Shintomi T., Takao T., Hirano N., Hamajima T., Yagai T., Makida Y., Komagome T., Onji T., Inomata R.
Ключевые слова: LTS, Nb3Sn, wires, fibers, composites, mechanical properties, tensile tests, fracture behavior, heat treatment
Iwamoto A., Tsuda M., Shirai Y., Shiotsu M., Yagai T., Kobayashi H., Ohya M., Imagawa S., Matsumoto G., Hamaguchi S., Nagasaki Y., Maeda Y., Kawasaki R., Matsumoto F., Oya H.
Ключевые слова: HTS, Bi2223, tapes, coils, design parameters, fabrication, cooling technology, hydrogen liquid, thermal runaway, overcurrent, test results
Yagai T., Shimoyama J., Yanagisawa Y., Hamada M., Saito K., Piao R., Motoki T., Suetomi Y., Takeda Y., Matsutake Y., Nakai U.
Ключевые слова: NMR magnet, HTS, DI-Bi2223, tapes, coils insert, design, design parameters, joints superconducting , Bi2223, current-voltage characteristics, persistent current mode, coils outer, LTS, test results
Kikuchi A., Shintomi T., Nishijima G., Takao T., Hirano N., Hamajima T., Matsumoto A., Yagai T., Takahashi M., Makida Y., Komagome T., Onji T., Inomata R.
Ключевые слова: SMES, MgB2, wires round, design parameters, Rutherford cables, cryogenic systems, hydrogen liquid, helium liquid, cooling technology, mechanical properties, strain effects, measurement setup, voltage waveforms, critical current, quench, heater, normal zone propagation, stability, test results
Ключевые слова: LTS, Nb3Sn, wires, fabrication, bronze process, doping effect, microstructure, critical caracteristics, grain size, composition, distribution, Jc/B curves, experimental results
Iwamoto A., Tsuda M., Shirai Y., Shiotsu M., Yagai T., Kobayashi H., Imagawa S., Hamaguchi S., Nagasaki Y., Kawasaki R., Ohya H., Matsumoto F.
Ключевые слова: HTS, DI-Bi2223, tapes, critical caracteristics, critical current, magnetic field dependence, magnets, coils pancake, design, design parameters, fabrication, test results, cooling technology, nitrogen liquid , hydrogen liquid, thermal runaway, cryostability, current-voltage characteristics, heat generation
Ключевые слова: LTS, Nb3Sn, bronze process, fabrication, doping, composition, electron diffraction, microstructure, grain alignment, critical caracteristics, Jc/B curves, n-value, experimental results
Ключевые слова: LTS, Nb3Sn, wires, fabrication, internal tin method, diffusion process, doping effect, microstructure, critical caracteristics, Jc/B curves
Shintomi T., Takao T., Tomita M., Tsukada K., Hirano N., Hamajima T., Kobayashi Y., Yagai T., Ishihara A., Komagome T., Onji T., Hira M., Makida Y.-3
Shintomi T., Takao T., Tomita M., Tsukada K., Hirano N., Miyagi D., Tsuda M., Hamajima T., Yagai T., Makida Y., Arai Y., Ishihara A., Komagome T., Onji T., Hira M.
Ключевые слова: MgB2, strands, design parameters, Rutherford cables, coils wind-and-react, coils, react-and-wind technique, cryogenic systems, hydrogen liquid, SMES, mechanical properties, strain effects, twisting, experimental results, critical caracteristics, critical current, magnetic field dependence
Ключевые слова: HTS, DI-Bi2223, tapes multifilamentary, joints superconducting , melting, NMR magnet, MRI magnets, X-ray diffraction, microstructure, critical caracteristics, current-voltage characteristics, critical current, temperature dependence, n-value, magnetic field dependence, persistent current mode, experimental results
Shintomi T., Takao T., Tomita M., Tsukada K., Hirano N., Miyagi D., Tsuda M., Hamajima T., Yagai T., Makida Y., Arai Y., Ishihara A., Komagome T., Okubo T., Kamibayashi M., Onji T., Jimbo M., Hira M., Kuwabara Y.
Ключевые слова: MgB2, strands, Rutherford cables, coils, SMES, coils pancake, design parameters, heat transfer, stability, test results, numerical analysis, temperature distribution
Nakamura S., Kato T., Kitaguchi H., Yagai T., Kobayashi S., Shimoyama J., Nakashima T., Yanagisawa Y., Motoki T., Suetomi Y., Takeda Y., Matsutake Y.
