An improved compact design for a superconducting magnetic suspension and balance system for an 8 ft. x 8 ft. transonic wind tunnel is developed. The original design of an MSBS in NASA Cr-3802 utilized 14 external superconductive coils and a superconductive solenoid in the airplane test model suspended in a wind tunnel. The improvements are in the following areas: test model solenoid options, dynamic force limits on the model, magnet cooling options, structure and cryogenic designs, power supply specifications, and cost and performance evaluations. The improvements are: MSBS cost reduction of 28%, weight; reduction of 43%, magnet system ampere-meter reduction of 38%, helium liquifier capacity reduction by 33%, magnet system stored energy reduction by 55%, AC loss to liquid helium reduced by 76%, system power supply reduced by 68%, test coil pole strength increased by 19%, wing magnetization increased by 40%, and control frequency limit increased by 200% from 10 Hz to 30 Hz. The improvements are due to: magnetic holmium coil forms in the test model, better rare earth permanent magnets in the wings, fiberglass-epoxy structure replacing stainless steel, better coil configuration, and new saddle roll coil design.
[1]
Y. M. Eyssa,et al.
Magnetic suspension and balance system study
,
1984
.
[2]
Takashi Kato,et al.
Development of a 30-kA cable-in-conduit conductor for pulsed poloidal coils
,
1983
.
[3]
F. Arendt,et al.
Field enhancement in superconducting solenoids by holmium flux concentrators
,
1983
.
[4]
S. H. Kim,et al.
Operating Characteristics of a 1.5-MJ Pulsed Superconducting Coil
,
1980
.
[5]
T. Shibata,et al.
Highly heat-resistant Nd-Fe-Co-B system permanent magnets
,
1985
.
[6]
D. H. Nelson,et al.
Field enhancement of a 12.5-T magnet using holmium poles
,
1984
.
[7]
Hisao Yamamoto,et al.
Permanent magnet materials based on the rare earth-iron-boron tetragonal compounds
,
1984
.