Title :
Development of radiation-resistant magnet coils for high-intensity beam lines. II. Completely inorganic insulated coils
Author :
Yamanoi, Y. ; Tanaka, K.H. ; Takasaki, M. ; Saito, Y. ; Yahata, K. ; Kato, K. ; Ito, S. ; Iwanaga, K. ; Sinozuka, N. ; Tsukada, S.
Author_Institution :
Dept. of Phys., Nat. Lab. for High Energy Phys., Ibaraki, Japan
fDate :
7/1/1996 12:00:00 AM
Abstract :
For pt. I see IEEE Trans. Magn., vo1.30, p.2511, (1994). We report here on R/D work concerning two types of radiation-resistant magnet coils, which were insulated using completely inorganic materials. Regarding the first coil, the electric insulator employed was a alumina long fiber and a ceramic binder. A new combination of adhesive agent, inorganic filler and alumina long fiber was found, which enabled us to form a strong insulation layer which does not peel off from a copper conductor. The magnet coil for 2000 A excitation current was produced using this insulation method. The second coil is a mineral insulated cable (MIG) with a 3000 A excitation current. This 3000 A-class MIC has been manufactured as a short sample, and was tested concerning its electric insulation both before and after bending
Keywords :
alumina; beam handling equipment; cable insulation; coils; electromagnets; 2000 A; 3000 A; adhesive agent; alumina long fiber; ceramic binder; completely inorganic insulated coils; electric insulation; electric insulator; high-intensity beam lines; inorganic filler; mineral insulated cable; radiation-resistant magnet coils; Cable insulation; Ceramics; Coils; Conducting materials; Copper; Dielectrics and electrical insulation; Inorganic materials; Microwave integrated circuits; Minerals; Optical fiber cables;
Journal_Title :
Magnetics, IEEE Transactions on
