Sage Journals: Discover world-class research

Abstract

Electrodynamic bearings exploit repulsive forces due to eddy currents to produce positive stiffness by passive means. Such a feature would make this type of bearing a viable alternative to active and permanent magnet bearings. Although electrodynamic bearings do not violate Earnshaw’s theorem, the open issue remains the stabilization system that is needed to make the rotating body stable, due to the low rotational speeds. Stabilizing solutions proposed in the literature are partially effective and not totally convincing. This limits real industrial applications.

The present paper proposes a combination of electrodynamic and active magnetic bearings. At low speed the active part behaves as a conventional active magnetic bearing, while at high speed it provides damping. The readiness of the proposed solution is demonstrated by experimental results obtained using a dedicate test rig.

Keywords

Passive levitation electrodynamic bearings rotordynamics magnetic bearings hybrid bearings eddy currents

Get full access to this article

View all access options for this article.

References

Kalita

Garvey

Hill-Cottingham

. Active axial-magnetomotive force parallel-airgap serial flux magnetic bearings. IEEE T Magn 2011; 46(7): 2596–2602.

Bleuler

Cole

Keogh

. Magnetic bearings: Theory, design, and application to rotating machinery. Dordrecht, Heidelberg, London, New York: Springer, 2009.

Post

RF.

Stability issues in ambient-temperature passive magnetic bearing systems. Technical Report, NASA STI/Recon, 2000.

Amati

De Lépine

Tonoli

Modeling of electrodynamic bearings. J Vib Acoust 2008; 130(6): 061007(1)–061007(9).

Filatov

Maslen

EH.

Passive magnetic bearing for flywheel energy storage systems. IEEE T Magn 2001; 37(6): 3913–3924.

Tonoli

Amati

Impinna

. A solution for the stabilization of electrodynamic bearings: Modeling and experimental validation. J Vib Acoust 2011; 133(2): 021004(1)–021004(10).

Vance

Ying

Nikolajsen

. Actively controlled bearing dampers for aircraft engine applications. In: ASME 1999 international gas turbine and aeroengine congress and exhibition, Indianapolis, Indiana, USA, 7–10 June 1999, pp.V004T03A004–V004T03A004.

Tonoli

Amati

Bonfitto

. Design of electromagnetic dampers for aero-engine applications. J Eng Gas Turb Power 2010; 132(11): 112501(1)–112501(11).

Tonoli

Amati

Silvagni

Transformer eddy current dampers for the vibration control. J Dyn Syst-T ASME 2008; 130(3): 031010(1)–031010(9).

10.

Amati

Detoni

Zenerino

. Design methodology of electrodynamic bearings. In: Proceedings of the XXXVIII CONVEGNO NAZIONALE AIAS, Torino, Italy, 9–11 September 2012, pp.1–10.

11.

Amati

Detoni

Impinna

. Model based design of a rotor supported by radial electrodynamic bearings. In: 10th international conference on vibrations in rotating machinery, London, UK, 11–13 September 2012, pp.123–132.

12.

Detoni

JG.

Progress on electrodynamic passive magnetic bearings for rotor levitation. Proc IMechE C-J Mec 2014; 228(10): 1829–1844.

13.

Genta

Dynamics of rotating systems. New York: Springer, 2007.

14.

Detoni

Impinna

Tonoli

. Unified modelling of passive homopolar and heteropolar electrodynamic bearings. J Sound Vib 2012; 331: 4219–4232.

15.

Detoni

Impinna

Amati

. Rotational power loss on a rotor radially supported by electrodynamic passive magnetic bearings. In: Proceedings of the 5th world tribology congress, Torino, Italy, 2013, pp.1–4.

Test and theory of electrodynamic bearings coupled to active magnetic dampers

Abstract

Keywords

Get full access to this article

References