Ключевые слова: accelerator magnets, coils, quench propagation, quench protection, modeling, resistance, temperature distribution
Verweij A.P., Rijk G., Russenschuck S., Perez J.C., Kirby G., Mentink M., Koettig T., Nugteren J.v., Petrone C., Pincot F.O., Bortot L., Schops S., Pentella M., Deferne G.
Verweij A.P., Ambrosio G., Ferracin P., Todesco E., Wollmann D., Rodriguez-Mateos F., Bajas H., Mentink M., Ravaioli E., Bermudez S.I., Duda M., Marinozzi V., Troitino J.F., Mangiarotti F.
Ключевые слова: LHC, luminosity, LTS, Nb3Sn, magnets quadrupole, quench protection, quench current, hot spots, modeling, numerical analysis
Verweij A.P., Auchmann B., Mentink M., Nugteren J.v., Maciejewski M., Bortot L., Garcia I.C., Gersem H.D., Schцps S.
Ключевые слова: HTS, accelerator magnets, eddy currents, coils, magnetization, numerical analysis, flux density, bulk, tapes
Verweij A.P., Charifoulline Z., Ravaioli E., Maciejewski M., Prioli M., Bortot L., Liakopoulou A., Annema A.J., Salm C., Schmitz J.
Ключевые слова: LHC, magnets dipole, series connection, modeling, transient performance, short circuit test
Ключевые слова: FCC, magnets dipole, LTS, Nb3Sn, design, design parameters, quench protection
Verweij A.P., Auchmann B., Mentink M., Ravaioli E., Maciejewski M., Navarro A.M., Prioli M., Bortot L., Garcia I.C., Schps S.
Ключевые слова: LHC, accelerator magnets, magnetic circuit, quench, modeling, numerical analysis, LTS, Nb3Sn, magnets quadrupole, temperature distribution, voltage distribution, hot spots
Verweij A.P., Auchmann B., Maciejewski M., Navarro A.M., Prioli M., Bortot L., Garcia I.C., Bayrasy P., Wolf K., Wilczek M., Griesemer T., Schops S.
Tommasini D., Arbelaez D.*11, Auchmann B., Bajas H., Bajko M., Ballarino A., Barzi E.*10, Bellomo G., Benedikt M., Bermudez S.I., Bordini B., Bottura L., Brower L.*11, Buzio M., Caiffi B., Caspi S.*11, Dhalle M., Durante M., DeRijk G., Fabbricatore P., Farinon S., Ferracin P., Gao P., Gourlay S.*11, Juchno M.*11, Kashikhin V.*10, Lackner F., Lorin C., Marchevsky M.*11, Marinozzi V., Martinez T., Munilla J., Novitski I.*10, Ogitsu T., Ortwein R., Perez J.C., Petrone C., Prestemon S.*11, Prioli M., Rifflet J., Rochepault E., Russenschuck S., Salmi T., Savary F., Schoerling D., Segreti M., Senatore C., Sorbi M., Stenvall A., Todesco E., Toral F., Verweij A.P., Wessel S., Wolf F., Zlobin A.V.*10
Verweij A.P., Auchmann B., Mentink M., Ravaioli E., Bermudez S.I., Maciejewski M., Navarro A.M., Prioli M., Bortot L., Yammine S.
Ключевые слова: LHC, luminosity, magnets dipole, LTS, Nb3Sn, quench protection, design parameters, modeling, current waveforms, upgrade
Volpini G., Fabbricatore P., Dhalle M., Bottura L., Ogitsu T., Farinon S., Verweij A.P., Ferracin P., Senatore C., Wessel S., Bellomo G., Sorbi M., Bordini B., Toral F., Bajko M., Savary F., Todesco E., Tommasini D., Auchmann B., Russenschuck S., Stenvall A., Ballarino A., Lorin C., Rijk G.d., Bajas H., Salmi T., Schoerling D., Buzio M., Lackner F., Durante M., Segreti M., Rochepault E., Martinez T., Bermudez S.I., Gao P., Marinozzi V., Benedikt M., Perez J., Rifflet J., Munilla J., Ortwein R., Prioli M., Wolf F.
Ключевые слова: FCC, magnets dipole, LTS, Nb3Sn, coils racetrack, model small-scale, design parameters
Ключевые слова: LTS, Nb3Sn, accelerator magnets, magnets dipole, quench protection, hot spots, comparison, FCC
Verweij A.P., Ambrosio G., Ferracin P., Sabbi G., Todesco E., Auchmann B., Rodriguez-Mateos F., Ravaioli E., Maciejewski M.
