Liquid helium cooling of the MFTF superconducting magnets

The large superconducting detector magnets used for high energy physics experiments are virtually all indirectly cooled. In general, these detector magnets are not cryogenically stabilized. Therefore, there are a number of choices for cooling large indirectly cooled detector magnets. These choices i

A new superconducting magnet (4.6 T, 38 mm room temperature bore) which consists of a low-T~ Nb3Sn superconducting magnet and high-To Bi2Sr2Ca2Cu3Olo current leads has been working in vacuum for about 7400 hours without trouble. An experiment at a field of 3.7 T, which is generated by an operating c

An 11 T liquid helium-free superconducting magnet designed at 6 K in vacuum using high temperature superconducting current leads was developed. The NbTi/Nb,Sn coil was conductively cooled down from room temperature to 4.1 K in 40 h by two 4 K GMcryocoolers. In a performance test, the coil temperatur

To overcome the low threshold against disturbance usually observed in high current density, close-packed magnets, it was proposed to introduce narrow liquid helium channel cooling into the winding. Several magnets with winding inner diameters ranging from 8 to 60 cm were constructed and tested. The