Zhukovsky A., Michael P.C., Doody J., Golfinopoulos T., Hartwig Z.S., Vieira R.F., Fry V., Ihloff E., Nash D., Schweiger S., O’Shea C., Watterson A., Barnett R., Voirin E.A., Bartoszek L., Lations R.F.
Ключевые слова: power equipment, HTS, cables, power transmission lines, pressure drop, cryostat, spiral lines, modeling, numerical analysis
Yamamoto H., Okuno K., Chikumoto N., Sato A., Inoue N., Motojima O., Watanabe H., Ivanov Y., Sawamura T., Hino T., Sumi K.
Ключевые слова: DEMO, LTS, NbTi, bus bar conductor, thermal-hydraulics, operational performance, cooling technology, stability, modeling, numerical analysis, heat loads, ac losses, pressure drop
Ключевые слова: Tokamak, feeder, design parameters, MgB2, cooling technology, helium gas, heat transfer, temperature distribution, pressure drop, design, numerical analysis
Ключевые слова: ITER, magnetic systems, feeder, bus bar conductor, joints, quality control, joint resistances, pressure drop, stability, test results
Tsuchiya K., Hamada K., Fukui K., Kawano K., Abe T., Murakami H., Tomarchio V., Natsume K., Hoa C., Michel F., Wanner M., Otsu K.
Ключевые слова: power equipment, HTS, GdBCO, cables, design parameters, cryogenic systems, nitrogen liquid , phase composition, cooling technology, pressure drop, temperature rise , modeling, numerical analysis
Wu X., Wang Z., Wang Z., Dai S., Huang Y., Song M., Tian B., Wang B., Chen T., Xia Y., Lv Z., Xie H.
Ключевые слова: measurement setup, test results, current-voltage characteristics, grid operation, HTS, YBCO, tapes, power equipment, cables triaxial, cables three-phase, design, fabrication, critical caracteristics, critical current, magnetic field dependence, fault currents, heat generation, current leads, termination, cryogenic systems, pressure drop
Zanino R., Martovetsky N.N., Bonifetto R., Schild T., Gauthier F., Zappatore A., Khumthong K., Schaubel K.M., Sheeron J., Langhorn A.R.
Ключевые слова: ITER, central coils, thermal-hydraulics, cable-in-conduit conductor, pressure drop, test results, modeling
Ключевые слова: measurement setup, cryogenic systems, cryostat, helium gas, HTS, cable-in-conduit conductor, coils, pressure drop, thermal-hydraulics, friction, cooling technology, facility
Grundmann J., Frank M., Kuhn L., Wilke M., Hasselt P.v., Filipenko M., Gleixner T., Thummet M., Lessmann M., Moller D., Bohm M., Schroter A., Hase K., Richter J., Herranz-Garcia M., Weidermann C., Spangolo A., Klopzig M.
Ключевые слова: aviation application, hybrid systems, propulsion system, HTS, coated conductors, generators, design, design parameters, review, weight, hydrogen liquid, flux density, distribution, torque, ac losses, electrical conductivity, temperature distribution, coils racetrack, mechanical properties, stress effects, strain effects, stators, heat transfer, pressure drop
Ключевые слова: HTS, YBCO, coated conductors, cables in separated cryostat, power transmission lines, thermal-hydraulics, modeling, numerical analysis, cryogenic systems, heat transfer, pressure drop, nitrogen liquid , doping effect, nanoscaled effects, thermal conductivity, specific heat, viscosity, density, friction, cryogenic pumps, cooling technology
Ciazynski D., Zani L., Lacroix B., Torre A., Hertout P., Nicollet S., Decool P., Nunio F., Hoa C., Vallcorba R., Lamaison V., Gros G., Poncet J., Coz Q.L., Bonne F., Misiara N., Radhakrishnan R.
