002674338 001__ 2674338
002674338 003__ SzGeCERN
002674338 005__ 20220817145929.0
002674338 0247_ $$2DOI$$9IEEE$$a10.1109/TASC.2018.2809561
002674338 0248_ $$aoai:inspirehep.net:1674815$$pcerncds:CERN$$qINSPIRE:HEP$$qForCDS
002674338 035__ $$9http://inspirehep.net/oai2d$$aoai:inspirehep.net:1674815$$d2019-05-13T13:54:28Z$$h2019-05-14T04:02:55Z$$mmarcxml
002674338 035__ $$9Inspire$$a1674815
002674338 041__ $$aeng
002674338 100__ $$aStatera, Marco$$jORCID:0000-0003-3529-913X$$uINFN, Milan
002674338 245__ $$9IEEE$$aConstruction and Cold Test of the Superferric Octupole for the LHC Luminosity Upgrade
002674338 260__ $$c2018
002674338 300__ $$a5 p
002674338 520__ $$9IEEE$$aINFN is developing the prototypes of five corrector magnets, from skew quadrupole to dodecapole, which will equip the high-luminosity interaction regions of the high luminosity-LHC (HL-LHC) at LASA lab (Milano, Italy). These magnets are based on a superferric design, which allows a relatively simple, modular, and easy to construct magnet. This activity takes place within the framework of a collaboration agreement between CERN and INFN. The first prototype, a sextupole, has been tested in 2016. We present here the results of the cold tests of the octupole, including the training performed at 4.2 K and the qualification at 2.17 K, that has been assembled and tested in 2017. We report also on the overall experience gained during constructions and tests and the improvements toward the series production. Other important results concern inductance measurements and quench studies.
002674338 65017 $$2SzGeCERN$$aAccelerators and Storage Rings
002674338 6531_ $$9author$$aSuperconducting magnets
002674338 6531_ $$9author$$aCoils
002674338 6531_ $$9author$$aTraining
002674338 6531_ $$9author$$aMagnetic flux
002674338 6531_ $$9author$$aIron
002674338 6531_ $$9author$$aInsulation
002674338 6531_ $$9author$$aPrototypes
002674338 6531_ $$9author$$aHI-lumi
002674338 6531_ $$9author$$amultipole
002674338 6531_ $$9author$$amagnet training
002674338 6531_ $$9author$$asuperconducting coils
002674338 6531_ $$9author$$asuperconducting magnet
002674338 6531_ $$9author$$asuperferric magnet
002674338 6531_ $$9author$$atest facility
002674338 690C_ $$aCERN
002674338 693__ $$pCERN HL-LHC
002674338 700__ $$aAlessandria, Franco$$uINFN, Milan
002674338 700__ $$aBroggi, Francesco$$uINFN, Milan
002674338 700__ $$aLeone, Augusto$$uINFN, Milan
002674338 700__ $$aMarinozzi, Vittorio$$jORCID:0000-0002-2098-8963$$uINFN, Milan
002674338 700__ $$aMariotto, Samuele$$jORCID:0000-0003-1801-4534$$uINFN, Milan
002674338 700__ $$aPaccalini, Antonio$$uINFN, Milan
002674338 700__ $$aPedrini, Danilo$$uINFN, Milan
002674338 700__ $$aQuadrio, Mauro$$uINFN, Milan
002674338 700__ $$aSorbi, Massimo$$jORCID:0000-0003-3333-1589$$uINFN, Milan
002674338 700__ $$aTodero, Maurizio$$uINFN, Milan
002674338 700__ $$aUva, Carlo$$uINFN, Milan
002674338 700__ $$aFessia, Paolo$$uCERN
002674338 700__ $$aMusso, Andrea$$jORCID:0000-0002-1688-7561$$uCERN
002674338 700__ $$aTodesco, Ezio$$jORCID:0000-0001-5518-4191$$uCERN
002674338 773__ $$c4008705$$n4$$pIEEE Trans. Appl. Supercond.$$v28$$wC17-09-17$$y2018
002674338 960__ $$a13
002674338 962__ $$b2256109$$k4008705$$ngeneva20170917
002674338 980__ $$aARTICLE
002674338 980__ $$aConferencePaper
002674338 999C6 $$a0-0-0-1-0-0-1$$t2019-05-13 11:08:25$$vInvenio/1.1.2.1260-aa76f refextract/1.5.44
002674338 999C5 $$9CURATOR$$hP. Abramian et al.$$o1$$sIEEE Trans.Appl.Supercond.,23,4101204$$tDevelopment of superconducting corrector magnets with hard radiation resistance for LHC upgrade$$y2013
002674338 999C5 $$9CURATOR$$hG. Volpini et al.$$o2$$sIEEE Trans.Appl.Supercond.,25,4002605$$tNbTi superferric corrector magnets for the LHC luminosity upgrade$$y2015
002674338 999C5 $$9CURATOR$$hM. Giovannozzi, S. Fartoukh, and R. De Maria$$o3$$sProc.4th Int.Particle Accelerator Conf., Shanghai, China, pp.2612-2614$$tSpecification of a system of correctors for the triplets and separation dipoles of the LHC Upgrade
002674338 999C5 $$hF. R. Mateos et al.$$mEDMS document no. 90327, Oct.. [Online]. Available:$$o4$$tVoltage withstand levels for electrical insulation testson components and bus bars cross section for the different LHC machine circuits$$uhttps://edms.cern.ch/ui/file/90327/2.0/LHC-PM-ES-0001-20-00.pdf$$y2004
002674338 999C5 $$9CURATOR$$hE. Todesco et al.$$o5$$sIEEE Trans.Appl.Supercond.,24,4003305$$tA first baseline for the magnets in the high luminosity LHC insertion regions$$y2014
002674338 999C5 $$9CURATOR$$hG. Volpini et al.$$o6$$sIEEE Trans.Appl.Supercond.,26,4004804$$tDevelopment of the superferric sextupole correctormagnet for the LHC luminosity upgrade$$y2016
002674338 999C5 $$9CURATOR$$hM. Statera et al.$$o7$$sIEEE Trans.Appl.Supercond.,27,4003205$$tConstruction and cold test of the first superferric correctormagnet for the LHC luminosity upgrade$$y2017
002674338 999C5 $$9CURATOR$$hM. Sorbi et al.$$o8$$sIEEE Trans.Appl.Supercond.,28,4100205$$tStatus of the activity for the construction of the HL-LHC superconducting high order corrector magnets at LASA-milan$$y2018