Kikuchi A., Shintomi T., Takao T., Tomita M., Tsukada K., Hirano N., Hamajima T., Yagai T., Makida Y., Komagome T., Kamibayashi M., Onji T., Jimbo M., Kuwabara Y.
Shintomi T., Takao T., Tomita M., Tsukada K., Hirano N., Miyagi D., Tsuda M., Hamajima T., Yagai T., Makida Y., Arai Y., Komagome T., Okubo T., Mizuno S., Mizuochi S., Kamibayashi M., Jinbo M., Onji T.
Ключевые слова: MgB2, strands, mechanical properties, bending process, Rutherford cables, coils pancake, design parameters, SMES, react-and-wind technique, coils wind-and-react, strain effects, twist-pitch, model small-scale, critical caracteristics, critical current, magnetic field dependence, design
Shintomi T., Takao T., Tomita M., Tsukada K., Hirano N., Fukumoto Y., Hamajima T., Kobayashi Y., Yagai T., Makida Y., Ishihara A., Komagome T., Mizuno S., Onji T.
Ключевые слова: LTS, Nb3Sn, wires multifilamentary, fabrication, doping effect, composition, internal tin method, matrix, Cu-based conductors, diffusion process, microstructure, growth rate, design parameters, magnetization, temperature distribution, critical caracteristics, Jc/B curves, experimental results
Shintomi T., Takao T., Tomita M., Tsukada K., Hirano N., Miyagi D., Tsuda M., Hamajima T., Yagai T., Makida Y., Arai Y., Komagome T., Okubo T., Mizuno S., Mizuochi S., Kamibayashi M., Jinbo M., Onji T.
Ключевые слова: critical current density, temperature distribution, uniformity, twist-pitch, stress effects, bending process, cryogenic systems, helium liquid, power equipment, voltage, fluctuations, SMES, MgB2, wires round, Rutherford cables, coils pancake, coils wind-and-react, react-and-wind technique, design, design parameters, fabrication, test results, critical caracteristics
Shintomi T., Takao T., Tomita M., Tsukada K., Hirano N., Miyagi D., Tsuda M., Hamajima T., Yagai T., Makida Y., Arai Y., Ishihara A., Komagome T., Okubo T., Mizuno S., Mizuochi S., Kamibayashi M., Onji T., Jimbo M.
Ключевые слова: SMES, MgB2, wires multifilamentary, strands, coils pancake, design, coils wind-and-react, react-and-wind technique, Rutherford cables, twist-pitch, mechanical properties, bending process, strain effects, distribution, stability, test results, critical caracteristics, critical current, magnetic field dependence, minimum quench energy, normal zone propagation
Nakamura T., Nomura S., Tsutsui H., Chikaraishi H., Yagai T., Yanagi N., Imagawa S., Kamada H., Akai H., Ryun R.D.
Nakamura T., Nomura S., Tsutsui H., Chikaraishi H., Yagai T., Yanagi N., Kimura Y., Imagawa S., Kamada H.
Ключевые слова: HTS, coated conductors, YBCO, high field magnets, helical winding, coils, winding techniques, operational performance
Nakamura T., Nomura S., Tsutsui H., Chikaraishi H., Yagai T., Yanagi N., Kimura Y., Imagawa S., Yoshida H., Kamada H., Kudo M.
Ключевые слова: HTS, YBCO, coated conductors, mechanical properties, bending process, strain effects, distribution, experimental results, coils, SMES
Ключевые слова: helical winding, coils toroidal, bending process, mechanical properties, modeling, numerical analysis, torsion strain, distribution
Shintomi T., Takao T., Hirano N., Miyagi D., Tsuda M., Sato Y., Hamajima T., Yagai T., Makida Y., Zhang Z., Komagome T., Iwaki K., Tsujigami H., Fujikawa S., Miyajima R., Hanada K.
Ключевые слова: power equipment, fluctuations, SMES, HTS, Bi2223, coils, thermosyphon, hydrogen liquid, generators, voltage waveforms, temperature rise
Mito T., Takao T., Nakamura K., Yoshida K., Yagai T., Takahata K., Imagawa S., Murakami H., Obana T., Natsume K., Hamaguchi S., Kawahara Y., Yamamoto Y.
