论文信息 - Analysis and Control of a Flywheel Energy Storage System With a Hybrid Magnetic Bearing

Analysis and Control of a Flywheel Energy Storage System With a Hybrid Magnetic Bearing

This article presents the design, dynamic analysis, and control of flywheel energy storage system. At the heart of the system is a hybrid magnetic bearing. The bearing consists of ring and disk shaped permanent magnets, and a synthetic ruby sphere on a sapphire plate. The bearing is shown to be stable without active control. Equations of motion for the flywheel are derived in a sensor based coordinate system. The resulting equations are non-singular around the nominal operating condition and are feedback linearizable without the need for a coordinate transformation. A method of modeling rotor imbalance as a set of sinusoidal disturbances of magnitudes that do not depend on rotational speed is also presented. To reject large external disturbances active control is applied to the flywheel. Two nonlinear control laws are applied and are shown to improve the initial condition response of the inherently stable system.

Brian C. Fabien | S. C. Thielman | J. D. Stienmier

[1] Wilson J. Rugh,et al. Gain scheduling dynamic linear controllers for a nonlinear plant , 1995, Autom..

[2] J. A. Kirk,et al. Design and Manufacturing for a Composite Multi-Ring Flywheel , 1992 .

[3] D. H. Curtiss,et al. Advanced composite flywheel structural design for a pulsed disk alternator , 1995 .

[4] Dennis S. Bernstein,et al. Global asymptotic stabilization of the spinning top , 1994 .

[5] Wilson J. Rugh,et al. Analytical Framework for Gain Scheduling , 1990, 1990 American Control Conference.

[6] H. Krauth,et al. Passive axial stabilization of a magnetic radial bearing by superconductors , 1989 .

[7] T. Kane,et al. A Realistic Solution of the Symmetric Top Problem , 1978 .

[8] B. Kaftanoğlu,et al. Mechanical Energy Storage Using Flywheels and Design Optimization , 1989 .