Ключевые слова: HTS, REBCO, tapes, coils, heat treatment, gas treatments, vacuum conditions, degradation studies, critical current, joint resistances, n-value, experimental results
Zhukovsky A., Michael P.C., Labombard B., Vieira R., Beck W., Doody J., Golfinopoulos T., Johnson R., Wolf M.J., Hartwig Z., Estrada J., Fry V., Ihloff E., Voirin E., Nash D., Schweiger S., O’Shea C., Watterson A., Barnett R., Bartoszek L., Lane-Walsh S., Muncks J.P., Santoro F., Stillerman J., Wilcox S., Chamberlain S., Chavarria D., Pfeiffer A., Pierson S., Ravikumar D.K., Rowell M., Vidal C., Burke W., Byford W., Cote K., Dombrowski E., Doos R., Fulton M., Levine M., Metcalfe K.
Ключевые слова: facility, magnets, Tokamak, design parameters, coils toroidal, coils model, HTS, REBCO, tapes, current leads, VIPER cable, bus bar conductor, cryogenic systems, cooling technology, cryostat, control systems, vacuum conditions, shields, irradiation effects, nitrogen liquid , helium supercritical, power supply
Saggese A., Iannone G., Ferrentino A., Avallone G., Severino C., D'Agostino D., Severino F., Leo E., Imran M.
Verweij A., Pojer M., Bajko M., Modena M., Todesco E., Fleiter J., Ballarino A., Wollmann D., Seshadri S., Perin A., Steckert J., Denz R., Prin H., Ravaioli E., Thiesen H., Bednarek M.J., Cruikshank P., Ramos D.D., Zerlauth M., Mateos F.R., Garcia R.T., Bruning O., Yammine S., Gamba D., Martino M., Leclercq Y., Bozzini D., Blanchard S., Garcia N.H., Herty A., Maan W., Onufrena A.
Ключевые слова: LHC, luminosity, magnets, LTS, NbTi, joints, MgB2, cables, current leads, HTS, quench protection, quench detection, cryogenic systems, vacuum conditions, plans, test results, facility
Ключевые слова: facility, measurement setup, magnets, cryogenic systems, cryostat, vacuum conditions
Fair R., Sun E., Kashy D., Rajput-Ghoshal R., Ghoshal P., Gopinath S., Ihloff E., Kumar K., Fast J., Sinnott M., Lamont J., Dion M.P., Mammei J.
Ключевые слова: spectrometer, electron irradiation, magnets, coils toroidal, vacuum conditions, design, prototype
Бутенко А.В., Бровко О.И., Галимов А.Р., Горбачёв Е.В., Костромин С.А., Карпинский В.Н., Мешков И.Н., Мончинский В.А., Сидорин А.О., Сыресин Е.М., Трубников Г.В., Тузиков А.В., Филиппов А.В., Ходжибагиян Г.Г.
Ключевые слова: NICA, synchrotron, ion irradiation, LTS, NbTi, magnets dipole, magnets quadrupole, design, design parameters, fabrication, cryogenic systems, cryostat, vacuum conditions, test results
Ключевые слова: coils, impregnation, heat treatment, vacuum conditions, heat losses, shields, heat transfer, modeling, experimental results, numerical analysis
Ключевые слова: Tokamak, divertor, heat loads, ITER, DEMO, vacuum conditions, cryogenic systems, status, plans
Ключевые слова: ITER, coils poloidal field, impregnation, vacuum conditions, pressure effect, insulation, experimental devices, test results
Ключевые слова: colliders, proton irradiation, luminosity, design, design parameters, high field magnets, Jc/B curves, LTS, HTS, comparison, vacuum conditions, screen, review
Feher S., Rabehl R., Bossert R., Todesco E., Prin H., Strauss T., Arnold D., Vouris A., Orozco C., Narug C., Nikolic V., Robotham W., Martin L.