Koizumi N., Nunoya Y., Miyagi D., Tsuda M., Hamajima T., Yagai T., Takahata K., Obana T., Morimura T.
Ключевые слова: LTS, Nb3Sn, cable-in-conduit conductor, friction, strands, contact characteristics, surface, compression, loads, measurement setup, experimental results
Koizumi N., Nunoya Y., Miyagi D., Tsuda M., Hamajima T., Yagai T., Takahata K., Obana T., Nakazawa S., Arai D., Morimura T.
Ключевые слова: LTS, Nb3Sn, strands, cable-in-conduit conductor, mechanical properties, bending process, crack formation, modeling, numerical analysis, deformation, time evolution
Koizumi N., Nunoya Y., Miyagi D., Tsuda M., Hamajima T., Yagai T., Takahata K., Obana T., Teshima S., Nakazawa S., Arai D.
Ключевые слова: LTS, Nb3Sn, cable-in-conduit conductor, joints, joint resistances, current distribution, twist-pitch, experimental results, length
Koizumi N., Nunoya Y., Miyagi D., Tsuda M., Hamajima T., Yagai T., Takahata K., Obana T., Teshima S., Nakazawa S., Arai D.
Ключевые слова: LTS, cable-in-conduit conductor, strands, displacements, NbTi, modeling, twist-pitch, deformation
Ключевые слова: LTS, Nb3Sn, strands, cable-in-conduit conductor, numerical analysis, mechanical properties
Ключевые слова: HTS, cables triaxial, power equipment, ac losses, power transmission lines, numerical analysis
Ключевые слова: HTS, YBCO, coated conductors, coils pancake, SMES, power equipment, current distribution, modeling
Ключевые слова: LTS, cable-in-conduit conductor, strands, displacements, twist-pitch, numerical analysis, experimental results
Ключевые слова: LTS, cable-in-conduit conductor, geometry effects, critical caracteristics, critical current, degradation studies, ac losses, strand geometry, NbTi, flux flow, loop
Ключевые слова: HTS, cables triaxial, Bi2223, insulating medium, thickness dependence, inductance, design parameters, twist-pitch, modeling, numerical analysis
Ключевые слова: HTS, bulk, railway applications, Maglev system, levitation performance, eddy currents, modeling
Ключевые слова: HTS, bulk, levitation performance, seismic isolation applications, experimental results, REBCO
Ключевые слова: power equipment, cables triaxial, HTS, Bi2223, fault currents, stabilizing layers, design parameters, modeling, overcurrent
Ключевые слова: power equipment, SMES, HTS, coils toroidal, current, capacity, current distribution, coils pancake, YBCO, coated conductors, design parameters, numerical analysis, dc reactor
Ключевые слова: HTS, cables triaxial, twist-pitch, ac losses, numerical analysis, power equipment
Ключевые слова: HTS, cables triaxial, experimental results, twist-pitch, Bi2223, tapes multifilamentary, voltage waveforms, cables three-phase, power equipment
Ключевые слова: HTS, cables triaxial, twist-pitch, ac losses, power equipment, numerical analysis
Ключевые слова: levitation performance, HTS, bulk, seismic isolation applications, YBCO, experimental results
Ключевые слова: HTS, cables triaxial, current distribution, ac losses, modeling, numerical analysis, power equipment
Ключевые слова: fusion magnets, SMES, control systems, power compensator, modeling, power equipment, high field magnets
Ключевые слова: HTS, cables triaxial, twist-pitch, ac losses, numerical analysis, power equipment
Ключевые слова: SMES, flywheel energy storage systems, pulsed operation, hybrid systems, modeling, economic analysis, power equipment
Ключевые слова: HTS, cables triaxial, ac losses, numerical analysis, power equipment
Ключевые слова: Maglev system, HTS, YBCO, bulk, numerical analysis, model small-scale, levitation performance
Ключевые слова: LTS, strand geometry, ac losses, cable-in-conduit conductor, NbTi, experimental results, power equipment
Ключевые слова: HTS, Bi2212/Ag, Bi2223/Ag, tapes, coils, comparison, stability, hydrogen, experimental results, power equipment
Ключевые слова: HTS, cables triaxial, current distribution, cables three-phase, numerical analysis, power equipment
Ключевые слова: HTS, current distribution, modeling, winding configurations, numerical analysis, cables triaxial, power equipment
Ключевые слова: SMES, coils solenoidal, coils toroidal, numerical analysis, power equipment, scaling law
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