Ключевые слова: hybrid systems, LTS, Nb3Sn, cable-in-conduit conductor, magnets resistive, coils insert, design, design parameters, current sharing, experimental results
Bellesia B., Buskop J., Harrison R., Rajainmaki H., Testoni P., Oliva A.B., Soto E.B., Boter E., Caballero J., Cornelis M., Cornella J., Galvan S., Losasso M., Poncet L., Heikkinen S., Verpont A.
Ключевые слова: ITER, coils toroidal, LTS, Nb3Sn, cable-in-conduit conductor, status
Koizumi N., Matsui K., Nakajima H., Shimada M., Hemmi T., Takano K., Nagamoto Y., Iguchi M., Chida Y., Oosemochi K., Makino Y., Esaki K.
Ключевые слова: ITER, review, coils toroidal, cable-in-conduit conductor, LTS, Nb3Sn, fabrication
Shikov A.K., Vysotsky V.S., Svalov G.G., Potanina L.V., Shutov K.A., Patrikeev V.M., Taran A.V., Ipatov Y.P., Marinin K.S., Kaverin D.S., Paramonov A.V., Kochetov M.V., Chensky I.F.
Ключевые слова: status, review, ITER, coils poloidal field, cable-in-conduit conductor, LTS, NbTi, Nb3Sn, fabrication, jacketing
Ключевые слова: status, ITER, magnetic systems, design, coils toroidal, coils poloidal field, central coils, design parameters, fatigue behavior, LTS, NbTi, Nb3Sn
Ключевые слова: ITER, coils toroidal, LTS, cable-in-conduit conductor, Nb3Sn, insulating medium, irradiation effects, design
Chen Z., Chen Z., Chen W., Li J., Pan Y., Zhu J., Tan Y., Ren Y., Wang F., He P., Kuang G., Huang P.
Ключевые слова: magnets sextupole, hybrid systems, ac losses, coils model, LTS, Nb3Sn, cable-in-conduit conductor, design parameters, experimental results
Ключевые слова: HTS, REBCO, coated conductors, coils pancake, coils insert, hybrid systems, magnetic systems, LTS, conduction cooled systems, NbTi, Nb3Sn, cryostat, design, fabrication
Zlobin A.V., Ambrosio G., Caspi S., Dietderich D., Ferracin P., Wang X., Ghosh A., Schmalzle J., Wanderer P., Dimarco J., Hafalia A.R., Bossert R., Lizarazo J., Felice H., Marchevsky M., Sabbi G.L., Joseph J., Bingham B., Cheng D.W., Chlachidze G.
Ключевые слова: accelerator magnets, LHC, magnets quadrupole, quench properties, LTS, Nb3Sn, quench propagation, test results, high field magnets, upgrade
Ключевые слова: accelerator magnets, LTS, Nb3Sn, modeling, numerical analysis, coils racetrack, high field magnets
Ключевые слова: LTS, coils poloidal field, magnetic systems, thermal-hydraulics, Tokamak, heat loads, friction, quench detection, NbTi, Nb3Sn, experimental results, high field magnets
Ключевые слова: magnetic systems, fusion magnets, NbTi, LTS, Nb3Sn, cable-in-conduit conductor, winding configurations, winding techniques, high field magnets
Ключевые слова: magnetic systems, coils toroidal, joints, Tokamak, LTS, NbTi, Nb3Sn, cable-in-conduit conductor, termination, design, joint resistances, high field magnets
Kikuchi A., Ogitsu T., Sasaki K., Tsuchiya K., Takeuchi T., Nakamoto T., Yamamoto A., Terashima A., Todesco E., Xu Q.
Ключевые слова: accelerator magnets, LHC, design, magnets dipole, LTS, Nb3Al, NbTi, Nb3Sn, numerical analysis, critical caracteristics, Jc/B curves, design parameters, supporting structure, high field magnets, upgrade
Barzi E., Andreev N., Zlobin A.V., Rossi L., Kashikhin V.V., Bossert R., Novitski I., Auchmann B., Apollinari G., Karppinen M., Nobrega A., Smekens D.
Ключевые слова: accelerator magnets, LHC, magnets dipole, LTS, Nb3Sn, design, design parameters, high field magnets, upgrade
Godeke A., Ferracin P., Dietderich D.R., Wang X., Hafalia A.R., Felice H., Sabbi G., Marchevsky M., Cheng D.W.
Zlobin A.V., Ambrosio G., Caspi S., Ferracin P., Dietderich D.R., Wang X., Anerella M., Ghosh A., Schmalzle J., Wanderer P., Hafalia A.R., Bossert R., Lizarazo J., Felice H., Sabbi G., Marchevsky M., Joseph J., Cheng D.W., Chlachidze G.
Ключевые слова: ITER, LTS, Nb3Sn, coatings, fabrication
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