Ключевые слова: LHC, luminosity, upgrade, cryogenic systems, cryostat, cold mass, vacuum conditions, bus bar conductor, design, design parameters, quench protection
Ключевые слова: high field magnets, hybrid systems, vacuum conditions, design, test results
Ключевые слова: dc performance, circuit breaker, vacuum conditions, damping, contact characteristics, operational performance
Ключевые слова: synchrotron, undulator, vacuum conditions
Bachmann C., Vorpahl C., Cufar A., Eade T., Flammini D., Gliss C., Kodeli I.A., Marzullo D., Mazzone G., Wilde A.
Ключевые слова: DEMO, fusion, power plants, coils toroidal, gamma irradiation, irradiation effects, heating rates, design, shields, vacuum conditions
Ключевые слова: power equipment, power transmission lines, HTS, cables, vacuum conditions, cryogenic pumps, test long-term operation
Ключевые слова: DEMO, Europe, design, divertor, vacuum conditions, shielding effects, neutron irradiation, loads, irradiation effects, defects
Ключевые слова: LHC, luminosity, magnets, feeder, design, MgB2, LTS, NbTi, cables, joints, flexible cryostat, cryogenic systems, helium liquid, thermal properties, mechanical properties, vacuum conditions
Nam K., Park W.W., Hur J., Lee Y., Kang K., Her N., Panchal M., Pichel G.P., Noh C.H., Kang D.K., Kim I.J., Lim K.
Ключевые слова: ITER, thermal performance, shields, fabrication, cryostat, vacuum conditions
Ключевые слова: magnets, accelerator magnets, cryostat, design, coils solenoidal, fabrication, vacuum conditions
Ключевые слова: Tokamak, HTS, vacuum conditions, design, thermal properties, mechanical properties, thermal loads, modeling, transient performance, numerical analysis, arc
Caspi S., Sanfilippo S., Auchmann B., Arbelaez D., Lackner F., Felder R., Smekens D., Montenero G., Sidorov S., Brouwer L., Swanson J.H.
Ключевые слова: LTS, Nb3Sn, coils, fabrication, accelerator magnets, vacuum conditions, impregnation, heat treatment, winding process
Ouden A.D., Dixon I.R., Bird M.D., Perenboom J.A., Adkins T.A., Hoffman M., Wulffers C.A., Hussey N.E.
Ключевые слова: hybrid systems, high field magnets, LTS, Nb3Sn, cable-in-conduit conductor, coils, fabrication, helium supercritical, cryogenic systems, winding configurations, heat treatment, critical caracteristics, critical current, RRR parameter, n-value, impregnation, vacuum conditions, photo, cold mass
Ключевые слова: DEMO, fusion, hybrid systems, design, vacuum conditions, cooling technology, modeling, facility
Ключевые слова: presentation, undulator, LTS, Nb3Sn, cryocoolers, vacuum conditions, photo, magnets, design parameters, design, ac losses, quench current, photon
Bredy P., Scola L., Vedrine P., Bourquard A., Quettier L., Belorgey J., Lannou H., Payn A., Berriaud C., Gilgrass G., Nunio F., Schild T., Aubert G., Stepanov V., Dubois O., Moliniй F., Nusbaum M., Sinanna A., Billotte G., Schweitzer M., Juster F., Guihard Q., Jannot V.
Ключевые слова: MRI magnets, LTS, NbTi, helium superfluid, design, design, fabrication, cryogenic systems, shields, vacuum conditions
Ключевые слова: Tokamak, central coils, impregnation, vacuum conditions, pressure effect, LTS, Nb3Sn, test results
Ключевые слова: Maglev system, HTS, YBCO, bulk, cryogenic systems, cryostat, vacuum conditions, levitation performance, model small-scale, experimental results
Takano H., Yamaguchi S., Watanabe M., Chikumoto N., Vyatkin V.S., Inoue N., Watanabe H., Ivanov Y.V., Sawamura T., Ishiyama K., Kanda M.
Ключевые слова: magnets permanent, cryogenic systems, undulator, comparison, LTS, NbTi, Nb3Sn, magnetic field density, design, cooling technology, vacuum conditions, plans
Ключевые слова: rotating machines, HTS, motors, torque, vacuum conditions, tubes, measurement setup, gas treatments
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
Vedrine P., Bourquard A., Quettier L., Berriaud C., Gilgrass G., Schild T., Stepanov V., Nusbaum M., Schweitzer M., Dilasser G., Oudot J.
