CERN Accelerating science

002783196 001__ 2783196
002783196 003__ SzGeCERN
002783196 005__ 20211005211158.0
002783196 0247_ $$2DOI$$a10.1109/TASC.2004.829126
002783196 0248_ $$aoai:cds.cern.ch:2783196$$pcerncds:CERN
002783196 035__ $$9https://inspirehep.net/api/oai2d$$aoai:inspirehep.net:663236$$d2021-10-04T13:34:00Z$$h2021-10-05T04:00:06Z$$mmarcxml
002783196 035__ $$9Inspire$$a663236
002783196 037__ $$aFERMILAB-FN-0864-TD
002783196 041__ $$aeng
002783196 100__ $$aFeher, S$$uFermilab
002783196 245__ $$aTest results of shell-type Nb$_3$Sn dipole coils
002783196 260__ $$c2004
002783196 269__ $$c2004
002783196 300__ $$a4 p
002783196 520__ $$9IEEE$$aSeveral different shell type coils were made by using the 'wind-and-react' technique, installed in a mirror magnet configuration and tested at Fermilab. The results revealed that the previously suspect splice technique is adequate and is not responsible for the quench performance limitation. Cable instability is the preferred candidate, however this might be coupled with other effects since all of the experimental results cannot be explained exclusively with cable instability.
002783196 542__ $$dIEEE$$g2004
002783196 6531_ $$9author$$aaccelerator magnets
002783196 6531_ $$9author$$aniobium alloys
002783196 6531_ $$9author$$aquenching (thermal)
002783196 6531_ $$9author$$asplicing
002783196 6531_ $$9author$$astability
002783196 6531_ $$9author$$asuperconducting cables
002783196 6531_ $$9author$$asuperconducting coils
002783196 6531_ $$9author$$asuperconducting magnets
002783196 6531_ $$9author$$aNb3Sn
002783196 6531_ $$9author$$acable instability
002783196 6531_ $$9author$$amirror magnet configuration
002783196 6531_ $$9author$$aquench performance limitation
002783196 6531_ $$9author$$ashell-type dipole coils
002783196 6531_ $$9author$$asplice technique
002783196 6531_ $$9author$$atest results
002783196 6531_ $$9author$$awind-and-react technique
002783196 6531_ $$9author$$aCoils
002783196 6531_ $$9author$$aConducting materials
002783196 6531_ $$9author$$aConductors
002783196 6531_ $$9author$$aMirrors
002783196 6531_ $$9author$$aNiobium
002783196 6531_ $$9author$$aSuperconducting magnets
002783196 6531_ $$9author$$aSuperconducting materials
002783196 6531_ $$9author$$aTesting
002783196 6531_ $$9author$$aTin
002783196 6531_ $$9author$$aVoltage
002783196 6531_ $$9author$$a$hboxNb_
002783196 6531_ $$9author$$aAccelerator
002783196 6531_ $$9author$$ahboxSn$
002783196 6531_ $$9author$$ahigh field dipole
002783196 6531_ $$9author$$amagnet
002783196 690C_ $$aARTICLE
002783196 690C_ $$aCERN
002783196 693__ $$pCERN HL-LHC
002783196 693__ $$aCERN LHC
002783196 700__ $$aAmbrosio, G$$uFermilab
002783196 700__ $$aAndreev, N$$uFermilab
002783196 700__ $$aBarzi, E$$uFermilab
002783196 700__ $$aCarcagno, R$$uFermilab
002783196 700__ $$aChichili, D R$$uFermilab
002783196 700__ $$aKashikhin, V$$uFermilab
002783196 700__ $$aKashikhin, V V$$uFermilab
002783196 700__ $$aLamm, M J$$uFermilab
002783196 700__ $$aOrris, D$$uFermilab
002783196 700__ $$aPischalnikov, Y$$uFermilab
002783196 700__ $$aSylvester, C$$uFermilab
002783196 700__ $$aTartaglia, M$$uFermilab
002783196 700__ $$aTompkins, J C$$uFermilab
002783196 700__ $$aYadav, S$$uFermilab
002783196 700__ $$aYamada, R$$uFermilab
002783196 700__ $$aZlobin, A V$$uFermilab
002783196 773__ $$01370519$$c349-352$$n2$$pIEEE Trans. Appl. Supercond.$$v14$$wC03-10-20.6$$y2004
002783196 960__ $$a13
002783196 962__ $$b600810$$k349-352$$nmorioka20031020
002783196 980__ $$aARTICLE
002783196 980__ $$aConferencePaper