Performance Limitations of Non-Laminated Magnetic Suspension Systems

Performance Limitations of Non-Laminated Magnetic Suspension Systems

Limitations on the closed-loop performance of magnetic suspension systems employing electromagnetic actuators that are not constructed from laminations are examined. Eddy currents induced within the iron by time-varying magnetic fields are shown to have a strong effect on the system dynamics and hen...

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Veröffentlicht in:IEEE transactions on control systems technology 2011-03, Vol.19 (2), p.327-336
Hauptverfasser: Knospe, C R, Lei Zhu
Format: Artikel
Sprache:eng
Schlagworte:
Active magnetic bearings
Actuators
Applied sciences
Bandwidth
Bearings, bushings, rolling bearings
Constraint theory
Drives
Dynamical systems
Eddy currents
electromagnetic actuators
electromagnetic suspension
Exact sciences and technology
fractional order systems (FOSs)
Hydraulic actuators
Iron
Lamination
Machine components
Magnetic fields
Magnetic levitation
Magnetic suspension
Mathematical analysis
Mechanical engineering. Machine design
performance limits
Polynomials
Springs and dampers
Suspension systems
Time varying systems
Weight control
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Zusammenfassung:Limitations on the closed-loop performance of magnetic suspension systems employing electromagnetic actuators that are not constructed from laminations are examined. Eddy currents induced within the iron by time-varying magnetic fields are shown to have a strong effect on the system dynamics and hence the achievable performance. To obtain the needed relations, the theory of performance limitations, specifically the sensitivity integral constraint result, is extended to fractional order systems. The unstable pole of the plant and the achievable closed-loop bandwidth are then analytically determined as roots of a quintic polynomial. The results indicate that the required control effort increases as the square of flotor mass for actuators with significant eddy currents, while the relation is linear for laminated actuators.
ISSN:1063-6536
1558-0865
DOI:10.1109/TCST.2010.2044179