Lorin C., Maksoud W.A., Berriaud C., Nunio F., Calvelli V., Dilasser G., Stacchi F., Lottin J.-., Pontarollo T.
Ключевые слова: detector, LTS, NbTi, cable-in-conduit conductor, coils, cryogenic systems, stability, helium superfluid, magnets, prototype, design, mechanical properties
Ключевые слова: measurement setup, facility, cryogenic systems, helium superfluid, cooling technology, cryostat, design, magnets, test results
Ключевые слова: LHC, upgrade, luminosity, LTS, Nb3Sn, magnets, impregnation, temperature distribution, homogeneity, heat transfer, cryogenic systems, helium superfluid, modeling, numerical analysis
Bredy P., Juster F.P., Scola L., Vedrine P., Quettier L., Belorgey J., Lannou H., Molinie F., Berriaud C., Gilgrass G., Nunio F., Aubert G., Touzery R., Dubois O., Sinanna A., Dilasser G., Guihard Q., Jannot V., Amadon A., Bonnelye C., Boulant N., Gras V., Lepretre F., Lerman C., Ster C.L., Mauconduit F., Vignaux A.
Bredy P., Juster F.P., Scola L., Quettier L., Belorgey J., Lannou H., Molinie F., Stepanov V., Touzery R., Dubois O., Sinanna A., Guihard Q., Jannot V., Bonnelye C., Lepretre F., Roger A.
Ключевые слова: MRI magnets, LTS, NbTi, cooling technology, helium superfluid, design, cryogenic systems
Hobl A., Gehring M., Lorin C., Wu H., Maksoud W.A., Steinmann J., Allard J., Amend J., Schaffran J., Berriaud C. and 20 Authors, Majorovits B., Kreikemeyer-Lorenzo D., Caldwell A., Zoeller H.
Lorin C., Mayri C., Maksoud W.A., Berriaud C., Nunio F., Calvelli V., Dilasser G., Stacchi F., Duraсona U., Pontarollo T., Lottin J., Denarie L.
Ключевые слова: magnets dipole, new, LTS, NbTi, strands, cable-in-conduit conductor, cables, wrapping, Cu-based conductors, helium superfluid, tensile tests, mechanical properties, numerical analysis
Lorin C., Maksoud W.A., Berriaud C., Nunio F., Calvelli V., Dilasser G., Stacchi F., Duraсona U., Pontarollo T., Lottin J.
Scola L., Baudouy B., Lorin C., Maksoud W.A., Berriaud C., Nunio F., Allard J., Moliniй F., Godon P., Calvelli V., Dilasser G., Guihard Q., Solenne N., Stacchi F., GODON R., Duraсona U., Lottin J.-., Pontarollo T., Denarie L., Donga T., Drouen Y., Jurie S., Juster F.-., Millot J.-., Correia-Machado R., Segrestan L.
Scola L., Lorin C., Maksoud W.A., Berriaud C., Godon P., Solenne N., Stacchi F., GODON R., Duraсona U., Pontarollo T., Donga T., Drouen Y., Jurie S., Correia-Machado R., Segrestan L.
Ключевые слова: medical applications, MRI magnets, high field magnets, cryogenic systems, helium superfluid
Juster F.P., Pugnat P., Hervieu B., Ronayette L., Molinie F., Berriaud C., Berthier R., Pfister R., Barbier R., Grandclement C., Yildiz E., Graffin P., Boujet T., Pelloux M., Neyrial H., Verney E., Jousset J*1., Kamke M., Schneider-Muntau H.J*3.
Ключевые слова: Tokamak, magnetic systems, coils toroidal, design, design parameters, LTS, NbTi, cryogenic systems, helium superfluid, quench state, neutron irradiation, gamma irradiation, thermal-hydraulics, electrical field, modeling, minimum quench energy, quench properties, heat transfer, hot spots
Baudouy B., Lorin C., Maksoud W.A., Berriaud C., Calvelli V., Dilasser G., Stacchi F., Duraсona U., Lottin J.-., Pontarollo T.
Juster F.P., Pugnat P., Hervieu B., Ronayette L., Molinie F., Berriaud C., Pfister R., Barbier R., Grandclement C., Yildiz E., Graffin P., Boujet T., Pelloux M., Jousset J.
Claudet S., Claudet S., Brodzinski K., Brodzinski K., Capatina O., Capatina O., Capelli T., Capelli T., Delprat L., Delprat L.
Ключевые слова: LHC, luminosity, cryogenic systems, design, helium superfluid, cavity, thermal performance, screen, modeling, numerical analysis
Ключевые слова: cryogenic systems, compression, helium superfluid, design, design parameters, refrigerator, bearing magnetic, HTS, stators, YBCO, bulk, rings, fabrication, displacements, loads, levitation performance, experimental results
Ключевые слова: Europe, coils toroidal, LTS, NbTi, helium superfluid, quench detection, quench protection, quench properties, Tokamak
Pugnat P., Fazilleau P., Debray F., Hervieu B., Ronayette L., Molinie F., Berriaud C., Berthier R., Queinec Y., Pfister R., Barbier R., Graffin P., Vincent B., Hanoux P., Boujet T., Pelloux M., Peroni C., Neyrial H.
