DocumentCode
1481619
Title
Development of a Nb3Sn quadrupole magnet model
Author
Devred, A. ; Durante, M. ; Gourdin, C. ; Juster, F.P. ; Peyrot, M. ; Rey, J.M. ; Rifflet, J.M. ; Streiff, F. ; Védrine, P.
Author_Institution
CEA, Centre d´´Etudes Nucleaires de Saclay, Gif-sur-Yvette, France
Volume
11
Issue
1
fYear
2001
fDate
3/1/2001 12:00:00 AM
Firstpage
2184
Lastpage
2187
Abstract
One possible application of Nb3Sn, whose superconducting properties far exceed those of NbTi, is the fabrication of short and powerful quadrupole magnets for the crowded interaction regions of large particle accelerators. To learn about Nb3Sn technology and to evaluate fabrication techniques, DAPNIA/STCM at CEA/Saclay has undertaken an R&D program aimed at designing and building a 1 m-long, 56 mm single-aperture quadrupole magnet model. The model relies on the same coil geometry as the LHC arc quadrupole magnets, but has no iron yoke. It is expected to produce a nominal field gradient of 211 T/m at 11870 A. The coils are wound from Rutherford-type cables insulated with quartz fiber tapes, before being heat-treated and vacuum-impregnated with epoxy resin. Laminated, austenitic collars, locked around the coil assembly by means of keys restrain the Lorentz forces. After reviewing the conceptual design of the magnet model, we report on the cable and cable insulation development programs and we present the results of NbTi-Nb3Sn cable splice tests
Keywords
accelerator magnets; cable insulation; niobium alloys; superconducting cables; superconducting magnets; tin alloys; 1 m; 11870 A; 56 mm; CEA/Saclay; DAPNIA/STCM; Lorentz forces restraint; Nb3Sn; Nb3Sn quadrupole magnet model; NbTi-Nb3Sn cable splice tests; Rutherford-type cables; cable insulation; crowded interaction regions; epoxy resin; fabrication techniques; heat-treatment; laminated austenitic collars; large particle accelerators; quadrupole magnets; quartz fiber tapes; single-aperture quadrupole magnet model; superconducting properties; vacuum-impregnation; Buildings; Cable insulation; Coils; Fabrication; Linear particle accelerator; Magnetic properties; Niobium compounds; Superconducting magnets; Tin; Titanium compounds;
fLanguage
English
Journal_Title
Applied Superconductivity, IEEE Transactions on
Publisher
ieee
ISSN
1051-8223
Type
jour
DOI
10.1109/77.920291
Filename
920291
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