| Paper |
Title |
Page |
| FRXKI01 |
Superconducting Magnet Needs for the ILC
|
3732 |
| |
- J. C. Tompkins
- J. A. Clarke
Cockcroft Institute, Warrington, Cheshire
- V. S. Kashikhin
Fermilab, Batavia, Illinois
- M. A. Palmer
CLASSE, Ithaca
- B. Parker
BNL, Upton, Long Island, New York
|
|
| |
The ILC Reference Design Report will be completed early in 2007. The Magnet Systems Group was formed to translate magnetic field requirements into magnet designs and cost estimates for the Reference Design. As presently configured, the ILC will have more than 11,000 magnetic elements of which more than 1200 will be based on superconducting technology. This paper will describe the major superconducting magnet needs for the ILC as presently determined by the Magnet Systems Group and the leaders of the Area Systems Groups, responsible for beamline design. The superconducting magnet components include the Main Linac quadrupoles, the Positron Source undulators, the Damping Ring wigglers, and the complex array of Final Focus superconducting elements in the Beam Delivery System.
|
|
|
Slides
|
|
| FRXKI02 |
Magnet Development for LARP
|
3737 |
| |
|
|
| |
The talk will cover progress and prospects for developing Nb3Sn quadrupoles for the eventual upgrade of the LHC IR's. The talk should also cover developments in cabling, but not R&D on the Nb3Sn strand.
|
|
|
|
Slides
|
|
| FRXKI03 |
Magnets for Upgrade of the Accelerator Complex at CERN
|
3738 |
| |
|
|
| |
While the LHC is approaching commissioning phase, a global plan with different options for the consolidation and upgrade of the accelerator complex is under discussion at CERN. In one option the change of the interaction region (IR) magnets, in order to increase the luminosity of the LHC, is considered. This measure may be accompanied or not by an increase of the beam current. In any case the needs of new more performing Nb-Ti based magnets and/or Nb3Sn magnets is established. The choice of Nb3Sn based magnets with13-15 T peak field on the coil seems mandatory for the low-beta triplet quadrupoles in case a factor two or more in luminosity is envisaged. In another option the improvement of the injector chain is considered. For the moment the first priority is the design of a new PS of energy about 50 GeV, with duty cycle less than 1 Hz. In this paper a comparison among the option based on normal conducting magnets (today baseline) and superconducting magnets of various types will be presented. In the frame of the longer-term scenario, magnets envisaged for an upgrade of the present SPS (from 450 to 1 TeV) and for neutrino production facilities will be discussed as well.
|
|
|
|
Slides
|
|