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 structure
Ключевые слова: LHC, accelerator magnets, cryogenic systems, helium superfluid, insulation, porosity, modeling, numerical analysis, quench, experimental results
Ключевые слова: measurement setup, design, fabrication, quench protection, magnets quadrupole, LTS, Nb3Sn, cryogenic systems, helium superfluid, power supply, training effect, test results, facility
Pugnat P., Ronayette L., Pfister R., Pissard M., Hanoux P., Tudela J., Boujet T., Peroni C., Disparti T.
Ключевые слова: LHC, luminosity, cryostat, design, magnets, helium superfluid, cooling technology, new
Schild T., Aubert G., Belorgey J., Berriaud C., Bourquard A., Bredy P., Dubois O., Gilgrass G., Juster F.P., Lannou H., Molinie F., Nusbaum M., Nunio F., Payn A., Quettier L., Scola L., Sinanna A., Stepanov V., Vedrine P.
Ключевые слова: MRI magnets, coils pancake, stacked blocks, LTS, NbTi, helium superfluid, shields, design, status
Ключевые слова: magnets, cryogenic systems, cooling technology, helium superfluid, cryogenic pumps, modeling
Ключевые слова: LHC, magnets dipole, magnets quadrupole, cables, heat transfer, LTS, NbTi, helium superfluid, insulation, experimental results
Ключевые слова: LTS, Nb3Sn, coils wind-and-react, insulation, helium superfluid, thermal properties, thermal conductivity, experimental results
Pugnat P., Fazilleau P., Debray F., Hervieu B., Ronayette L., Trophime C., Berriaud C., Berthier R., Massinger M., Pfister R., Manil P.
Ключевые слова: cryogenic systems, hybrid systems, magnets, design parameters, NbTi, LTS, coils, cryostat, design, helium superfluid, thermal-hydraulics
Pugnat P., Fazilleau P., Debray F., Hervieu B., Ronayette L., Trophime C., Berriaud C., Pes C., Berthier R., Massinger M., Pfister R., Manil P., Barbier R*2., Pissard M.
Ключевые слова: magnets, hybrid systems, magnets permanent, LTS, NbTi, Rutherford cables, design parameters, helium superfluid, cryogenic systems, status, plans
Verweij A., Willering G., Bajko M., Savary F., Prin H., Giloux C., Dahlerup-Petersen K., Bermudez S.I., Bednarek M.J., D’Angelo G., Dib G., Grand-Clement L., Moron-Ballester R., Roger V.
Ключевые слова: LTS, NbTi, Rutherford cables, helium superfluid, insulation, heat transfer, measurement setup, measurement technique
Ключевые слова: LTS, Nb3Sn, cables, insulation, heat transfer, LHC, high field magnets, helium superfluid, test results, impregnation, thermal conductivity, temperature distribution
Ключевые слова: presentation, cryogenic systems, review, current leads, Bi2223, tapes, helium superfluid, upgrade
Ключевые слова: LTS, NbTi, cables, insulation, heat transfer, helium superfluid, magnets dipole, experimental results, modeling, cryogenic materials, thermal conductivity, LHC
Ключевые слова: LTS, Nb3Sn, helium superfluid, accelerator magnets, numerical analysis, modeling, temperature distribution, quench, high field magnets
Ключевые слова: helium superfluid, cryogenic materials, resistance, thermal conductivity, insulation, experimental results
Ключевые слова: MRI magnets, coils, helium superfluid, pressure effect, quench, thermal-hydraulics, modeling, experimental results
Ключевые слова: LHC, helium superfluid, heat transfer, cables, insulation, numerical analysis, modeling, accelerator magnets, high field magnets
Musenich R., McInturff A., Siemko A., Lebedev A., Becker R., Bollweg K., Burger J., Capell M., Datskov V.I., Gallilee M.A., Gargiulo C., Kounine A., Koutsenko V., Schinzel D., Stiff K.J., Zeigler J.C.
Ключевые слова: space application, spectrometer, magnets dipole, coils racetrack, test results, LTS, NbTi, helium superfluid
Ключевые слова: cryogenic systems, cryostat, helium superfluid, cooling technology, pulse tube cryostat
Juster F.P., Meuris C., Maksoud W.A., Chesny P., Lannou H., Molinie F., Vieillard L., Schild T., Donati A.
Ключевые слова: LTS, NbTi, coils pancake, magnets, helium superfluid, quench properties, normal zone propagation, pressure effect, experimental results
Joss W., Juster F.P., Pugnat P., Fazilleau P., Bourquard A., Bresson D., Dael A., Debray F., Hervieu B., Mayri C., Rifflet J.M., Ronayette L., Trophime C.
Ключевые слова: hybrid systems, magnets, LTS, NbTi, Rutherford cables, cable-in-conduit conductor, helium superfluid, coils, design parameters, cryogenic systems, test results, new
Ключевые слова: cable-in-conduit conductor, ITER, heat transfer, helium superfluid, numerical analysis, experimental results, LTS, NbTi, power equipment
Ключевые слова: LTS, NbTi, wires, surface, stability, helium superfluid, voltage waveforms, flux density, heat transfer, coils model, experimental results, power equipment
Shirai Y., Shiotsu M., Shigemasu S., Ohya M.(ohya@pe.energy.kyoto-u.ac.jp), Imagawa S.(Imagawa@LHD.nifs.ac.jp)
Ключевые слова: LTS, NbTi, wires, coils, cryostability, helium superfluid, surface, voltage waveforms, heat transfer, experimental results, power equipment
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