Carcagno R., Feher S., Song H., Anerella M., Marone A., Muratore J., Wanderer P., Baldini M., Joshi P., Sabbi G., Cheng D., Kovach P., Apollinari G., Amm K., Marchevsky M., Pan H., Chlachidze G., Ravaioli E., Marinozzi V.
Ключевые слова: LHC, luminosity, upgrade, LTS, Nb3Sn, magnets quadrupole, design, design parameters, prototype, fabrication, test results, quench, training effect, quench current
Ogitsu T., Sasaki K., Sugano M., Tanaka K., Tanaka K., Takahashi N., Nakamoto T., Suzuki K., Kimura N., Higashi N., Iida M., Ohhata H., Ikeda H., Okada R., Musso A., Ikemoto Y., Okada N., Kawamata H.
Ключевые слова: spectrometer, coils solenoidal, training effect, accelerator magnets, modeling, numerical analysis, displacements, thermal properties
Ogitsu T., Sasaki K., Sugano M., Tanaka K., Takahashi N., Nakamoto T., Suzuki K., Kimura N., Higashi N., Iida M., Todesco E., Okada R., Musso A., Ikemoto Y., Okada N., Kawamata H., Enomoto S., Ohata H.
Ключевые слова: LHC, luminosity, magnets dipole, model small-scale, training effect, mechanical properties, LTS, NbTi, quench current, stress effects, coils, deformation, experimental results, upgrade
Ferracin P., Willering G., Rijk G.d., Perez J.C., Manil P., Guinchard M., Rochepault E., Rondeaux F., Bourcey N., Rifflet J., Grosclaude P.
Nugteren J.v., Kirby G., Bajas H., Bajko M., Ballarino A., Bottura L., Chiuchiolo A., Contat P., Dhalle M., Durante M., Fazilleau P., Fontalva A., Gao P., Goldacker W., Kate H.t., Kario A., Lahtinen V., Lorin C., Markelov A., Mazet J., MOLODYK A., Murtomaki J., Long N., Perez J., Petrone C., Pincot F., Rijk G.d., Rossi L., Russenschuck S., Ruuskanen J., Schmitz K., Stenvall A., Usoskin A., Willering G., Yang Y.
Ключевые слова: accelerator magnets, magnets dipole, coils insert, HTS, GdBCO, coated conductors, helium gas, Roebel conductors, cables, cooling technology, design parameters, quench detection, RRR parameter, training effect, degradation studies, critical caracteristics, current-voltage characteristics, n-value, temperature dependence, magnetic field distribution, quench current, current decay, joint resistances, test results
Ключевые слова: accelerator magnets, magnets quadrupole, prototype, training effect, quench, quench propagation, test results
Ambrosio G., Dietderich D., Ferracin P., Tartaglia M., Wang X., Anerella M., Ghosh A., Schmalzle J., Wanderer P., Orris D., Sylvester C., Dimarco J., Hafalia A.R., Bossert R., Sabbi G., Todesco E., Cheng D., Marchevsky M., Pan H., Prestemon S., Yu M., Chlachidze G., Velev G., Holik E.F., Salmi T., Perez J.C., Guinchard M., Nobrega A., Ravaioli E., Krave S., Bermudez S.I., Grosclaude P., Cavanna E., Stoynev S., Strauss T., Vallone G., Felice H.* 5
Ключевые слова: LHC, luminosity, LTS, Nb3Sn, magnets quadrupole, model small-scale, test results, mechanical properties, stress effects, strain effects, quench current, training effect, upgrade
Ambrosio G., Ferracin P., Pan H., Prestemon S., Cheng D.W., Chlachidze G., Bajas H., Perez J.C., Guinchard M., Bourcey N., Bermudez S.I., Juchno M., Grosclaude P., Strauss T., Vallone G.
Ключевые слова: measurement setup, design, fabrication, quench protection, magnets quadrupole, LTS, Nb3Sn, cryogenic systems, helium superfluid, power supply, training effect, test results, facility
Boffo C., Holubek T., Walter W., Casalbuoni S., Grau A., Turenne M., Jauregui D.S., Glamann N., Gerhard T.
Ключевые слова: LTS, NbTi, wires, test results, undulator, coils, conduction cooled systems, fabrication, training effect, stability, thermal performance
Bottura L., Ambrosio G., Ferracin P., Tartaglia M., Wang X., Rossi L., Schmalzle J., Wanderer P., Dimarco J., Bordini B., Bossert R., Willering G., Sabbi G., Bajko M., Savary F., Cheng D., Fleiter J., Apollinari G., Ballarino A., Prestemon S., Yu M., Chlachidze G., Velev G., Rijk G.d., Bajas H., Salmi T., Lackner F., Guinchard M., Ravaioli E., Bermudez S.I., Hafalia A., Holik E., Cavanna E., Stoynev S., Strauss T., Vallone G., Todesco E.., Annarella M., Marchevsky M.*4 Loeffler C., Nobrega A.*3 Perez J.C.
