2003
DOI: 10.1109/tasc.2003.812634
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Design of a superconducting multipole Wiggler for synchrotron radiation

Abstract: A 32-pole superconducting magnet with a 12 80 mm 2 cold bore aperture was designed to serve as a multipole wiggler in the Taiwan synchrotron light source. The magnet consists of 32 pairs of racetrack NbTi superconducting coils with a periodic length of 60 mm, and can produce a maximum magnetic field of 3.2 Tesla at a pole gap of 18 mm. The superconducting coils, the aluminum-supporting block, and the return iron yokes are cooled to 4.4 K in LHe bath. The temperature of cold bore beam duct will be at 70 K using… Show more

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Cited by 14 publications
(7 citation statements)
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“…This magnet adopts the even-number pole design [1], to minimize the first integral. Poles and coils are impregnated with an aluminum block of the up and down magnet array, respectively.…”
Section: Design and Construction Of Components Of Magnetmentioning
confidence: 99%
See 2 more Smart Citations
“…This magnet adopts the even-number pole design [1], to minimize the first integral. Poles and coils are impregnated with an aluminum block of the up and down magnet array, respectively.…”
Section: Design and Construction Of Components Of Magnetmentioning
confidence: 99%
“…Under normal operation conditions, the beam duct experiences no pressure difference and no deflection. However, when the beam duct is open to air, the beam duct experiences burst pressure and stress [1]. Therefore, the beam duct is stripped under vacuum.…”
Section: Design and Construction Of Components Of Magnetmentioning
confidence: 99%
See 1 more Smart Citation
“…To provide a world-competitive MAD capability, beamlines have been built on a high-field (3.2 T) superconducting magnet, multi-pole (28 effective poles) wiggler [1,2] that can illuminate up to three beamlines for simultaneous use. This field increases the critical energy from 2.14 keV for a 1.25 T normal conducting magnet to 4.82 keV.…”
Section: Introductionmentioning
confidence: 99%
“…Four superconducting cavities occupy two long straight sections and maintain the energy level of the electrons. Superconducting insertion magnets located at the remaining straight sections are the major devices providing the desired photon energy with high brilliance and flux [2]. All the superconducting devices require liquid helium for normal operation and the goal of their cryogenic system is to supply enough cooling power to maintain the helium levels of the cryostats.…”
Section: Introductionmentioning
confidence: 99%