175 research outputs found
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Test Results for HINS Focusing Solenoids at Fermilab
A focusing lens R&D program is close to completion and industrial production of magnets has begun. Two types of magnets are being built for use in the room temperature RF section at the front end of a superconducting H-minus linac of a High Intensity Neutrino Source. All of the magnets are designed as a solenoid with bucking coils to cancel the field in the vicinity of adjacent RF cavities, and one type incorporates steering dipole corrector coils. We present a summary of the predicted and measured quench and magnetic properties for both R&D and production device samples that have been tested at Fermilab
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Electrical and quench performance of the first MICE coupling coil
The first MICE Coupling Coil has been tested in a conduction-cooled environment in the new Solenoid Test Facility at Fermilab. We present an overview of the power and quench protection scheme, and report on the electrical and quench performance results obtained during cold power tests of the magnet
Status of the High Field Cable Test Facility at Fermilab
Fermi National Accelerator Laboratory (FNAL) and Lawrence Berkeley National
Laboratory (LBNL) are building a new High Field Vertical Magnet Test Facility
(HFVMTF) for testing superconducting cables in high magnetic field. The
background magnetic field of 15 T in the HFVMTF will be produced by a magnet
provided by LBNL. The HFVMTF is jointly funded by the US DOE Offices of
Science, High Energy Physics (HEP), and Fusion Energy Sciences (FES), and will
serve as a superconducting cable test facility in high magnetic fields and a
wide range of temperatures for HEP and FES communities. This facility will also
be used to test high-field superconducting magnet models and demonstrators,
including hybrid magnets, produced by the US Magnet Development Program (MDP).
The paper describes the status of the facility, including construction,
cryostat designs, top and lambda plates, and systems for powering, and quench
protection and monitoring
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Strength and shape of the magnetic field of the Fermilab main injector dipoles
Measurements of 230 6-meter and 136 4-meter dipoles constructed for the Fermilab Main Injector were carried out as part of the magnet production effort. An automated measurement system provided data on magnetic field strength and shape using several partially redundant systems. Results of these measurements are available for each individual magnet for use in accelerator modelling. In this report we will summarise the results on all of the magnets to characterise the properties which will govern accelerator operation
A Quench Detection and Monitoring System for Superconducting Magnets at Fermilab
A quench detection system was developed for protecting and monitoring the
superconducting solenoids for the Muon-to-Electron Conversion Experiment (Mu2e)
at Fermilab. The quench system was designed for a high level of dependability
and long-term continuous operation. It is based on three tiers: Tier-I,
FPGA-based Digital Quench Detection (DQD); Tier-II, Analog Quench Detection
(AQD); and Tier-3, the quench controls and data management system. The Tier-I
and Tier-II are completely independent and fully redundant systems. The Tier-3
system is based on National Instruments (NI) C-RIO and provides the user
interface for quench controls and data management. It is independent from Tiers
I & II. The DQD provides both quench detection and quench characterization
(monitoring) capability. Both DQD and AQD have built-in high voltage isolation
and user programmable gains and attenuations. The DQD and AQD also includes
user configured current dependent thresholding and validation times.
A 1st article of the three-tier system was fully implemented on the new
Fermilab magnet test stand for the HL-LHC Accelerator Up-grade Project (AUP).
It successfully provided quench protection and monitoring (QPM) for a cold
superconducting bus test in November 2020. The Mu2e quench detection design has
since been implemented for production testing of the AUP magnets. A detailed
description of the system along with results from the AUP superconducting bus
test will be presented
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