93 research outputs found
High Field Niobium-Tin Quadrupoles
Insertion quadrupoles with large aperture and high gradient are required to achieve the luminosity upgrade goal of 1035 cm-2s-1 at the Large Hadron Collider (LHC). NbSn conductor is required in order to operate at high field and with sufficient temperature margin. We report here on the development of a “High-performance Quadrupole” (HQ) that will demonstrate the technology required for achieving the target luminosity. Conductor requirements, magnetic, mechanical and quench protection issues are presented and discussed. The HQ design is also suitable for an intermediate “Phase 1” upgrade, operating with large engineering margin
Development and demonstration of next generation technology for Nb_3Sn accelerator magnets with lower cost, improved performance uniformity, and higher operating point in the 12-14 T range
The scope of the proposal outlined in this white paper is the development and
demonstration of the technology needed for next generation of Nb_3Sn
accelerator magnets in the 12-14 T range. The main goal is to cut magnet
cold-mass cost by a factor 2 or higher with respect to the Nb_3Sn magnets
produced by the US Accelerator Upgrade Project (AUP) for the High-Luminosity
Large Hadron Collider (HL-LHC). This goal will be achieved by significant
reduction of labor hours, higher operating point, and improved performance
uniformity. A key factor will be automation that will be achieved through
industry involvement and benefitting from the experience gained in US national
laboratories through the production of the AUP magnets. This partnership will
enable the development of a technology that will be easily transferable to
industry for mid- and large-scale production of Nb_3Sn accelerator magnets in
the 12-14 T range. This step is essential to enable next generation of
colliders such as the FNAL-proposed Muon Collider, FCC and other HEP hadron
colliders.
This is a Directed R&D where direction is given by the field range and
industry involvement for high-automation and industry-ready technology. The
plan includes ten milestones, to be achieved in 6-8 years at the cost of 5-7
$M/year.Comment: White Paper for Snowmass 2022, 8 pages, 2 tables, 1 figur
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Limits of NbTi and Nb3Sn, and development of W& R Bi-2212 High Field Accelerator Magnets
NbTi accelerator dipoles are limited to magnetic fields (H) of about 10 T, due to an intrinsic upper critical field (H{sub c2}) limitation of 14 T. To surpass this restriction, prototype Nb{sub 3}Sn magnets are being developed which have reached 16 T. We show that Nb{sub 3}Sn dipole technology is practically limited to 17 to 18 T due to insufficient high field pinning, and intrinsically to 20 to 22 T due to H{sub c2} limitations. Therefore, to obtain magnetic fields approaching 20 T and higher, a material is required with a higher H{sub c2} and sufficient high field pinning capacity. A realistic candidate for this purpose is Bi-2212, which is available in round wires and sufficient lengths for the fabrication of coils based on Rutherford-type cables. We initiated a program to develop the required technology to construct accelerator magnets from 'wind-and-react' (W&R) Bi-2212 coils. We outline the complications that arise through the use of Bi-2212, describe the development paths to address these issues, and conclude with the design of W&R Bi-2212 sub-scale magnets
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Design Studies of Nb3Sn High-Gradient Quadrupole Models for LARP
Insertion quadrupoles with large aperture and high gradient are required to achieve the luminosity upgrade goal of 10{sup 35} cm{sup -2} s{sup -1} at the Large Hadron Collider (LHC). In 2004, the US Department of Energy established the LHC Accelerator Research Program (LARP) to develop a technology base for the upgrade. Nb{sub 3}Sn conductor is required in order to operate at high field and with sufficient temperature margin. We report here on the conceptual design studies of a series of 1 m long 'High-gradient Quadrupoles' (HQ) that will explore the magnet performance limits in terms of peak fields, forces and stresses. The HQ design is expected to provide coil peak fields of more than 15 T, corresponding to gradients above 300 T/m in a 90 mm bore. Conductor requirements, magnetic, mechanical and quench protection issues for candidate HQ designs will be presented and discussed
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Mechanical Analysis of the Nb3Sn Dipole Magnet HD1
The Superconducting Magnet Group at Lawrence Berkeley National Laboratory (LBNL) has recently fabricated and tested HD1, a Nb3Sn dipole magnet. The magnet reached a 16 T field, and exhibited training quenches in the end regions and in the straight section. After the test, HD1 was disassembled and inspected, and a detailed 3D finite element mechanical analysis was done to investigate for possible quench triggers. The study led to minor modifications to mechanical structure and assembly procedure, which were verified in a second test (HD1b). This paper presents the results of the mechanical analysis, including strain gauge measurements and coil visual inspection. The adjustments implemented in the magnet structure are reported and their effect on magnet training discussed
Concept for a Future Super Proton-Proton Collider
Following the discovery of the Higgs boson at LHC, new large colliders are
being studied by the international high-energy community to explore Higgs
physics in detail and new physics beyond the Standard Model. In China, a
two-stage circular collider project CEPC-SPPC is proposed, with the first stage
CEPC (Circular Electron Positron Collier, a so-called Higgs factory) focused on
Higgs physics, and the second stage SPPC (Super Proton-Proton Collider) focused
on new physics beyond the Standard Model. This paper discusses this second
stage.Comment: 34 pages, 8 figures, 5 table
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Development of Wind-and-React Bi-2212 Accelerator Magnet Technology
We report on the progress in our R&D program, targeted to develop the technology for the application of Bi{sub 2}Sr{sub 2}CaCu{sub 2}O{sub x} (Bi-2212) in accelerator magnets. The program uses subscale coils, wound from insulated cables, to study suitable materials, heat treatment homogeneity, stability, and effects of magnetic field and thermal and electro-magnetic loads. We have addressed material and reaction related issues and report on the fabrication, heat treatment, and analysis of subscale Bi-2212 coils. Such coils can carry a current on the order of 5000 A and generate, in various support structures, magnetic fields from 2.6 to 9.9 T. Successful coils are therefore targeted towards a hybrid Nb{sub 3}Sn-HTS magnet which will demonstrate the feasibility of Bi-2212 for accelerator magnets, and open a new magnetic field realm, beyond what is achievable with Nb{sub 3}Sn
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Design and Fabrication of a Supporting Structure for 3.6m Long Nb3Sn Racetrack Coils
As part of the LHC Accelerator Research Program (LARP), three US national laboratories (BNL, FNAL, and LBNL) are currently engaged in the development of superconducting magnets for the LHC Interaction Regions (IR) beyond the current design. As a first step towards the development of long Nb{sub 3}Sn quadrupole magnets, a 3.6 m long structure, based on the LBNL Subscale Common-Coil Magnet design, will be fabricated, assembled, and tested with aluminum-plate 'dummy coils'. The structure features an aluminum shell pre-tensioned over iron yokes using pressurized bladders and locking keys (bladder and key technology). Pre-load homogeneity and mechanical responses are monitored with pressure sensitive films and strain gauges mounted on the aluminum shell and the dummy coils. The details of the design and fabrication are presented and discussed, and the expected mechanical behavior is analyzed with finite element models
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