Optimizing Radial Choke Cell Geometry with Different Damping for Enhanced Field Configuration
Implementing radial choke cell geometry for optimizing electric and magnetic field configurations by utilizing two disks per cell with varied damping properties. Detailed table of parameters, new C10/CD10 structures, and proposals for improved efficiency included.
Optimizing Radial Choke Cell Geometry with Different Damping for Enhanced Field Configuration
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Presentation Transcript
C10 with different damping Grudiev 23/10/2008
Radial Choke cell geometry ~30mm Two disks per cell are necessary to implement radial choke geometry
Electric field configuration C10_vg1.16 WG damping C10_vg1.35 C10_vg1.15 Radial Choke damping
Magnetic field configuration CD10_vg1.16 WG damping C10_vg1.35 CD10_vg1.15 Radial Choke damping
Magnetic field configuration for different damping waveguides CD10_vg1.16 WG damping C10_vg1.35 CD10_vg1.32 WG damping
Table of parameters ΔT @(100 MV/m, 200 ns) = 2*(Hs/Ea) 2 [K]
List of new C10/CD10 structures • C10 structures with a=3mm which are already in the pipe-line • C10_vg1.35 • CD10_vg1.16_WDS • CD10_vg1.15_Choke new proposals in case CD10_vg1.16_WDS is much worse than C10_vg1.35 CD10_vg1.32_WDS C10_vg1.35_milled_NOT_turned CD10_vg1.16_WDS_CuZr CD10_vg1.16_WDS_GlidCop lower dT milling versus turning harder material harder material
