Cryogen-FREE optical cryostat compatible with 5T Split Pair superconducting magnet system. Custom variable temperature cryostat designed to allow for beamline research at temperatures ranging from 1.8K to 750K with minimal attenuation of neutrons.
5 Tesla Recondensing Superconducting Magnet System with 15cm Horizontal Room Temperature Bore
6 Tesla Cryogen-FREE Superconducting Magnet System with Horizontal Room Temperature Bore.
3 Tesla, Cryogen-FREE 10ppm superconducting magnet system with 4.00 inch horizontal room temperature bore and 2kG Superconducting Sweep Coil.
After several years of successful operation in the Collider Accelerator Department Electron Beam Ion Source (EBIS), the customer decided to upgrade their capabilities by adding a second Cryomagnetics’ magnet system. This time, both 5T magnet systems are required to be operated together with only 20 cm space between them.
The SPIRAL2 project at France’s GANIL (Grand Accélérateur National d’Ions Lourds) laboratory will significantly extend the research possibilities of Radioactive Ion Beam (RIB) physics. Part of SPIRAL2 is the S3 (Super Separator Spectrometer), a device designed for experiments with very high intensity stable ion beams. S3 requires seven (7) complex Superconducting Multipole Triplet (SMT) magnet systems. Each system is comprised of three sets of quadrupole, sextupole, octupole and dipole superconducting magnets.
GANIL selected the team of Cryomagnetics and Advanced Magnet Lab to design, develop and manufacture the SMT systems. The first system recently passed final factory tests at Cryomagnetics’ facility in Oak Ridge, TN.
5 Tesla Split Pair Cryogen-FREE superconducting magnet system. Designed with an extremely compact design and the ability to be mounted in multiple orientations. Dual perpendicular room temperature bores.
Custom Designed 5T Magnet System Cryogen-FREE with 110mm Horizontal Room Temperature Bore and Asymmetric Field Center
Designed to operate with another 6T, large bore superconducting magnet system delivered by Cryomagnetics in close proximity. When both systems are operating, there will be approximately 7,500 pounds of attractive force on each coil. Careful design of each cryostat’s support structure insures this force can be handled, while at the same time give low enough heat leak so the recondensing circuits are not overwhelmed by evaporating liquid helium.