Design of 11 T Twin-Aperture ${\rm Nb}_{3}{\rm Sn}$ Dipole Demonstrator Magnet for LHC Upgrades

Karppinen, M.; Andreev, N.; Apollinari, G.; Auchmann, Bernhard; Barzi, E.; Bossert, R.; Kashikhin, V.V.; Nobrega, A.; Novitski, I.; Rossi, L.; Smekens, D.; Zlobin, A.V.

doi:10.1109/tasc.2011.2177625

Cited by 75 publications

(73 citation statements)

References 7 publications

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“…IGH critical current density, J c , Nb 3 Sn wires are the superconductors preferred option for the next generation of accelerator magnets at CERN [1]- [3]. The J c of recent Nb 3 Sn strands have reached values in excess of 3000 A/mm 2 at 12 T and 4.2 K allowing larger aperture/stronger field magnets.…”

Section: Introductionmentioning

confidence: 99%

“…The J c of recent Nb 3 Sn strands have reached values in excess of 3000 A/mm 2 at 12 T and 4.2 K allowing larger aperture/stronger field magnets. On the other hand, such large J c values may cause magneto-thermal instabilities that can drastically reduce the conductor performance by quenching the superconductor prematurely before reaching its critical current [4]- [13].…”

Section: Introductionmentioning

confidence: 99%

“…In high J c Nb 3 Sn magnets, one of the main parameters for preventing premature quenches caused by magneto-thermal instabilities is the thermal and electrical conductivity of the stabilizing copper within the Nb 3 Sn strands. A large copper conductivity allows a major amount of heat to escape from the region that is experiencing the instability, thus improving the capability of the superconductor to sustain a flux jump without quenching.…”

Section: Introductionmentioning

confidence: 99%

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Impact of the Residual Resistivity Ratio on the Stability of ${\rm Nb}_{3}{\rm Sn}$ Magnets

Bordini

Bottura

Oberli

et al. 2012

IEEE Trans. Appl. Supercond.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Impact of the Residual Resistivity Ratio on the Stability of ${\rm Nb}_{3}{\rm Sn}$ Magnets

Bordini

Bottura

Oberli

et al. 2012

IEEE Trans. Appl. Supercond.

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“…Two different approaches for the coil-collar interface are being explored in this R&D phase, and they will be eventually assembled in one Two-In-One magnet model that should validate the superconductor and the basic design 16) . A full size prototype should be ready in 2014.…”

Section: T Dipole For Lhcmentioning

confidence: 99%

Superconducting Magnet Development for the LHC Upgrades

Rossi

2012

TEION KOGAKU

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LHC is now delivering proton and heavy ion collisions at the highest energy. Upgrading the LHC beyond its design performance is a long term program that started during the LHC construction, with some fundamental R&D programs.The upgrade program is based on a vigorous superconductor and magnet R&D, aimed at increasing the field in Review ArticleSuperconducting Magnet Development for the LHC Upgrades Lucio ROSSI * Synopsis: LHC is now delivering proton and heavy ion collisions at the highest energy. Upgrading the LHC beyond its design performance is a long term program that started during the LHC construction, with some fundamental R&D programs. The upgrade program is based on a vigorous superconductor and magnet R&D, aimed at increasing the field in accelerator magnets from 8 T to 12 T for the luminosity upgrade, with the scope of increasing the collider luminosity by a factor 5 to 10 from 2022. The upgrade program might continue with the LHC energy upgrade, which would require magnets producing field in the range of 16-20 T. The results obtained so far and the future challenges are discussed together with the possible plan to reach the goals.

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“…These collared coils will be tested first in a single-aperture configuration and then assembled and tested inside a common iron yoke (twinaperture configuration). In parallel, four 2 m long collared coils will be built and tested at CERN first in a single-aperture and then in a twin-aperture configuration to establish the technology transfer to CERN, and demonstrate and optimize the quench performance, field quality and quench protection of Nb 3 Sn coils and a somewhat different mechanical concept of the collar and yoke [4]. This paper describes the design features of the first 1 m long single-aperture Nb 3 Sn dipole model (MBHSP02) fabricated at Fermilab and tested in April 2013.…”

Section: Introductionmentioning

confidence: 99%

Quench Performance of a 1 m Long Single-Aperture 11 T <formula formulatype="inline"><tex Notation="TeX">$ \hbox{Nb}_{3}\hbox{Sn}$</tex></formula> Dipole Model for LHC Upgrades

Zlobin

Andreev

Apollinari

et al. 2014

IEEE Trans. Appl. Supercond.

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Design of 11 T Twin-Aperture ${\rm Nb}_{3}{\rm Sn}$ Dipole Demonstrator Magnet for LHC Upgrades

Cited by 75 publications

References 7 publications

Impact of the Residual Resistivity Ratio on the Stability of ${\rm Nb}_{3}{\rm Sn}$ Magnets

Impact of the Residual Resistivity Ratio on the Stability of ${\rm Nb}_{3}{\rm Sn}$ Magnets

Superconducting Magnet Development for the LHC Upgrades

Quench Performance of a 1 m Long Single-Aperture 11 T <formula formulatype="inline"><tex Notation="TeX">$ \hbox{Nb}_{3}\hbox{Sn}$</tex></formula> Dipole Model for LHC Upgrades

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