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Ключевые слова: Rutherford cables

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Zhu Z., Zhao Y., Yuan X., Zhao L., Wang M., Ning F., He X., Feng W., He G., Liao H.

Development of High Strength and High RRR Aluminum-Stabilizer for Superconducting Cable in CEPC Detector Magnet

Ключевые слова: colliders, detector, magnets, LTS, NbTi, wires, stabilizing layers, Al, Rutherford cables, RRR parameter, cooling technology, tensile tests, experimental results

IEEE Transactions Applied Superconductivity, 2023, v.33, N 2, p.4500105

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Devred A., Ballarino A., Arndt T., Barth C., Puthran K.

Onset of Mechanical Degradation due to Transverse Compressive Stress in Nb3Sn Rutherford-Type Cables

Ключевые слова: LTS, Nb3Sn, Rutherford cables, design parameters, compression, stress effects, transverse stress, mechanical properties, degradation studies, crack formation, heat treatment, pressure distributions, microstructure

IEEE Transactions Applied Superconductivity, 2023, v.33, N 5-3, p.8400406

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Musenich R., Farinon S., Rossi L., Sorbi M., Statera M., Mariotto S., Prioli M., Felcini E., Matteis E.d., Valente R.U., Pullia M., Sorti S., Gagno A.

Design of a 4 T Curved Demonstrator Magnet for a Superconducting Ion Gantry

Ключевые слова: medical applications, ion irradiation, accelerator magnets, gantry, magnets dipole, LTS, NbTi, strands, Rutherford cables, design parameters, design, ac losses

IEEE Transactions Applied Superconductivity, 2023, v.33, N 5-2, p.4400505

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Dhalle M., Willering G., Kate H., Keijzer R.

Effect of Strand Damage in Nb3Sn Rutherford Cables on the Quench Propagation in Accelerator Magnets

Ключевые слова: accelerator magnets, LTS, Nb3Sn, Rutherford cables, design parameters, quench propagation, strands, degradation studies, current distribution, homogeneity, modeling

IEEE Transactions Applied Superconductivity, 2023, v.33, N 5-2, p.4700605

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Musenich R., Farinon S., Sorbi M., Ballarino A., Perini D., Bersani A., Statera M., Mariotto S., Prioli M., Caiffi B., Matteis E.d., Burioli S., Pampaloni A., Levi F., Palmisano A., Valente R.U., Sorti S., Vernassa G., Gagno A., Bracco M., Sala N., Coelli S.

Optimization of Electromagnetic Design After Winding Tests for the Nb3Sn Cos-Theta Dipole Model for FCC-hh

Ключевые слова: FCC, colliders, magnets dipole, LTS, Nb3Sn, Rutherford cables, design, winding techniques, test results

IEEE Transactions Applied Superconductivity, 2023, v.33, N 5-2, p.4601107

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Wu Y., Lin J., Liu D.

Concentric-Coil Distributed Winding Design for Large Direct-Drive Fully Superconducting Machines

Ключевые слова: rotating machines, generators, MgB2, Rutherford cables, coils racetrack, rotors, HTS, REBCO, tapes, winding configurations, design parameters

IEEE Transactions Applied Superconductivity, 2023, v.33, N 5-2, p.5201005

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Nakamura S., Ohuchi N., Tsuchiya K., Wang X., Anerella M., Ghosh A., Sugimoto H., Escallier J., Jain A., Parker B., Higashi N., Kawai M., Tawada M., Yamaoka H., Zong Z., Oki T., Masuzawa M., Okada N., Arimoto Y., Kondou Y., Aoki K., Hocker H., Ueki R., Akai K., Kanazawa K., Kawamoto T., Koiso H., Morita A., Ohnishi Y., Ohsawa Y., Oide K.

SuperKEKB beam final focus superconducting magnet system

Ключевые слова: colliders, magnetic systems, LTS, NbTi, Rutherford cables, cryogenic systems, cryostat, design, design parameters, fabrication

Nuclear Instruments Methods in Physics Research A, 2022, v.1021, N , p.165930

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Bogdanov I., Kozub S., Tkachenko L., Altukhov Y.

Numerical Optimization of the FFS Quadrupole

Ключевые слова: magnets quadrupole, LTS, NbTi, Rutherford cables, design parameters, magnetic field distribution, modeling, numerical analysis

IEEE Transactions Applied Superconductivity, 2022, v.32, N 4, p.4000105

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Ohya M.

Numerical Simulation of One-Sided Normal Zone Propagation in Large Helical Device Conductors

Ключевые слова: fusion, fusion magnets, helical winding, LTS, NbTi, Rutherford cables, resistivity, Hall effect, quench propagation, normal zone propagation, anisotropy, Joule heat, current transfer, transient performance, experimental results, numerical analysis, comparison

IEEE Transactions Applied Superconductivity, 2022, v.32, N 4, p.4200305

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Bruzzone P., Sedlak K., D'Auria V., Bykovskiy N.

Diffusion-Bonding Between Strands and Modeling of Splices of Nb3Sn Rutherford Cables

Ключевые слова: LTS, Nb3Sn, Rutherford cables, strands, diffusion process, joints, joint resistances, magnetic field dependence, current distribution, experimental results, modeling

IEEE Transactions Applied Superconductivity, 2022, v.32, N 4, p.7000105

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Rossi L., Ballarino A., Barna D., Benedetto E., Calzolaio C., Ceruti G., Matteis E.d., Echeandia A., Ekelof T., Farinon S., Felcini E., Gehring M., Kirby G., Lecrevisse T.*10, Lucas J., Tommasini D., Toral F.*11, Valente R., Veres D., Vieweg M.*14, Munilla J.*11, Musenich R., Pampaloni A., Pepitone K., Perini D., Popovic D.*12, Prioli M., Pullia M., Mariotto S., Quettier L.*10, Sanfilippo S., Senatore C.*13, Shabagin E., Sorbi M., Statera M.

