Title :
Cryomodule design for the Rare Isotope Accelerator
Author :
Grimm, T.L. ; Hartung, W. ; Johnson, M. ; York, R.C. ; Kneisel, P. ; Turlington, L.
Author_Institution :
Michigan State Univ., East Lansing, MI, USA
Abstract :
The Rare Isotope Accelerator (RIA) driver linac will produce >400 MeV/u proton through uranium beams using many types of superconducting accelerating cavities such as quarter wave, spoke, and elliptical cavities. A cryomodule design that can accommodate all of the superconducting cavity and magnet types is presented. Alignment of the cold mass uses a titanium rail system, which minimizes cryomodule size, and decreases both the tunnel cross-section and length. The titanium rail is supported from the top vacuum plate by an adjustable tri-link, which is similar to existing Michigan State University magnet technology. A prototype cryomodule is under construction for testing 805 MHz, v/c=0.47, six-cell niobium cavities in realistic operating conditions. Details of the design and progress to date are presented.
Keywords :
accelerator cavities; accelerator magnets; beam handling techniques; ion accelerators; linear accelerators; particle beam dynamics; proton accelerators; superconducting cavity resonators; superconducting magnets; Rare Isotope Accelerator driver linac; cold mass; cryomodule design; elliptical cavity; prototype cryomodule; quarter wave cavity; six-cell niobium cavities; spoke cavity; superconducting accelerating cavities; superconducting magnets; titanium rail system; top vacuum plate; tunnel cross-section; uranium beams; Acceleration; Isotopes; Linear particle accelerator; Particle beams; Proton accelerators; Rails; Structural beams; Superconducting magnets; Titanium; Vacuum technology;
Conference_Titel :
Particle Accelerator Conference, 2003. PAC 2003. Proceedings of the
Print_ISBN :
0-7803-7738-9
DOI :
10.1109/PAC.2003.1289702