Ключевые слова: LHC, luminosity, LTS, Nb3Sn, accelerator magnets, magnets dipole, critical caracteristics, coils, strands, current density, RRR parameter, design, design parameters, quench protection, training effect
Ключевые слова: LHC, luminosity, magnets dipole, LTS, Nb3Sn, PIT process, RRP process, coils racetrack, test results, design, design parameters, fabrication, loads, training effect, quench current, mechanical properties, stress effects, test results
Bottura L., Ferracin P., Bordini B., Willering G., Bajko M., Rifflet J.M., Feuvrier J., Rijk G.d., Bajas H., Perez J.C., Manil P., Durante M., Rochepault E., Rondeaux F., Bourcey N., Duda M., Petrone C., Grosclaude P., Mangiarotti F.
Ключевые слова: LTS, Nb3Sn, Rutherford cables, magnets dipole, cooling technology, quench protection, high field magnets, training effect, hot spots, test results
Bottura L., Bordini B., Bajko M., Savary F., Feuvrier J., Rijk G.d., Bajas H., Fiscarelli L., Bermudez S.I., Perez J., Loffler C., Nilsson E., Willering C., Mangiarotti F.
Ключевые слова: LHC, magnets dipole, LTS, Nb3Sn, coils model, high field magnets, cooling technology, training effect, quench current, test results
Fiscarelli L., Juchno M., Bermudez S.I., Guinchard M., Kopal J., Lackner F., Marchevsky M., Nobrega F., Pan H., Perez J.C., Prin H., Ravaioli E., Rossi L., Sabbi G., Tavares S.S., Steckert J., Stoynev S., Todesco E., Vallone G., Wanderer P., Wang X., Yu M., Bajas H., Ambrosio G., Ballarino A., Bajko M., Bordini B., Bourcey N., Cheng D.W., Cabon M., Chiuchiolo A., Chlachidze G., Felice H.
Ключевые слова: LHC, luminosity, high field tests, LTS, Nb3Sn, magnets quadrupole, quench properties, measurement setup, critical caracteristics, current, magnetic field dependence, high voltage process, quench protection, heater, training effect, quench current, flux jumps, RRR parameter, inductance, test results, upgrade
Bottura L., Rossi L., Verweij A., Willering G., Siemko A., Bajko M., Fessia P., Hagen P., Modena M., Todesco E., Tommasini D., Auchmann B., Schmidt R., Rijk G.d., Perez J.C., Tock J.P., Naour S.L., Bruning O., Mapelli D.
Ключевые слова: LHC, magnets dipole, training effect, LTS, Nb3Sn, coils, quench current, quench, distribution, thermal loads
Bottura L., Rossi L., Verweij A., Willering G., Siemko A., Bajko M., Fessia P., Hagen P., Modena M., Todesco E., Tommasini D., Auchmann B., Schmidt R., Rijk G.d., Perez J.C., Tock J.P., Naour S.L., Bruning O.
Ключевые слова: training effect, LTS, NbTi, coils, current, quench, distribution, experimental results, LHC, magnets dipole
Strauss T., Sylvester C., Tartaglia M., Todesco E., Vallone G., Velev G., Wanderer P., Wang X., Yu M., Chlachidze G., Ambrosio G., Anerella M*2., Bossert R., Cavanna E., Cheng D.W., Dietderich D.R., Dimarco J., Felice H., Ferracin P., Ghosh A.K., Grosclaude P., Guinchard M., Hafalia A.R., Holik E.F., Bermudez S.I., Krave S.T., Marchevsky M., Nobrega A., Orris D., Pan H., Perez J.C., Prestemon S., Ravaioli E., Sabbi G., Salmi T., Schmalzle J., Stoynev S.E.
Ключевые слова: LHC, luminosity, LTS, Nb3Sn, magnets quadrupole, operational performance, prototype, design, design parameters, quench, training effect, quench current, mechanical properties, strain effects, upgrade
Barzi E., Andreev N., Zlobin A.V., Rossi L., Velev G.V., Dimarco J., Turrioni D., Bossert R., Novitski I., Savary F., Auchmann B., Apollinari G., Chlachidze G., Karppinen M., Nobrega A., Smekens D., Bermudez S.I., Stoynev S., Strauss T.
Ключевые слова: LHC, LTS, Nb3Sn, magnets dipole, quench properties, quench propagation, test results, design, training effect, quench current, magnetic properties, upgrade, quality control
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