NbTi Superferric Corrector Magnets for the LHC Luminosity Upgrade

Author

Volpini, G. ; Alessandria, F. ; Bellomo, G. ; Broggi, F. ; Paccalini, A. ; Pedrini, D. ; Leone, A. ; Quadrio, M. ; Somaschini, L. ; Sorbi, M. ; Todero, M. ; Uva, C. ; Fessia, P. ; Todesco, E. ; Toral, F.

Author_Institution

LASA Lab., INFN, Segrate, Italy

Volume

25

Issue

3

fYear

2015

fDate

Jun-15

Firstpage

1

Lastpage

5

Abstract

CERN and INFN, Italy, have signed an agreement for R&D activities relating to high-luminosity LHC superconducting magnets, which include the design, construction, and cryogenic test of a set of five prototypes, one for each type foreseen, from the skew quadrupole to the dodecapole. The reference layout of these magnets is based on a superferric design type, which allows reaching the required integrated field strength with a relatively simple design. Since the number of magnets of all the types required for the series is 36, emphasis has been put on modularity, reliability, ease of construction, and on the use of an available superconducting wire. This paper presents the status of the development work being performed at INFN, LASA Laboratory, and at CERN, focusing on the following issues: the electromagnetic 2- and 3-D design including harmonic component study; the fringe field analysis; the magnet powering and quench protection; mechanical and construction main choices.

Keywords

brightness; cryogenics; design engineering; finite element analysis; niobium compounds; superconducting magnets; titanium compounds; wires (electric); CERN; FEM calculations; INFN; Italy; LASA Laboratory; LHC luminosity upgrade; R&D activities; cryogenic test; dodecapole; ease-of-construction; electromagnetic 2D design; electromagnetic 3D design; finite element method; fringe field analysis; harmonic component; high-luminosity LHC superconducting magnets; integrated field strength; magnet powering; modularity; niobium-titanium superferric corrector magnets; quench protection; reliability; skew quadrupole; superconduct- ing wire; superferric design type; Coils; Iron; Magnetic flux; Magnetic separation; Saturation magnetization; Superconducting magnets; Wires; FEM calculations; Multipole Analysis; Superconducting magnet; Superferric magnet; multipole analysis; superconducting magnet; superferric magnet;

fLanguage

English

Journal_Title

Applied Superconductivity, IEEE Transactions on

Publisher

ieee

ISSN

1051-8223

Type

jour

DOI

10.1109/TASC.2014.2378377

Filename

6980084