Ключевые слова: ITER, coils poloidal field, impregnation, LTS, NbTi, coils pancake, modeling, numerical analysis
Smirnov A., Khodzhibagiyan H., Kuznetsov G., Trubnikov G., Bazanov A., Donyagin A., Galimov A., Karpinsky V., Nikitaev P.
Ключевые слова: synchrotron, magnets dipole, cryogenic systems, test results, LTS, NbTi, cables, prototype, accelerator magnets, quench current, ac losses, high field magnets
Andreev N., Yamada R., Ambrosio G., Ostojic R., Lamm M.J., Tartaglia M., Tang Z., Kashikhin V.V., Nicol T., Page T., Wake M., Miller J., Peterson T., Evbota D., Brandt J., Coleman R., Lopes M., Popp J., Pronskikh V., Wands R.
Ключевые слова: accelerator magnets, coils solenoidal, detector, LTS, NbTi, design, design parameters, high field magnets
Ключевые слова: coils equilibrium field, ac losses, joints, magnetic field dependence, LTS, NbTi, experimental results, numerical analysis, comparison
Ключевые слова: HTS, YBCO, coated conductors, coils solenoidal, coils insert, normal zone propagation, modeling, stability, heat transfer, quench propagation, helium liquid, hybrid systems, LTS, NbTi, Nb3Sn, coils, resistive transition, magnetic field dependence, critical caracteristics, critical current density, anisotropy, irreversibility fields, hot spots, temperature distribution, magnetic field distribution
Ключевые слова: LTS, NbTi, filaments, ac losses, numerical analysis, modeling computational
Bredy P., Juster F.P., Scola L., Vedrine P., Bresson D., Meuris C., Maksoud W.A., Belorgey J., Lannou H., Molinie F., Payn A., Berriaud C., Gilgrass G., Bermond S., Nunio F., Schild T., Donati A., Aubert G., Beaudet F., Dubois O., Nusbaum M., Sinanna A.
Ключевые слова: MRI magnets, LTS, NbTi, coils pancake, fabrication, cryostat, control systems
Xu T., Wang Q., Dai Y., Zhao B., Song S., Wang C., Li L., Cheng J., Chen S., Wang H., Ni Z., Li Y., Cui C., Hu X., Wang H., Lei Y., Chan K., Yan L., Wen C., Hui G., Yang W., Liu F., Zhuo Y., Zhou X., Yan Z., Chen J.
Ключевые слова: MRI magnets, quench protection, LTS, NbTi, fabrication, design parameters, cryogenic systems, cryostat
Ключевые слова: accelerator magnets, medical applications, design, LTS, NbTi, coils, design parameters, magnetic field distribution, modeling, cyclotron, high field magnets
Pradhan S., Thankey P.L., Khan Z., George S., Pathan F., Dhanani K.R., Paravastu Y., Manthena H., Raval D.C.
Kanithi H., Juster F.P., Vedrine P., Payn A., Berriaud C., Gilgrass G., Bermond S., Dechambre T., Gheller J.M., Nunio F., Schild T.
Joss W., Pugnat P., Oberli L., Fazilleau P., Hervieu B., Mayri C., Ronayette L., Berriaud C., Pfister R., Xiao H.
Ключевые слова: LTS, NbTi, composites, wires multifilamentary, mechanical properties, temperature dependence, cryogenic systems, tensile tests
Ключевые слова: magnetic systems, design, irradiation effects, accelerator magnets, design parameters, cables, insulating medium, NbTi, high field magnets
Ключевые слова: SMES, review, design parameters, coils, LTS, NbTi, Rutherford cables, current leads, HTS, YBCO, voltage waveforms, Bi2212, wires round, coils solenoidal
Roy A., Saha S., Bhandari R.K., Mallik C., Bhunia U., Pradhan J., Khare V., Panda U., De A., Bandopadhaya S., Bhattacharyya T., Thakur S., Das M.
Ключевые слова: SMES, coils solenoidal, design, fabrication, quench, ac losses, mechanical properties, stress effects, LTS, NbTi, stress distribution, eddy currents, cryogenic systems, test results
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