Ключевые слова: detector, size effect, magnets, coils solenoidal, design parameters, LTS, NbTi, Rutherford cables, cryogenic systems, helium, thermosyphon, test long-term operation
Bragin A.V., Mezentsev N.A., Syrovatin V.M., Khrushchev S.V., Shkaruba V.A., Tsukanov V.M., Erokhin A.I., Kholopov M.A., Kremnev A.A.
Ключевые слова: detector, magnets dipole, design, design parameters, cooling technology, thermosyphon, LTS, NbTi, wires, coils
Ключевые слова: thermosyphon, magnets, cooling technology, modeling, experimental results
Hervieu B., Berriaud C., Thuillier T., Vallcorba R., Segreti M., Sinanna A., Rochepault E., Ghribi A., Simon D., MINIER G., Cadoux T., Mora E.F., Gregoire L., Bakon N.
Ключевые слова: ion sources, magnets, design, design parameters, LTS, NbTi, coils solenoidal, cryogenic systems, cryocoolers, thermosyphon, current leads, HTS, quench protection
Ключевые слова: measurement setup, detector, LTS, NbTi, Rutherford cables, cryogenic systems, helium, coils solenoidal, magnetic field distribution, magnets dipole, thermosyphon, facility
Morita M., Izumi M., Teshima H., Ida T., Miki M., Tsuzuki K., Felder B., Englebretson S., Shaanika E., Bocquel C., Chin R., Kolehmainen J.
Ключевые слова: rotating machines, propulsion system, motors synchronous, design, design parameters, thermosyphon, rotors, HTS, GdBCO, bulk, magnetization, cryocoolers, measurement setup, ac losses, friction, trapped field, prototype, fabrication, test results
Mueller H., Quettier L., Pes C., Madur A., Graffin P., Winkler M., Allain H., Reymond H., Cho E.J., Munoz-Garcia J., Rasamimanana O.
Ключевые слова: magnets dipole, accelerator magnets, design, thermosyphon, LTS, NbTi, flux density, distribution, cryogenic systems
Izumi M., Yamagata K., Miki M., Ikeda T., Yamaguchi K., Yanamoto T., Murase Y., Kashima H., Yanase E.
Ключевые слова: cryogenic systems, cooling technology, thermosyphon, thermal stability, heat loads, transient performance, HTS, coils, motors, rotors, cryocoolers, prototype, experimental results, rotating machines, loop
Ключевые слова: HTS, MgB2, magnets, cooling technology, cryocoolers, thermosyphon, hydrogen, helium, comparison, loop
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
Ключевые слова: detector, coils solenoidal, design, thermal performance, heat loads, cryogenic systems, cooling technology, thermosyphon, shields, thermal stress
Ключевые слова: rotating machines, generators, rotors, HTS, GdBCO, coated conductors, coils racetrack, thermosyphon, neon liquid, design, design parameters, cryogenic systems, fabrication, test results
Ключевые слова: MgB2, HTS, magnets, cooling technology, thermosyphon, cryocoolers, helium liquid, hydrogen liquid, nitrogen liquid , loop
Ivanyushenkov Y., Shiroyanagi Y., Doose C., Hasse Q., Kasa M., Skiadopoulos D., Trakhtenberg E.M., Fuerst J.D.
Ключевые слова: undulator, cryogenic systems, cryostat, cryocoolers, prototype, HTS, current leads, helium liquid, thermosyphon, heat loads, fabrication
Ключевые слова: thermosyphon, cooling technology, coils solenoidal, magnets, cryogenic systems, LTS, NbTi, heat loads
Shintomi T., Takao T., Miyagi D., Tsuda M., Hamajima T., Makida Y., Ota N., Kajiwara M., Asami T., Suzuki G., Hirose J.
Ключевые слова: power equipment, renewable energy systems, SMES, MgB2, coils, design, thermosyphon, design parameters, cryogenic systems, new
Ключевые слова: rotating machines, motors synchronous, cryogenic systems, helium, neon, thermosyphon, cooling technology, stability, heat loads, HTS, experimental results
Kim J., Sivasubramaniam K., Weeber K., Laskaris E.T., Duckworth R., Rochford J., Amm K., Stautner W., Fair R., Douglass M., Rajput-Ghoshal R., Moscinski M., Riley P., Wagner D., Hou S., Bray J., Fulton L., Longtin R.
Ключевые слова: rotating machines, cryogenic systems, cooling technology, joints, helium, neon, thermosyphon, heat loads, experimental results, HTS, motors
Shintomi T., Takao T., Miyagi D., Tsuda M., Hamajima T., Makida Y., Munakata K., Kajiwara M., Asami T., Suzuki G.
Ключевые слова: SMES, cryogenic systems, hydrogen liquid, coils, MgB2/Al, ac losses, thermosyphon
Ключевые слова: cryogenic systems, cooling technology, heat transfer, thermosyphon, nitrogen liquid , experimental results
Shintomi T., Takao T., Miyagi D., Hamajima T., Makida Y., Tsuda S., Tanoue N., Ota N., Munakata K., Miwa Y.
Ключевые слова: SMES, hydrogen liquid, renewable energy systems, design, thermosyphon, cooling technology, coils, MgB2, loads, power equipment, new
Ключевые слова: HTS, power equipment, cables, dc performance, thermosyphon, nitrogen liquid , cryogenic systems, pressure drop, experimental results
Fazilleau P., Baudouy B., Hervieu B., Mayri C., Berriaud C., Gastineau B., Massinger M., Medioni D., Polinski J., Wone M., Bessette A., Bouziat D., Graffin P., Bigaut M.L.
Ключевые слова: thermosyphon, Rutherford cables, joints, magnets dipole, coils racetrack, test results, loop
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