Title :
Rapid-cycling dipole using block-coil geometry and bronze-process Nb3Sn superconductor
Author :
McInturff, A. ; McIntyre, P. ; Sattarov, A.
Author_Institution :
Texas A&M Univ., College Station
Abstract :
The block coil geometry utilized in recent high-field dipole development has significant benefit for applications requiring rapid cycling, since it intrinsically suppresses coupling currents between strands. A conceptual design for a 6 Tesla dipole has been studied for such applications, in which the intra-strand losses are minimized by using bronze-process Nb3Sn superconducting wire developed for ITER. That conductor provides isolated fine filaments and optimum matrix resistance between filaments. The block-coil geometry further accommodates placement of He cooling channels inside the coil, so that heat from radiation and from AC losses can be removed with minimum temperature rise in the coil. The design could be operated with supercritical helium cooling, and should make it possible to operate with a continuous ramp rate of 5-10 T/s.
Keywords :
fusion reactor instrumentation; fusion reactor materials; niobium alloys; superconducting coils; superconducting materials; tin alloys; AC losses; He cooling channels; Nb3Sn; Nb3Sn superconductor; Tesla dipole; block-coil geometry; bronze-process superconducting wire; coupling currents; fine filaments; high-field dipole development; intra-strand losses; optimum matrix resistance; rapid cycling; rapid-cycling dipole; supercritical helium cooling; Geometry; Large Hadron Collider; Magnetic flux; Magnetization; Niobium compounds; Niobium-tin; Superconducting cables; Superconducting coils; Superconducting magnets; Titanium compounds;
Conference_Titel :
Particle Accelerator Conference, 2007. PAC. IEEE
Conference_Location :
Albuquerque, NM
Print_ISBN :
978-1-4244-0916-7
DOI :
10.1109/PAC.2007.4440262