Ключевые слова: MRI magnets, shields, coils, fabrication, status, LTS, NbTi, impregnation, vacuum conditions, design, design parameters
Ivanyushenkov Y., Harkay K., Abliz M., Boon L., Borland M., Capatina D., Collins J., Decker G., Dejus R., Dooling J., Doose C., Emery L., Fuerst J., Gagliano J., Hasse Q., Jaski M., Kasa M., Kim S.H., Kustom R., Lang J.C., Liu J., Moog E., Robinson D., Sajaev V., Schroeder K., Sereno N., Shiroyanagi Y., Skiadopoulos D., Smith M., Sun X., Trakhtenberg E., Vasserman I., Vella A., Xiao A., Xu J., Zholents A., Gluskin E., Lev V., Mezentsev N., Syrovatin V., Tsukanov V., Makarov A., Pfotenhauer J., Potratz D.
Ключевые слова: undulator, LTS, NbTi, cryostat, cryogenic systems, cooling technology, heat loads, fabrication, test results, quench, vacuum conditions, photon
Ключевые слова: helium liquid, heat transfer, cryogen transfer line, vacuum conditions, losses, cavity, experimental results
Ключевые слова: accelerator magnets, vacuum conditions, review, high field magnets
Ключевые слова: ITER, Europe, status, magnetic systems, vacuum conditions, review
Neilson G.H., Rummel T., Bykov V., Wegener L., Bosch H., Brakel R., Eeten P., Feist J.-H., Gasparotto M., Grote H., Klinger T., Nagel M., Naujoks D., Schacht J., Vilbrandt R., Werner A.
Ключевые слова: stellarator, status, cryogenic systems, cooling technology, cryostat, vacuum conditions, fabrication, commissioning
Ключевые слова: Tokamak, control systems, temperature distribution, vacuum conditions
Ключевые слова: presentation, HTS, cables, Korea, review, status, plans, power equipment, cables three-in-one, ac performance, dc performance, cables in separated cryostat, power distribution system, cryogenic systems, test results, grid operation, power transmission lines, cooling technology, critical caracteristics, current-voltage characteristics, cycling, pressure effect, vacuum conditions
Ключевые слова: ITER, correction coils, vacuum conditions, impregnation, experimental results, mechanical properties, microstructure, LTS, NbTi
Oliva B.A., Soto B.E., Batista R., Bellesia B., Robello B.E., Buskop J., Caballero J., Cornelis M., Cornella J., Galvan S., Libens K., Losasso M., Moreno A., Poncet L., Harrison R., Heikkinen S., Barutti A., Dormicchi O., D'Urzo C., Pesenti P., Valle N., Villa E.R., Lucas J., Pando F., Francone R., Franchiello E., Barbero P., Ribeiro S.J., Rossi D., Bara X., Sorrentino S., Pedrosa N., Scheller H.
Ключевые слова: ITER, coils toroidal, fabrication, status, winding techniques, LTS, Nb3Sn, insulation, vacuum conditions, heat treatment, termination, joints, prototype
Ключевые слова: presentation, power equipment, status, fabrication, cryogenic systems, insulation, operational performance, review, HTS, YBCO, cables, dc performance, power transmission lines, coated conductors, critical caracteristics, current-voltage characteristics, vacuum conditions, pressure effect
Ключевые слова: ITER, coils poloidal field, impregnation, fabrication, vacuum conditions
Ключевые слова: LTS, Nb3Sn, cable-in-conduit conductor, magnets, hybrid systems, NbTi, impedance, winding configurations, fabrication, vacuum conditions, review
Makarov A., Efremov A., Bunzarov Z., Dodokhov V., Golovatyuk V., Ionaites V., Kekelidze V., Kovalchuk O., Koshurnikov E., Lobanov Y., Ochrimenko V., Vodopyanov A.
