Title :
A Radiation Resistant Dipole Using Metal-Oxide Insulated CICC
Author :
DeLauter, J. ; DeKamp, J.C. ; Zeller, A.F.
Author_Institution :
Michigan State Univ., East Lansing
fDate :
6/1/2007 12:00:00 AM
Abstract :
Several proposed accelerator facilities will be capable of providing intense beams on targets that are in close proximity to superconducting magnets. These magnets will have to operate in high-radiation environments. A proposed solution to the manufacture of radiation tolerant coils is to use a metal-oxide insulated version of the standard CICC, which allows the use of welding to provide structural integrity. A small superferric dipole, similar to one previously constructed with conventional epoxy-potted coils, has been fabricated with metal-oxide CICC. The coils have four turns of 10 mm square conductor having 42 strands of 0.5 mm diameter NbTi wire. The calculated field on the conductor is about 2 T at a current of 10 kA. Test results will be reported and extension to larger devices discussed.
Keywords :
niobium alloys; radiation effects; superconducting coils; superconducting magnets; titanium alloys; welding; NbTi - Interface; accelerator facilities; conventional epoxy-potted coils; current 10 kA; high-radiation environments; intense beams; metal-oxide insulated cable-in-conduit-conductor; radiation resistant dipole; radiation tolerant coils; size 0.5 mm; superconducting magnets; superferric dipole; welding; Accelerator magnets; Conductors; Insulation; Manufacturing; Niobium compounds; Particle beams; Superconducting coils; Superconducting magnets; Titanium compounds; Welding; CICC; dipole; radiation resistant; superconducting magnet;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2007.898189
