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Examples of High-Performance & Cryostable Magnets
� 920-MHz (21.06 T) NMR magnet—“Adiabatic” bath-cooled � Dipole & quadrupole magnets —“Adiabatic” forced-flow cryogen � Research-purpose magnets —“Adiabatic” cryocooler-cooled � Large Helical Device —“Cryostable” bath-cooled & CCIC � 45-T Hybrid —“Cryostable” CCIC � LHC CMS magnet —“Cryostable” reinforced composite &
forced-flow single-phase cryogen
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High-Performance
1. Bath-Cooled: NMR Magnet
High-resolution 920 MHz NMR Magnet (Nb-Ti/Nb3Sn @1.8 K) at National Institute for Materials Science, Tsukuba (Kobe Steel, Co.; June 2001)
Center Field: 21.6 T Drift rate: <0.000235 gauss/h
<10 Hz/h RT bore: 54 mm Height: 5.5 m Weight: 17 ton (including cryogen & anti-vibration stand )
LHe refill interval: >21 daysrefill volume: 386 liters
LN2 refill interval: >27 daysrefill volume: 520 liters
Courtesy of Mamoru Hamada (Kobe Steel)
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Liquid He
Nb3Sn Joints
Superfluid Bath
NbTi Coils
Shim Coils Axial : Radial : X, Y, ZX, ZY, XY, X2-Y2
NbTi Joints
)3Sn Coils
Burst Disk
1860
3619
54
Z0, Z1, Z2
(Nb,Ti
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Main Coil Details
(m) (T) 0.8
0.0 (m)
-25
-20
-15
-10
-5
0
5
10
15
20
25
Nb-Ti (shim coils)
-0.5 0.5
High-Current0.6 High Tin Content (15%-Sn) (Nb,Ti)3Sn
0.4
0.2 High-Strength (>300 MPa @ 4.2 K) Ta-reinforced (Nb,Ti)3Sn
0.0
High-Strength (>430 MPa @ 4.2 K)-0.2 Cold-worked NbTi
-0.4 Nb3Sn conductors: 1382 kg NbTi conductors: 3444 kg Inductance: 1123 H-0.6 Operating current: 244.2 A Stored energy: 33 MJ
-0.8
Courtesy of Akio Sato (NIMS, Tsukuba)
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High-Performance2. Forced-Flow Cryogen: LHC Dipoles & Quadrupole
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LHC Dipole
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LHC Quadrupole
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High-Performance
3. Cryocooler-Cooled: Research-Purpose Magnets
Courtesy of Toru Kuriyama (Toshiba)
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Conduction-Cooled 6 T Nb-Ti Magnet
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6 T Cryocooler/Nb-Ti Magnet
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Room Temperature Bore 4-K Cryocooler
Superconducting Magnet
Thermal path
Radiation Shield
Vacuum Case
Courtesy of Kazuyuki Shibutani (Kobe Steel/JASTECH)
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Cryostable
1. & 2. Bath-Cooled & CICC: Large Helical Device (LHD)
� Large Helical Device (LHD) is an experimental fusion device which uses the heliotron magnetic field concept developed in Japan.
� To confine current-less steady-state plasma, LHD was designed as a fully superconducting system.
� Construction started in 1991 and completed by the end of 1997.
� Plasma experiment started on March 31, 1998.
Courtesy of Toshiyuki Mito (NIFS, Toki)
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Winding Machine for Helical Coils
On-site winding Start: Jan 1995; Finish: May 1996
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