Ключевые слова: rotating machines, generators, wind farms application, review, HTS, Bi2223, YBCO, tapes, coated conductors, coils, cryogenic systems, vacuum conditions, economic analysis, design, design parameters
Ключевые слова: fusion magnets, Tokamak, review, ITER, Europe, coils toroidal, coils poloidal field, vacuum conditions, winding configurations, fabrication, presentation, high field magnets
Ключевые слова: MRI magnets, homogeneity, LTG process, NbTi, coils, design parameters, thermal properties, vacuum conditions, design, resonance effects
Mitchell N., Bauer P., Devred A., Clayton N., Sahu A.K., Dolgetta N., Gung C.Y., Prasad K., Mahadevappa V.
Ключевые слова: feeder, ITER, design, helium supercritical, vacuum conditions, thermal performance, heat loads, modeling
Mitchell N., Bi Y., Bauer P., Wang Z., Chen Y., Zhou T., Devred A., Song Y., Huang X., Gung C., Cheng Y., Ding K., Lu K., Shen G., Sahu A., Jong C., Dolgetta N., Ilin Y.
Ключевые слова: feeder, ITER, design, fabrication, termination, vacuum conditions, cryostat
Nishimura A., Lelekhov S.A., Oh Y.K., Ivanov D.P., Weng P.D., Song Y.T., Pradhan S., Sharma A.N., Anashkin I.O., Khvostenko P.P., Kolbasov B.N., Pan W.J.
Ключевые слова: fusion magnets, Tokamak, magnetic systems, forced flow, insulation, breakdown characteristics, vacuum conditions, losses, review, high field magnets
Ключевые слова: impregnation, ITER, insulation, vacuum conditions, pressure effect, insulating medium, fabrication, magnetic systems
Bellesia B., Harrison R., Rajainmaki H., Bonito-Oliva A., Soto E.B., Boter E., Caballero J., Cornelis M., Losasso M., Batista R., Echeandia J., Felipe A., Larizgoitia I., Marin M., Merino A., Pando F., Pesenti P., Villa E.R., D’Urzo C., Valle N.
Ключевые слова: ITER, coils toroidal, winding techniques, status, fabrication, heat treatment, insulation, vacuum conditions, pressure effect, LTS, Nb3Sn, cable-in-conduit conductor
Ключевые слова: magnetic systems, coils, high voltage process, installation, vacuum conditions, breakdown characteristics
Fischer E., Shcherbakov P., Schnizer P., Mierau A., Wilfert S., Macavei J., Koch S., Weiland T., Kurnishov R.
Ключевые слова: accelerator magnets, vacuum conditions, design, cyclotron, high field magnets, beam lines
Pradhan S., Thankey P.L., Khan Z., George S., Pathan F., Dhanani K.R., Paravastu Y., Manthena H., Raval D.C.
Ключевые слова: magnets quadrupole, accelerator magnets, vacuum conditions, design, cryogenic systems, cryostat, heat transfer, heat leakage, high field magnets
Ключевые слова: cryogenic systems, cryostat, review, vacuum conditions, experimental devices
Ключевые слова: presentation, power transmission lines, power distribution system, power equipment, dc performance, test results, prototype, HTS, Bi2223, cables, economic analysis, current leads, termination, heat leakage, cryogenic systems, cryocoolers, vacuum conditions, ac performance, comparison, supporting structure
Ключевые слова: hybrid systems, magnets, series connection, eddy currents, shields, thermal insulation, vacuum conditions, numerical analysis, cold mass
Wang B., Wahrer B., Taylor C., Zbasnik J., Dell'Orco D., Ross J., Chen J., Xu L., Chen H., Wagner B., McMullin J., Pong R., Juang T., Wang M., Carter C., Quettier L., Burkert V., Elouadrhiri L., Kashy D., Leung E., Schneider W.
Ключевые слова: spectrometer, experimental devices, coils toroidal, design, design parameters, vacuum conditions, cooling technology
Fleshler S., Hazelton D., Gamble B., Gouge M., Demko J., Marchionini B., Eckroad S., McCall J., Hassenzahl W., Reddy N., Ulliman J., Dalstrom T., Selvamanickaml V., Butler S, . Haught D.
Ключевые слова: HTS, cables, dc performance, economic analysis, power equipment, presentation, design, joints, vacuum conditions, cryogenic systems
Ключевые слова: patents, thermal performance, cooling technology, insulation, vacuum conditions
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