Ключевые слова: DEMO, status, Europe, cryogenic systems, magnetic systems, LTS, Nb3Sn, cable-in-conduit conductor, hot spots, coils toroidal, central coils, mechanical properties, friction, pressure drop, design
Ключевые слова: power equipment, cables, HTS, nitrogen sub-cooled, hydraulic performances, friction, pressure drop, numerical analysis, modeling
Ключевые слова: power equipment, cables three-phase, cables coaxial, design, HTS, coated conductors, cooling technology, pressure drop, modeling, numerical analysis
Ключевые слова: power equipment, cables, cryogenic systems, cryogen transfer line, nitrogen liquid , HTS, YBCO, coated conductors, modeling, pressure drop, cryostat, sample shapes
Ключевые слова: fusion magnets, high field magnets, forced flow, cooling technology, hydrogen, helium, neon, heat transfer, coils toroidal, HTS, REBCO, cables, current sharing, heat capacity, pressure drop, modeling, numerical analysis
Hayashi K., Takano H., Masuda T., Yamaguchi S., Watanabe M., Chikumoto N., Inoue N., Watanabe H., Ivanov Y.V., Koshizuka H., Sawamura T., Ishiyama K., Oishi Z.
Ключевые слова: HTS, Bi2212, stability, LTS, Nb3Sn, hybrid systems, high field magnets, Tokamak, central coils, design, modeling, design parameters, ac losses, temperature distribution, recovery characteristics, pressure drop
Ключевые слова: cryogen transfer line, nitrogen liquid , modeling, numerical analysis, heat transfer, pressure drop, friction
Ключевые слова: cryogenic systems, helium, boiling, experimental results, pressure drop, friction, thermal-hydraulics, loop
Solenne N., Vieillard L., Walter C., Maksoud W.A., Allard J., Bargueden P., Belorgey J., Bounab A., Bouty A., Donati A., Durand G., Eppelle D., Faict-Bastin S., Genini L., Guiho P., Guihard Q., Joubert J.-M., Kuster O., Kante A., Medioni D., Molinie F.
Ключевые слова: pressure drop, cryogenic systems, helium supercritical, specific heat, viscosity, thermal conductivity, density, tubes, experimental results
Mitchell N., Kim H., Ilyin Y., Chen L., Chen Y., Devred A., Clayton N., Gung C., Ding K., Lu K., Beemsterboer C., Farek J., Wen X., Man S., Naoyuki S.
Ключевые слова: bus bar conductor, ITER, joints, design, test results, feeder, heat loads, pressure drop
Ключевые слова: power equipment, power transmission lines, dc performance, cryogenic systems, nitrogen liquid , HTS, pressure drop, heat leakage, test results
Zanino R., Bruzzone P., Celentano G., Augieri A., Muzzi L., Marzi G.D., Corte A.D., Bonifetto R., Carli S., Savoldi L., Piras V.
Ключевые слова: HTS, cable-in-conduit conductor, fusion magnets, thermal-hydraulics, modeling, DEMO, coated conductors, twisting, stacked blocks, Al, cores, REBCO, EDIPO, test results, pressure drop, thickness dependence
Ogitsu T., Sasaki K., Sugano M., Okamura T., Yang Y., Nakamoto T., Makida Y., Ki T., Yoshida M., Iio M., Mihara S.
Ключевые слова: cryogenic systems, accelerator magnets, coils solenoidal, design parameters, helium liquid, heat loads, pressure drop, status
Zenobio A.D., Bruzzone P., Stepanov B., Ouden A., Muzzi L., Corte A., Quagliata F., Sedlak K., Perenboom J.
Ключевые слова: ITER, correction coils, quench, modeling, cable-in-conduit conductor, design parameters, thermal-hydraulics, LTS, NbTi, pressure drop, coils pancake, pressure distributions
Honjo S., Masuda T., Watanabe M., Nakano T., Ohya M., Maruyama O., Yaguchi H., Nakamura N., Machida A.
Ключевые слова: power equipment, grid operation, test long-term operation, HTS, Bi2223, tapes, cables three-in-one, pressure drop, fault currents, heat losses, ac losses
Vysotsky V.S., Lelekhov S.A., Patrikeev V.M., Kaverin D.S., Kochetov M.V., Tronza V.I., Svertnev S.A.
Ключевые слова: ITER, coils toroidal, cable-in-conduit conductor, resistance, hydraulic performances, pressure drop, test results
Ключевые слова: ITER, current leads, prototype, fabrication, design, design parameters, pressure drop, HTS, Bi2223, stacked blocks, LTS, NbTi, cable-in-conduit conductor, joint resistances, insulation, solder, heat exchanger
Tsuchiya K., Mito T., Yoshida K., Chikaraishi H., Takahata K., Kizu K., Murakami H., Obana T., Natsume K., Hamaguchi S., Nomoto K., Imai Y., Koide Y., Imagwa S.