Ключевые слова: accelerator magnets, quench, quench protection, LHC, magnets dipole, hot spots
Verweij A.P., Willering G., Kirby G., Ravaioli E., Datskov V.I., ten Kate H.H.J., Dib G., Maciejewski M., Fernandez N.A.
Verweij A.P., Willering G., Kirby G., Kate H.H., Ravaioli E., Datskov V.I., Dib G., Maciejewski M., Navarro A.M.
Verweij A.P., Auchmann B., Kirby G., Kate H.H., Ravaioli E., Dahlerup-Petersen K., Datskov V.I., Maciejewski M., Ghini J.B., Navarro A.M., Mateos F.R.
Ключевые слова: LTS, Nb3Sn, magnets quadrupole, LHC, luminosity, quench protection, accelerator magnets, design parameters, hot spots, thermal performance
Ключевые слова: colliders, accelerator magnets, magnets dipole, LTS, Nb3Sn, quench protection, design, design parameters, hot spots, thermal properties
Verweij A.P., Willering G., Feuvrier J., Bajas H., Kirby G., Kate H.H., Ravaioli E., Datskov V.I., Desbiolles V., Maciejewski M.
Ключевые слова: accelerator magnets, magnets quadrupole, quench protection, modeling, design parameters, experimental results, LTS, NbTi
Ключевые слова: quench protection, ac losses, thermal properties, electro-thermal model, numerical analysis, magnets, modeling, coils, dynamic operation
Verweij A.P., Sabbi G., Feuvrier J., Bajas H., Kirby G., Ravaioli E., Datskov V.I., ten Kate H.H.J., Desbiolles V., Maciejewski M.
Ключевые слова: LTS, Nb3Sn, accelerator magnets, quench protection, magnets quadrupole, hot spots, experimental results, high field magnets, new
Verweij A.P., Willering G., Feuvrier J., Kirby G., Kate H.H., Ravaioli E., Datskov V.I., Sperin K.A., Desbiolles V., Maciejewski M.
Ключевые слова: magnets quadrupole, quench protection, accelerator magnets, coils, LTS, NbTi, experimental results, high field magnets
Verweij A.P., Auchmann B., Kirby G., Kate H.H., Ravaioli E., Dahlerup-Petersen K., Datskov V.I., Maciejewski M., Ghini J.B., Navarro A.M., Mateos F.R.
Ключевые слова: accelerator magnets, LTS, Nb3Sn, magnets quadrupole, quench protection, LHC, luminosity, design parameters, hot spots, thermal performance, high field magnets
Ключевые слова: accelerator magnets, ac losses, coils, quench protection, NbTi, coils solenoidal, resistance, numerical analysis, experimental results, high field magnets, new
Ключевые слова: high field magnets, protective system, quench protection, magnets quadrupole, hot spots, temperature distribution, new
Verweij A.P., Sabbi G., Feuvrier J., Bajas H., Kirby G., Kate H.H., Ravaioli E., Datskov V.I., Desbiolles V., Maciejewski M.
Ключевые слова: LTS, Nb3Sn, quench protection, accelerator magnets, magnets quadrupole, design parameters, hot spots, test results, protective system, high field magnets, new
Ключевые слова: measurement technique, magnetization, accelerator magnets, high field magnets
Ключевые слова: LHC, joints, thermoelectric properties, numerical analysis, modeling, LTS, cables, NbTi, stabilizing layers, magnets dipole, magnets quadrupole, defects, series connection, design parameters
Ключевые слова: accelerator magnets, irradiation effects, magnets quadrupole, modeling, thermal performance, high field magnets
Ключевые слова: accelerator magnets, magnetization, measurement technique, high field magnets
Verweij A.P., Scheuerlein C., Bertinelli F., Fessia P., Mathot S., Willering G.P., ten Kate H., Perin A., Sgobba S., Steckert J., Tock J.-P., Lasheras N., Charifoulline Z., Denz R., Garion C., Koratzinos M.
Ключевые слова: LTS, LHC, joints, joint resistances, bus bar conductor, critical caracteristics, current-voltage characteristics, experimental results
Ключевые слова: accelerator magnets, LHC, thermal runaway, stabilizing layers, shunt, joints, experimental results, high field magnets
Ключевые слова: transformers, LTS, NbTi, Rutherford cables, experimental results, power equipment, facility
Kuijper A.(anton.kuijper@cern.ch), Verweij A.P., ten Kate H.
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