Your search keyword '"Rory Warner"' showing total 2 results

1. A cylindrically symmetric magnetic shield for a large-bore 3.0 Tesla magnet

Author

James R. Ewing, Rory Warner, and Joseph A. Helpern

Subjects

Fabrication, Physics::Instrumentation and Detectors, Surface Properties, Instrumentation, Physics::Medical Physics, Astrophysics::Cosmology and Extragalactic Astrophysics, Nuclear magnetic resonance, Optics, Electromagnetic Fields, Radiation Protection, Dipole magnet, Shield, Radiology, Nuclear Medicine and imaging, Physics, Electropermanent magnet, business.industry, Equipment Design, Models, Theoretical, Magnetic Resonance Imaging, Carbon, Dipole, Steel, Magnet, Electromagnetic shielding, Costs and Cost Analysis, Nuclear Medicine Department, Hospital, business

Abstract

A 3.0 Tesla, 0.80-m bore magnet replaced our previous 1.9 Tesla, 0.76-m magnet. The 3.0 Tesla replacement magnet had a dipole moment of 1.7 with respect to that of the 1.9 Tesla magnet. The pre-existing cylindrically symmetric passive steel shielding was modified to confine the fringe fields of the replacement magnet to match those of the previous magnet. A cylindrically symmetric inner shield insert of about 20,000 kg was designed, fabricated, and installed. Upon energization of the magnet, the combined shielding met all design criteria. Alternative designs, optimization of cylindrically symmetric designs, and costs of fabrication, are presented herein.

Published

1993

2. Ultra-high field magnets for whole-body MRI.

Author

Rory Warner

Subjects

*MAGNETIC fields, *MAGNETIC resonance imaging, *SOLENOIDS, *CARBON steel, *HOMOGENEITY

Abstract

For whole-body MRI, an ultra-high field (UHF) magnet is currently defined as a system operating at 7 T or above. Over 70 UHF magnets have been built, all with the same technical approach originally developed by Magnex Scientific Ltd. The preferred coil configuration is a compensated solenoid. In this case, the majority of the field is generated by a simple long solenoid that stretches the entire length of the magnet. Additional coils are wound on a separate former outside the main windings with the purpose of balancing the homogeneity. Most of the magnets currently in operation are passively shielded systems where the magnet is surrounded by a steel box of 200–870 tonnes of carbon steel. More recently actively shielded magnets have been built for operation at 7 T; in this case the stray field is controlled by with reverse turns wound on a separate former outside the primary coils. Protection against quench damage is much more complex with an actively shielded magnet design due to the requirement to prevent the stray field from increasing during a quench. In the case of the 7 T 900 magnet this controlled by combining some of the screening coils into each section of the protection circuit. Correction of the field variations caused by manufacturing tolerances and environmental effects are made with a combination of superconducting shims and passive shims. Modern UHF magnets operate in zero boil-off mode with the use of cryocoolers with cooling capacity at 4.2 K. Although there are no cryogen costs associated with normal operation UHF magnets require a significant volume (10 000–20 000 l) of liquid helium for the cool-down. Liquid helium is expensive therefore new methods of cool-down using high-power cryocoolers are being implemented to reduce the requirement. [ABSTRACT FROM AUTHOR]

Published

2016