Conductor Design for NET Toroidal Field Coils

F. Arendt; R. Fl&uuml;kiger; A. Hofmann; U. Jeske; K.-P. J&uuml;ngst; P. Komarek; H. Krauth; W. Lehmann; J. L&uuml;hning; B. Manes; W. Maurer; A. Nyilas; W. Specking; P. Turowski

doi:dx.doi.org/10.13182/FST85-A40141

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Home / Publications / Journals / Fusion Science and Technology / Volume 8 / Number 1P2A

Conductor Design for NET Toroidal Field Coils

F. Arendt, R. Flükiger, A. Hofmann, U. Jeske, K.-P. Jüngst, P. Komarek, H. Krauth, W. Lehmann, J. Lühning, B. Manes, W. Maurer, A. Nyilas, W. Specking, P. Turowski

Fusion Science and Technology / Volume 8 / Number 1P2A / July 1985 / Pages 862-867

Magnet Engineering / Proceedings of the Sixth Topical Meeting on the Technology of Fusion Energy (San Francisco, California, March 3-7, 1985) / dx.doi.org/10.13182/FST85-A40141

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The paper describes the results of studies for a NET toroidal field coil conductor carried out at KfK-Karlsruhe. The conductor concept is based on the same design principles as used in the Euratom-LCT coil, well proven in all conductor tests and the domestic tests of the coil. These principles are applied to the peculiarities of Nb₃Sn for a rated current of 20 kA at 12 T, taking into account ac losses and nuclear heating. A flat Nb₃Sn cable is soldered to a surrounding CuNi tape after reaction. Around this rectangular conductor core, Cu profiles are cabled on distance by the Roebel-process and subsequently soldered onto the CuNi tape. The whole system is surrounded by a steel conduit. The conductor data result from electric, thermohydraulic and stability calculations as well as mechanical evaluations. Expected fabrication processes are discussed, and measurements on a first simplified subsize conductor model are presented.