Barzi E., Zlobin A.V., Turrioni D., Ivanyushenkov Y., Kesgin I., Fuerst J., Kasa M., Gluskin E., MacDonald S.
Ключевые слова: LTS, Nb3Sn, magnets, undulator, design parameters, quench energy, stability, dissipative properties, losses, hot spots, fabrication, test results
Yu L., Lizhen M., Wei Y., Jiaqi L., Yi Z., Yiqin L., Enming M., Weizhuang P., Dongsheng N., Xinlong Z., Jian S., Wenjie Y.
Ключевые слова: medical applications, synchrotron, ion irradiation, gantry, magnets, bending radius, homogeneity, LTS, NbTi, wires, cables, coils, magnets dipole, magnets quadrupole, magnetic field distribution, design
Bragin A.V., Mezentsev N.A., Syrovatin V.M., Khrushchev S.V., Shkaruba V.A., Tsukanov V.M., Erokhin A.I., Kholopov M.A., Kremnev A.A.
Ключевые слова: detector, magnets dipole, design, design parameters, cooling technology, thermosyphon, LTS, NbTi, wires, coils
Ключевые слова: accelerator magnets, LTS, Nb3Sn, cables, quench propagation, quench protection, protective system, heater, modeling, numerical analysis
Ключевые слова: magnets dipole, design, modeling, test results, quench protection, coils outer, LTS, Nb3Sn, Rutherford cables, coils insert, HTS, magnetic field distribution
Han Z., Yuan P., Chen Y., Zhang X., Lu J., Yao Q., Zheng S., Zhu L., Yang T., Liang Y., Ni D., Mei E., Tong Y., Ou X., WeiWu
Ключевые слова: synchrotron, ion irradiation, magnets dipole, design, prototype, ac losses, cycling, LTS, NbTi, wires, cables, wires round, design parameters, modeling
Ключевые слова: DEMO, coils toroidal, LTS, Nb3Sn, Rutherford cables, react-and-wind technique, modeling, ac losses
Hopkins S.C., Senatore C., Buta F., Boutboul T., Ballarino A., Bonura M., Bovone G., Lonardo F., Borca C.N., Huthwelker T.
Ключевые слова: LTS, Nb3Sn, wires, fabrication, oxygenation treatments, precipitation methods
Ogitsu T., Sugano M., Tanaka K., Takahashi N., Nakamoto T., Suzuki K., Kimura N., Todesco E., Perez J.C., Okada R., Ikemoto Y., Okada N., Kawamata H.
Ключевые слова: LHC, luminosity, upgrade, LTS, NbTi, magnets dipole, separator, quench, training effect, test results
Ключевые слова: MRI magnets, LTS, NbTi, stability, shimming, conduction cooled systems, design, design parameters, fabrication, test results
Ключевые слова: fusion magnets, history, LTS, NbTi, wires multifilamentary, Nb3Sn, cable-in-conduit conductor, ITER, status, HTS, hybrid systems, review
Ключевые слова: multipole magnets, design, LTS, NbTi, wires, Bi2223, YBCO, tapes, power supply, cryogenic systems, cooling technology, prototype, test results, spectrometer, separator
Ключевые слова: Tokamak, central coils, coils model, LTS, Nb3Sn, NbTi, cable-in-conduit conductor, loads, mechanical properties, winding tension, friction, stiffness, experimental results
Ключевые слова: ITER, LTS, Nb3Sn, wires, central coils, winding techniques, quench detection, modeling
Willering G., Felice H., Todesco E., Tommasini D., Feuvrier J., Kirby G., Mangiarotti F.J., Fiscarelli L., Pincot F., Foussat A.P., Ilardi V., Kosowski F., Rogacki P.T., Urscheler C.
Ключевые слова: LHC, luminosity, LTS, NbTi, magnets dipole, correction coils, fabrication, prototype, test results
Ключевые слова: medical applications, rotating, gantry, magnets dipole, magnets quadrupole, LTS, NbTi, quench protection, ac losses, design parameters
Wang Y., Wang Y., Shi J., Wang J., Chen X., Wang C., Li C., Zhou J., Zhang H., Li W., Xu Q., Feng Z., Kang R., Feng A., RuiMa
Ключевые слова: LTS, Nb3Sn, wires, thermomagnetic instability, flux jumps, quench detection, modeling, numerical analysis, experimental results
Ключевые слова: ITER, coils poloidal field, LTS, NbTi, cable-in-conduit conductor, quench, modeling, quench detection
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