Ключевые слова: cryogenic systems, nitrogen gas, nitrogen liquid , pressure drop, cooling technology, experimental results
Ключевые слова: power equipment, power transmission lines, cables coaxial, dc performance, pressure drop, heat leakage
Ключевые слова: HTS, power equipment, cables three-in-one, cryogenic systems, grid operation, pressure drop
Ключевые слова: HTS, DI-Bi2223/Ag, tapes, cables, dc performance, power equipment, power transmission lines, cryogenic systems, test results, converters, current leads, joint resistances, joints, temperature distribution, pressure drop, critical caracteristics, current-voltage characteristics, breakdown characteristics, presentation
Ключевые слова: HTS, current leads, thermal-hydraulics, numerical analysis, meander, heat exchanger, Tokamak, stellarator, heat transfer, pressure drop, modeling, high field magnets
Ключевые слова: power equipment, cables, HTS, YBCO, coated conductors, Bi2223, tapes, modeling, cryogenic systems, cooling technology, pressure drop, heat transfer, numerical analysis, length
Ключевые слова: power equipment, HTS, cables, degaussing system, modeling, pressure drop, nitrogen gas, nitrogen liquid , coils
Ключевые слова: ITER, HTS, current leads, heat exchanger, nucleation, Bi2223/Ag alloy, tapes, pressure drop
Ключевые слова: cryogenic systems, helium, power equipment, modeling, heat transfer, cables, numerical analysis, pressure drop
Ключевые слова: LTS, Nb3Sn, coils, heat treatment, cable-in-conduit conductor, pressure drop
Ключевые слова: LTS, cable-in-conduit conductor, NbTi, test results, EDIPO, design parameters, SULTAN, comparison, n-value, ac magnetic field dependence, pressure drop, dc performance, test results
Ключевые слова: HTS, power equipment, cables, dc performance, thermosyphon, nitrogen liquid , cryogenic systems, pressure drop, experimental results
Ключевые слова: power equipment, power transmission lines, design, nitrogen liquid , cryogenic systems, HTS, pressure drop, numerical analysis, experimental results
Ключевые слова: fusion magnets, LTS, cable-in-conduit conductor, modeling computational, pressure drop, pressure effect, high field magnets
Sun J., Yamada H., Yamaguchi S., Hamabe M., Iiyoshi A., Watanabe H., Sugino M., Kawahara T., Ivanov Y.
Ключевые слова: power equipment, HTS, cables, dc performance, cryogenic systems, cryogenic pumps, pressure drop
Ключевые слова: shipboard applications, HTS, cables, dc performance, Bi2223, tapes, YBCO, coated conductors, economic analysis, MgB2, cables in separated cryostat, design, twisting, cryogenic systems, termination, current leads, pressure drop, power distribution system, dissipative properties, losses, review, presentation, power equipment
Ключевые слова: nitrogen liquid , nitrogen solid, phase composition, measurement setup, pressure drop, experimental results, tubes, friction
Ключевые слова: cryogenic systems, cryogenic pumps, cryogen transfer line, power transmission lines, cables, nitrogen liquid , pressure drop, HTS, power equipment
Ключевые слова: LTS, cable-in-conduit conductor, pressure drop, forced flow conductor, cooling technology, porosity, friction, experimental results
Ключевые слова: cryogenic systems, helium, phase composition, forced flow, measurement technique, sensors, pressure drop
Ключевые слова: LTS, cable-in-conduit conductor, friction, porosity, forced flow, cooling technology, pressure drop, numerical analysis
Ключевые слова: presentation, HTS, Bi2223, cables triaxial, FCL three-phase, test results, fault currents, cryocoolers, joints, current-voltage characteristics, cryogenic systems, pressure drop, heat transfer, dielectrics, high voltage process, collaborations, power equipment, critical caracteristics
Matsui K., Okuno K., Hamada K.(hamada@naka.jaeri.go.jp), Takahashi Y., Kato T.
Ключевые слова: LTS, Nb3Sn, cable-in-conduit conductor, pressure drop, magnets, ITER, numerical analysis, power equipment, magnetic properties
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