Ключевые слова: LTS, Nb3Sn, Rutherford cables, NbTi, winding techniques, LHC, luminosity, FCC, deformation, mechanical properties, stability, magnets dipole, magnets quadrupole, fabrication
Ambrosio G., Ferracin P., Scheuerlein C., Savary F., Todesco E., Perez J.C., Sahner T., Prin H., Principe R., Lackner F., Luzieux S., Bourcey N., Duret M., Triquet S., Cavanna E., Revilak P., Michels M., Pozzobon M., Genestier T., Axensalva J., Semeraro M.
Ключевые слова: LHC, luminosity, LTS, Nb3Sn, magnets dipole, prototype, fabrication, coils, supporting structure, status, fabrication, heat treatment
Barzi E., Zlobin A.V., Dimarco J., Turrioni D., Novitski I., Nobrega F., Chlachidze G., Velev G., Stoynev S., Strauss T.
Ключевые слова: LHC, luminosity, accelerator magnets, LTS, Nb3Sn, magnets dipole, measurement technique, dynamic operation, comparison, NbTi, field decay, experimental results
Ambrosio G., Ferracin P., Wang X., Sabbi G., Hagen P., Todesco E., Chlachidze G., Holik E.F., Bajas H., Fiscarelli L., Bermudez S.I., Stoynev S.E., Vallone G., Marco J.D., Troitino J.F.
Ключевые слова: LHC, luminosity, LTS, Nb3Sn, accelerator magnets, magnets quadrupole, modeling, numerical analysis, design parameters, harmonic coefficients, errors
Bottura L., Bordini B., Willering G., Bajko M., Rijk G., Savary F., Bajas H., Perez J.C., Bermudez S.I.
Ключевые слова: LHC, luminosity, LTS, Nb3Sn, magnets dipole, high field magnets, coils model, quench protection, design parameters, test results, minimum quench energy
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
Ambrosio G., Wang X., Rossi L., Wanderer P., Bordini B., Nobrega F., Felice H., Sabbi G., Bajko M., Todesco E., Ballarino A., Marchevsky M., Pan H., Yu M., Cheng D.W., Chlachidze G., Bajas H., Steckert J., Perez J.C., Prin H., Lackner F., Guinchard M., Ravaioli E., Bourcey N., Chiuchiolo A., Fiscarelli L., Bermudez S.I., Juchno M., Tavares S.S., Stoynev S., Vallone G., Cabon M., Kopal J.
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
Ambrosio G., Ferracin P., Pan H., Prestemon S., Cheng D.W., Perez J.C., Lackner F., Guinchard M., Bourcey N., Bermudez S.I., Juchno M., Grosclaude P., Anderssen E., Vallone G.
Ключевые слова: LHC, upgrade, magnets quadrupole, luminosity, LTS, Nb3Sn, mechanical properties, design, stress effects, modeling
Ключевые слова: LHC, magnets dipole, luminosity, LTS, Nb3Sn, model small-scale, design, fabrication, test results, persistent current mode, dynamic operation, quality control
Ogitsu T., Sasaki K., Sugano M., Tanaka K., Takahashi N., Nakamoto T., Suzuki K., Kimura N., Higashi N., Iida M., Ohhata H., Todesco E., Okada R., Musso A., Ikemoto Y., Okada N., Kawamata H., Enomoto S.
Ключевые слова: LHC, luminosity, upgrade, magnets dipole, saturation, iron yoke, magnetic field distribution, experimental results, numerical analysis
Ключевые слова: LHC, upgrade, magnetic systems, LTS, Nb3Sn, mechanical properties, friction, crack formation, test results, measurement setup, design, displacements, shimming
Ключевые слова: LHC, magnets dipole, protective system, electronics, design, quench protection, cables, insulation, measurement technique, electrical circuit, high voltage process
Ambrosio G., Ferracin P., Felice H., Prestemon S.O., Pan H., Cheng D.W., Perez J.C., Guinchard M., Bourcey N., Grosclaude P., Vallone G., Anderssen E.C.
Ключевые слова: LHC, luminosity, upgrade, magnetic systems, fabrication, assembled conductors, magnets quadrupole, LTS, Nb3Sn, supporting structure, mechanical properties, stress effects
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., Bordini B., Savary F., Prin H., Principe R., Lackner F., Smekens D., Fiscarelli L., Bermudez S.I., Grand-Clement L., Ramos D.D., Semeraro M., Foussat A.P., Loffler C.H.
Ключевые слова: LTS, Nb3Sn, upgrade, design parameters, test results, LHC, luminosity, magnets dipole, prototype, design, fabrication, length
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
Ogitsu T., Sasaki K., Sugano M., Tanaka K., Takahashi N., Nakamoto T., Kimura N., Higashi N., Iida M., Ohhata H., Sugawara S., Todesco E., Okada R., Musso A., Okada N., Kawamata H., Enomoto S.
Ключевые слова: LHC, luminosity, magnets dipole, LTS, NbTi, prototype, magnetic field density, measurement technique, magnetic field distribution, upgrade
Ambrosio G., Ferracin P., Dietderich D.R., Tartaglia M., Wang X., Schmalzle J., Wanderer P., Orris D., Sylvester C., Dimarco J., Hafalia A.R., Ghosh A.K., Bossert R., Felice H., Sabbi G., Todesco E., Marchevsky M., Pan H., Prestemon S., Yu M., Cheng D.W., Chlachidze G., Velev G., Holik E.F., Salmi T., Perez J.C., Guinchard M., Nobrega A., Ravaioli E., Bermudez S.I., Krave S.T., Grosclaude P., Stoynev S.E., Cavanna E., Strauss T., Vallone G., Anerella M*2.
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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