Ключевые слова: HTS, rings, bulk, YBCO, cylinders, suspension, dynamic operation, tubes, vacuum conditions, modeling, electromagnetic forces, numerical analysis
Ключевые слова: HTS, YBCO, bulk, levitation performance, pressure effect, nitrogen super-cooled, vacuum conditions, Maglev system, experimental results
Ключевые слова: HTS, current leads, measurement setup, vacuum conditions, cryogenic systems, helium supercritical, facility
Ключевые слова: evacuated tube, Maglev system, HTS, YBCO, bulk, fabrication, vacuum conditions, experimental results
Ключевые слова: cryogenic systems, review, cryostat, nitrogen liquid , portable unit, cryocoolers, vacuum conditions
Ключевые слова: Tokamak, design, design parameters, status, fabrication, cryogenic systems, cryostat, vacuum conditions, coils toroidal, refrigerator, plans
Ключевые слова: hybrid systems, magnetic systems, LTS, NbTi, Nb3Sn, Rutherford cables, coils solenoidal, HTS, Bi2223, tapes, GdBCO, coated conductors, coils pancake, conduction cooled systems, design parameters, critical caracteristics, critical current, tensile tests, stress effects, transverse stress, magnetic field dependence, loads, quench protection, cooling technology, impregnation, heat loads, cryocoolers, test results, vacuum conditions, hysteresis
Ключевые слова: stellarator, vacuum conditions, numerical analysis
Ключевые слова: Tokamak, modeling, nucleation, magnetic field distribution, magnetic field dependence, vacuum conditions
Chen Z.M., Fang Z., Tan Y.F., Pan Y.N., Kuang G.L., Chen W.G., Chen Z.Y., Zhu J.W., Li J.J., Huang P.C.
Ключевые слова: cryogenic systems, magnetic systems, hybrid systems, magnets resistive, coils insert, LTS, Nb3Sn, coils, cryostat, design, design parameters, shields, vacuum conditions
Ключевые слова: HTS, Maglev system, nitrogen liquid , boiling, cooling technology, vacuum conditions
Mitchell N., Hamada K., Domptail F., Foussat A., Zheng S., Surrey E., McIntosh S., Holmes A., Cave-Ayland K., Ash A., Taylor N.
Ключевые слова: ITER, magnets, fault currents, cryogenic systems, coils poloidal field, vacuum conditions, safety
Ivanov D.P., Khayrutdinov R.R., Rodin I.Y., Zapretilina E.R., Kolbasov B.N., Bondarchuk E.N., Azizov E.A., Belyakov V.A., Kavin A.A., Krasnov S.V., Mineev A.B., Muratov V.P., Tanchuk V.N., Khokhlov M.V., Maximova I.I., Labusov A.N., Lukash V.E., Ananyev S.S., Voronova A.A., Golikov A.A., Goncharov P.R., Dnestrovskij A.Y., Kedrov I.V., Klischenko A.V., Krylov A.I., Krylov V.A., Kuzmin E.G., Kuteev B.V., Medvedev S.Y., Petrov V.S.-1, Sergeev V.Y., Spitsyn A.V., Trofimov V.A., Shpanskiy Y.S.
Ключевые слова: DEMO, magnetic systems, vacuum conditions, irradiation effects, shields, ITER, comparison, coils poloidal field, central coils, coils toroidal, divertor, design parameters
Xu Y., Song H., Chouhan S., Cole D., Zeller A., Swanson R., Borden T., Burkhardt E.E., Patil M., Georgobiani D., Hausmann M., Portillo M., Ronningen R.
VanDevender B., Vocking S., Wall B., Wierman K., Wilkerson J., Wustling S., Amsbaugh J.F., Barrett J., Beglarian J., Beglarian A., Bergmann T., Bichsel H., Bodine L.I., Bonn J., Boyd N.M., Burritt T.H., Chaoui Z., Chilingaryan S., Corona T.J., Doe P.J., Dunmore J.A., Enomoto S., Formaggio J.A., Frankle F.M., Furse D., Gemmeke H., Gluck F., Harms F., Harper G.C., Hartmann J., Howe M.A., Kaboth A., Kelsey J.E., Knauer M., Kopmann A., Leber M.L., Martin E., Middleman K., Myers A., Oblath N.S., Parno D.S., Peterson D., Petzold L., Phillips D., Renschler P., Robertson R., Schwarz J., Steidl M., Tcherniakhovski D., Thummler T., VanWechel T.
Ключевые слова: detector, coils solenoidal, design, design parameters, vacuum conditions, cryogenic systems, cooling technology, review
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