Characterization and qualification of advanced insulators for fusion magnets

Characterization and qualification of advanced insulators for fusion magnets

•Various resins were qualified for the ITER TF coil insulation.•Pre-bonded glass fiber/polyimide tapes were characterized after irradiation.•A repair scenario of a magnet coil was simulated using a cyanate ester resin. Intensive research over the past decades demonstrated that the mechanical materia...

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Bibliographic Details
Published in:Fusion engineering and design Vol. 88; no. 5; pp. 350 - 360
Main Authors: Humer, K., Prokopec, R., Weber, H.W., Fillunger, H., Maix, R.K.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-06-2013
Subjects:
Cyanate ester blends
Fiber reinforced composites
Fluence
Glass fiber reinforced plastics
Insulation
Irradiation
Magnet insulation
Magnets
Mechanical properties
Neutron fluence
Polymer blends
Polymers
Reactor irradiation
Resins
Mechanical properties
Fiber reinforced composites
Reactor irradiation
Neutron fluence
Cyanate ester blends
Magnet insulation
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Summary:•Various resins were qualified for the ITER TF coil insulation.•Pre-bonded glass fiber/polyimide tapes were characterized after irradiation.•A repair scenario of a magnet coil was simulated using a cyanate ester resin. Intensive research over the past decades demonstrated that the mechanical material performance of epoxy based glass fiber reinforced plastics, which are normally used by industry as insulating materials in magnet technology, degrades dramatically upon irradiation to fast neutron fluences above 1×1022m−2 (E>0.1MeV). which have to be expected in large fusion devices like ITER. This triggered an insulation development program based on cyanate ester (CE) and blends of CE and epoxies, which are not affected up to twice this fluence level, and therefore appropriate for large fusion magnets like the ITER TF coils. Together with several suppliers resin mixtures with very low viscosity over many hours were developed, which renders them suitable for the impregnation of very large volumes. This paper reports on a qualification program carried out during the past few years to characterize suitable materials, i.e. various boron-free R-glass fiber reinforcements interleaved with polyimide foils embedded in CE/epoxy blends containing 40% of CE, a repair resin, a conductor insulation, and various polyimide/glass fiber bonded tapes. The mechanical properties were assessed at 77K in tension and in the interlaminar shear mode under static and dynamic load conditions prior to and after reactor irradiation at ~340K to neutron fluences of up to 2×1022m−2 (E>0.1MeV). i.e. twice the ITER design fluence. The results confirmed that a sustainable solution has become available for this critical magnet component of ITER.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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ISSN:0920-3796
1873-7196
DOI:10.1016/j.fusengdes.2013.03.074