S. Mattafirri scite author profile

Abstract-Magnet programs at BNL, LBNL and FNAL have observed instabilities in high J c Nb 3 Sn strands and magnets made from these strands. This paper correlates the strand stability determined from a short sample-strand test to the observed magnet performance. It has been observed that strands that carry high currents at high fields (greater than 10T) cannot sustain these same currents at low fields (1-3T) when the sample current is fixed and the magnetic field is ramped. This suggests that the present generation of strand is susceptible to flux jumps (FJ). To prevent flux jumps from limiting stand performance, one must accommodate the energy released during a flux jump. To better understand FJ this work has focused on wire with a given sub-element diameter and shows that one can significantly improve stability by increasing the copper conductivity (higher residual resistivity ratio, RRR, of the Cu). This increased stability significantly improves the conductor performance and permits it to carry more current.

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Design of HD2: a 15 tesla Nb/sub 3/Sn dipole with a 35 mm bore

Sabbi

Bartlett

Caspi

et al. 2005

IEEE Trans. Appl. Supercond.

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Abstract-The Nb 3 Sn dipole HD1, recently fabricated and tested at LBNL, pushes the limits of accelerator magnet technology into the 16 T field range, and opens the way to a new generation of HEP colliders. HD1 is based on a flat racetrack coil configuration and has a 10 mm bore. These features are consistent with the HD1 goals: exploring the Nb 3 Sn conductor performance limits at the maximum fields and under high stress. However, in order to further develop the block-coil geometry for future high-field accelerators, the bore size has to be increased to 30-50 mm. With respect to HD1, the main R&D challenges are: (a) design of the coil ends, to allow a magnetically efficient crosssection without obstructing the beam path; (b) design of the bore, to support the coil against the pre-load force; (c) correction of the geometric field errors. HD2 represents a first step in addressing these issues, with a central dipole field above 15 T, a 35 mm bore, and nominal field harmonics within a fraction of one unit. This paper describes the HD2 magnet design concept and its main features, as well as further steps required to develop a costeffective block-coil design for future high-field, acceleratorquality dipoles.Index Terms-High-field accelerator magnets, Nb 3 Sn.

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Development of TQC01, a 90 mm<tex>$hboxNb_3hbox Sn$</tex>Model Quadrupole for LHC Upgrade Based on SS Collar

Bossert

Ambrosio

Andreev

et al. 2006

IEEE Trans. Appl. Supercond.

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Design and Analysis of TQS01, a 90 mm<tex>$hboxNb_3hboxSn$</tex>Model Quadrupole for LHC Luminosity Upgrade Based on a Key and Bladder Assembly

Caspi

Ambrosio

Andreev

et al. 2006

IEEE Trans. Appl. Supercond.

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Abstract-The US LHC Accelerator Research Program (LARP) is developing Nb 3Sn accelerator magnet technology for the LHC luminosity upgrade. Two 90 mm "Technology Quadrupole" models (TQS01, TQC01) are being developed in close collaboration between LBNL and FNAL, using identical coil design, but two different support structures. The TQS01 structure was developed and tested at LBNL. With this approach coils are supported by an outer aluminum shell and assembled using keys and bladders. In contrast, the second model TQC01, utilize stainless steel collars and a thick stainless steel skin. This paper describes the TQS01 model magnet, its 3D ANSYS stress analysis, and anticipated instrumentation and assembly procedure.

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S. Mattafirri

Magnet R&D for the US LHC Accelerator Research Program (LARP)

Correlation between strand stability and magnet performance

Design of HD2: a 15 tesla Nb/sub 3/Sn dipole with a 35 mm bore

Development of TQC01, a 90 mm<tex>$hboxNb_3hbox Sn$</tex>Model Quadrupole for LHC Upgrade Based on SS Collar

Design and Analysis of TQS01, a 90 mm<tex>$hboxNb_3hboxSn$</tex>Model Quadrupole for LHC Luminosity Upgrade Based on a Key and Bladder Assembly

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