U-037

Superconductor-Magnet Bearings with Inherent Stability and Velocity-Independent Drag Torque

Authors: Eunjeong Lee (a,b); Ki Bui May (a); Thomas L.Wilson
Affiliation: (a) Texas Center for Superconductivity, University of Houston, Houston, TX
(b) NASA Johnson Space Center, Houston, TX

Abstract
A hybrid superconductor magnet bearing system has been developed based on passive magnetic levitation and the flux pinning effect of high-temperature superconductivity. The rationale lies in the unique capability of a high-temperature superconductor (HTS) to enhance system stability passively without power consumption. Characterization experiments have been conducted to understand its dynamic behavior and to estimate the required motor torque for its driving system design.

These experiments show that the hybrid HTS-magnet bearing system has a periodic oscillation of drag torque due mainly to the nonuniform magnetic field density of permanent magnets. Furthermore, such a system also suffers from a small superimposed periodic oscillation introduced by the use of multiple HTS disks rather than a uniform annulus of HTS material. The magnitude of drag torque is velocity independent and very small. These results make this bearing system appealing for high-speed application. Finally, design guidelines for superconducting bearing systems are suggested based on these experimental results.

Thomas Wilson
NASA, Johnson Space Center
Houston, Texas 77058
thomas.l.wilson1@jsc.nasa.gov