Title :
Superconducting combined function magnet system for J-PARC neutrino experiment
Author :
Ogitsu, Toru ; Ajima, Yasuo ; Anerella, Michael ; Escallier, John ; Ganetis, George ; Gupta, Ramesh ; Hagedorn, Dietrich ; Harrison, Michael ; Higashi, Norio ; Iwamoto, Yosuke ; Ichikawa, Atsuko ; Jain, Animesh ; Kimura, Nobuhiro ; Kobayashi, Takashi ; Ma
Author_Institution :
High Energy Accelerator Res. Organ., KEK, Tsukuba, Japan
fDate :
6/1/2005 12:00:00 AM
Abstract :
The J-PARC Neutrino Experiment, the construction of which starts in JFY 2004, will use a superconducting magnet system for its primary proton beam line. The system, which bends the 50 GeV 0.75 MW proton beam by about 80 degrees, consists of 28 superconducting combined function magnets. The magnets utilize single layer left/right asymmetric coils that generate a dipole field of 2.6 T and a quadrupole field of 18.6 T/m with the operation current of about 7.35 kA. The system also contains a few conduction cooled superconducting corrector magnets that serve as vertical and horizontal steering magnets. All the magnets are designed to provide a physical beam aperture of 130 mm in order to achieve a large beam acceptance. Extensive care is also required to achieve safe operation with the high power proton beam. The paper summarizes the system design as well as some safety analysis results.
Keywords :
beam handling equipment; neutrino oscillations; proton beams; safety; superconducting magnets; 0.75 MW; 130 mm; 2.6 T; 50 GeV; 7.35 KA; J-PARC Neutrino Experiment; accelerator safety; asymmetric coils; high power proton beam; large beam acceptance; particle beam transport; safety analysis; steering magnets; superconducting accelerator magnets; superconducting combined function magnet; superconducting corrector magnets; superconducting magnet; system design; Apertures; Magnetic analysis; Neutrino sources; Particle beams; Safety; Structural beams; Superconducting coils; Superconducting epitaxial layers; Superconducting magnets; System analysis and design; Accelerator safety; neutrinos; particle beam transport; superconducting accelerator magnets;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2005.849525
