Analysis of Microphonics in SSR1 for Project-X M. Hassan, D. Passarelli, I. Gonin, S. Barbanotti, L. Ristori, and S. Yakovlev 9/27/2011 PXIE Meeting.

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Presentation transcript:

Analysis of Microphonics in SSR1 for Project-X M. Hassan, D. Passarelli, I. Gonin, S. Barbanotti, L. Ristori, and S. Yakovlev 9/27/2011 PXIE Meeting

SSR1 Geometry Generations SSR1-G1 Single Rib on Top SSR1-G2 Double Rib on Top SSR1-G3 Two Ribs+ Side Ring

Comsol Simulation EM Eigen frequency simulation to find the resonant frequency (f0) Solid Mechanics Find the deformation under given pressure load (PL) Moving Mesh Update the mesh after deformation EM Eigen frequency simulation to find the resonant frequency after deformation (fp) Study1 Eigen-frequency (to find f0) Study2 Stationary (solving only for solid mechanics and moving mesh) Eigen-frequency (to find f p ) Electromagnetic Waves Solving only for the RF domain Applying the prober boundary conditions Solid Mechanics Solving only for the Cavity Shell Applying the proper fixed constraints, symmetries, displacements, and boundary load Moving Mesh Solving for all domains Applying the proper prescribed and free mesh deformation/displacement Two Simulation Studies Three Multiphysic Modules

Setup Moving Mesh Solving for all domains Applying the proper prescribed and free mesh deformation/displacement Niobium Shell RF Domain Stainless Steel Vessel Electromagnetic Waves Solving only for the RF domain Applying the prober boundary conditions Solid Mechanics Solving only for the Cavity Vessel Applying the proper fixed constraints, symmetries, displacements, and boundary load PMC PEC Fixed Constraint Prescribed Deformation u,v,w Free Deformation Symmetry Boundaries Pressure Boundary Load Prescribed Displacement dx Prescribed Displacement u,v,w dy=0 dx=0 dz=0

Investigation of the displacement effects on SSR1-G3 Fixed Beam Pipe Constraints Different constraints would imply another linear relation with different line slope that passes through the fixed all constraints point The larger the slope of the linear relation the better as it would get the zero df/dp closer from the fixed all constraints point Fixed all constraints

Lessons from SSR0  Pibe Ribs are very important to reduce df/dp  Ring between the shell and the Helium vessel would simplify the vessel design

Design procedure to minimize df/dp

SSR1-G3 with Helium Vessel Comsol f0= MHz f1= MHz df/dp ~4.9 Hz/torr 17.1 µm z µm

Conclusion Microphonics of SSR1 has been reduced to about 5Hz/Torr A general procedure for minimizing the microphonics in spoke cavities has been proposed What is next?