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2nd ILC Acc. Workshop

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Title: PowerPoint Presentation Author: Carlo Pagani Last modified by: pagani Created Date: 7/11/2002 1:38:59 PM Document presentation format: On-screen Show – PowerPoint PPT presentation

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Title: 2nd ILC Acc. Workshop


1
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2
BCD ILC Cryomodule from Type III
  • Take TTF Type III as reference conceptual design
  • Introduce layout modifications required to fit
    ILC requirements
  • Quadrupole/BPM package at the center (symmetry
    and stability)
  • Review pipe sizes/positions according to gradient
    and cryo-distribution
  • Consider/include movers (warm) at the center post
    for x,y quadrupole beam based alignment
  • Consider/include movers on the cryomodule
    supports to optimize the module centering
    according to HOM data
  • Review suspension system (post, etc.) for
    stability and transport
  • Review all the subcomponent design for production
    cost and MTBF
  • Materials, welds, subcomponent engineering, LMI
    blankets, feed-through, diagnostics and cables,
    etc.
  • Module assembly issues
  • Reduce the waste space between cavities for real
    estate gradient
  • Flange interconnection, tuners, etc.
  • Define all the QC and QA steps required to assure
    MTBF

3
ACD Alternative for Quadrupole
  • Independent Cryomodule for the Quad proposed by
    SLAC
  • Pros
  • To be analyzed wrt the upgrade of TTF 3 with
    movers
  • Cons
  • More expensive Valves, independent He supply and
    return, etc.
  • Consistent impact on real estate gradient because
    of vacuum valves and unavoidable bellows 2 x 350
    mm at least i.e. 0.5 km/linac ( 25 M/linac)

4
Q20 of Cavities per Cryomodules
  • From 8 to 12 is acceptable without major design
    changes
  • Cryomodule does not have strong reasons to prefer
    one specific number
  • Vacuum vessel and HeGRP thickness can be adjusted
    to improve momentum of inertia in a longer
    module Constant deformation
  • Cost impact on the linac was studied with
    industry for TDR and the result was that the
    effect should be in within the error bar because
    of pros and cons
  • Module assembling slightly less expensive but
    handling and transport is more
  • Module reference milling machining more expensive
  • Decision drivers
  • RF Distribution Cavities/Klystron and wave-guide
    distribution scheme
  • Modest impact on real estate gradient and tunnel
    length
  • The impact of each module interconnection is at
    present 380 mm and cannot be decreased
    substantially because it includes vacuum valves,
    He retourn connection and 70 K HOM absorber
  • At 30 MV/m gradient the impact on linac length
    is
  • 55 m (10) or 136 m (8)

5
Q31 Linac Cavity Spacing
  • As short as possible!
  • Electromagnetic constraint for 70 mm beam pipe
    ca. 180 mm
  • TTF 3 Spacing 3?/2 i.e. gt 340 mm !
  • TESLA TDR Spacing 283 mm
  • There is a lot of margin for improvement
  • Each cm saved as an impact of 85 m on the length
    of each linac
  • BCD should be based on 250 mm gt 750 m/linac
    saved
  • ABD could be the work for 180 mm gt 1,3 km /linac
    saved

TTF Cavity Interconnection 340 mm between irises
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