A European Collaboration to Investigate Superconducting Magnets for Next Generation Heavy Ion Therapy

Ключевые слова: medical applications, accelerator magnets, LTS, NbTi, strands, Rutherford cables, ion irradiation, synchrotron, gantry, design, Europe, collaborations, review

IEEE Transactions Applied Superconductivity, 2022, v.32, N 4, p.4400207

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Dhalle M., Auchmann B., Kario A., Guo Z., Kate H.t., Sidorov S., Otten S., Daly M., Brem A., Hug C.

Improved training in paraffin-wax impregnated Nb3Sn Rutherford cables demonstrated in BOX samples

Ключевые слова: LTS, Nb3Sn, Rutherford cables, design parameters, impregnation, insulating medium, comparison, training effect, current, quench, critical current, magnetic field dependence, experimental results

Superconductor Science Technology, 2022, v.35, N 5, p.54014

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Brouwer L., Barzi E., Cooley L., Fajardo L.G., Gupta R., Juchno M., Kashikhin V., Marinozzi V., Novitski I., Rochepault E., Stern J., Zlobin A., Zucchi N., Ferracin P., Ambrosio G., Arbelaez D.

Towards 20 T Hybrid Accelerator Dipole Magnets

Ключевые слова: accelerator magnets, hybrid systems, LTS, Nb3Sn, coils outer, HTS, Bi2212, Rutherford cables, REBCO, CORC cables, coils insert, comparison, design, design parameters

IEEE Transactions Applied Superconductivity, 2022, v.32, N 6, p.4000906

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Dhalle M., Bottura L., Bordini B., Willering G., Kate H.H., Mangiarotti F.J., Keijzer R., Succi G.

Modelling V-I Measurements of Nb3Sn Accelerator Magnets With Conductor Degradation

Ключевые слова: accelerator magnets, LTS, Nb3Sn, Rutherford cables, modeling, current-voltage characteristics, degradation studies, experimental results

IEEE Transactions Applied Superconductivity, 2022, v.32, N 6, p.4001105

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Barzi E., Zlobin A.V., Turrioni D., Novitski I.

Development of a Small-Aperture Cos-Theta Dipole Insert Coil Based on Bi2212 Rutherford Cable and Stress Management Structure

Ключевые слова: accelerator magnets, magnets dipole, coils outer, LTS, Nb3Sn, coils insert, HTS, Bi2212, wires round, Rutherford cables, mechanical properties, stress effects, stress distribution, transverse stress, design, design parameters, magnetic field distribution, quality control, critical caracteristics, critical current, magnetic field dependence, test results

IEEE Transactions Applied Superconductivity, 2022, v.32, N 6, p.4003605

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I. Novitski, A. V. Zlobin, J. Coghill, E. Barzi, D. Turrioni

Development of a 120-mm Aperture Nb3Sn Dipole Coil With Stress Management

Ключевые слова: accelerator magnets, LTS, Nb3Sn, Rutherford cables, magnets dipole, coils, mechanical properties, stress effects, supporting structure, design

IEEE Transactions Applied Superconductivity, 2022, v.32, N 6, p.4006005

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Majoros M., Collings E.W., Sumption M., Shen T., Myers C., Rochester J.

Flux Creep in a Bi-2212 Rutherford Cable for Particle Accelerator Applications

Ключевые слова: accelerator magnets, HTS, Bi2212, Rutherford cables, flux creep, magnetization, coils racetrack, experimental results

IEEE Transactions Applied Superconductivity, 2022, v.32, N 4, p.6400205

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Musenich R., Farinon S., Rossi L., Sorbi M., Tommasini D., Karppinen M., Perini D., Statera M., Mariotto S., Prioli M., Felcini E., Matteis E.d., Valente R.U., Benedetto E., Pullia M.

Preliminary Study of 4 T Superconducting Dipole for a Light Rotating Gantry for Ion-Therapy

Ключевые слова: medical applications, rotating machines, gantry, carbon, ion irradiation, magnets dipole, LTS, NbTi, Rutherford cables, winding techniques, design, fabrication, prototype

IEEE Transactions Applied Superconductivity, 2022, v.32, N 6, p.4400506

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Kikuchi A., Shintomi T., Nishijima G., Takao T., Hirano N., Hamajima T., Matsumoto A., Yagai T., Takahashi M., Makida Y., Komagome T., Onji T., Inomata R.

Demonstration of kA-Class Rutherford Cables Using MgB2 Wires for an Energy Storage Device Suitable for a Liquid Hydrogen Indirect Cooling

Ключевые слова: SMES, MgB2, wires round, design parameters, Rutherford cables, cryogenic systems, hydrogen liquid, helium liquid, cooling technology, mechanical properties, strain effects, measurement setup, voltage waveforms, critical current, quench, heater, normal zone propagation, stability, test results

IEEE Transactions Applied Superconductivity, 2022, v.32, N 6, p.4801605

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Savoldi L., Placido D., Viarengo S.

Thermal-hydraulic analysis of superconducting cables for energy applications with a novel open object-oriented software: OPENSC^2

Ключевые слова: power equipment, cables, fusion magnets, forced flow conductor, cryogenic systems, helium supercritical, LTS, Nb3Sn, cable-in-conduit conductor, HTS, tapes, Rutherford cables, cables in separated cryostat, dc performance, design, design parameters, thermal-hydraulics, modeling, temperature distribution, numerical analysis

Cryogenics, 2022, v.124, N , p.103457

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