the assembly process can be simplified. For verifying the performance of the proposed method, a test rig that consists of a proposed thrust magnetic bearing and variable loads is constructed. This paper presents the detailed design procedures and the obtained experimental results. The results show that the developed thrust magnetic bearing has the potential to replace conventional thrust magnetic bearings.

Keywords

thrust magnetic bearing; ring magnet; axial magnetization;

Citations & Related Records

Reference

1	C. R. Knospe, Control Eng. Pract. 15, 307 (2007). DOI ScienceOn
2	G. Schweitzer, "Applications and research topics for active magnetic bearings," IUTAM Symp. Emerging Trends in Rotor Dynamics, Springer Netherlands, 2011.
3	J. Fang, Y. Le, J. Sun, and K. Wang, IEEE Trans. Magn. 48, 2528 (2012). DOI ScienceOn
4	P. E. Allaire, A. Mikula, B. B. Banerjee, D. W. Lewis, and J. Imlach, J. Franklin Inst. 326, 831 (1989). DOI ScienceOn
5	D. O. Baun, R. L. Fittro, and E. H. Maslen, J. Eng. Gas Turbine Power. 119, 942 (1996).
6	E. H. Maslen, P. E. Allaire, M. D. Noh, and C. K. Sortore, J. Tribol. 118, 839 (1996). DOI ScienceOn
7	Y. H. Fan and A. C. Lee, J. Franklin Inst. 334, 337 (1997). DOI ScienceOn
8	J. Fang, J. Sun, and J. Tang, IEEE Trans. Magn. 46, 4034 (2010). DOI ScienceOn
9	X. D. Lu and D. L. Trumper, Annals of CIRO. 54, 383 (2005). DOI ScienceOn
10	D. C. Han, I. B. Chang, I. H. Park, and Y. H. Park, US Patent 2009/0072644 A1, 2009.
11	C. H. Park, S. K. Choi, and S. Y. Ham, Proceeding of 2011 IEEE Conference on Automation Science and Engineering. (2011) pp. 792-797.
12	S. M. Jang, K. H. Kim, K. J. Ko, J. H. Choi, and S. Y. Sung, J. Appl. Phys. 111, 07E726 (2012). DOI
13	E. Hou and K. Liu, IEEE Trans. Magn. 47, 4725 (2011). DOI ScienceOn

4	Cheol Hoon Park. (2014) Mechanics & Industry Design of magnetic bearings for turbo refrigerant compressors / 15 (4) , 245
12	Cheol Hoon Park. (2015) Transactions of the Korean Society for Noise and Vibration Engineering Development of High Speed Spindle for Machine Tool with Magnetic Bearings / 25 (12) , 895
3	Chaojun Xin. (2016) Journal of Magnetics Modeling and Analysis of Drift Error in a MSSG with Double Spherical Envelope Surfaces / 21 (3) , 356
3	Guochang Bai. (2016) Journal of Magnetics Analysis of Principle and Performance of a New 4DOF Hybrid Magnetic Bearing / 21 (3) , 379