Status and plans for the ILC cryomodule design - PowerPoint PPT Presentation

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Status and plans for the ILC cryomodule design

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... November 13 - 15, 2004 at KEK. http://tesla-new.desy.de/content/index_eng.html ... line connects to two-phase line via JT valve once per 'string' (~12 modules) ... – PowerPoint PPT presentation

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Title: Status and plans for the ILC cryomodule design


1
Status and plans for the ILC cryomodule design
  • Tom Peterson, Fermilab
  • TESLA Technology Collaboration Meeting
  • Frascati, 6 December 2005

2
TTF cryomodule is our reference
3
TESLA-style module information . . .
  • http//ilc.desy.de/e627/e634/e730/e745/index_eng.h
    tml
  • Links to talks presented by Lutz Lilje, Axel
    Matheisen, W.-D. Mueller, Bernd Petersen, Nick
    Walker, and others at our December 6 - 7, 2004,
    module meeting at DESY
  • http//lcdev.kek.jp/ILCWS/
  • First ILC workshop, November 13 - 15, 2004 at
    KEK
  • http//tesla-new.desy.de/content/index_eng.html
  • DESY TESLA page with link to the TESLA Design
    Report and other information including talks and
    posters from the March 2004 ITRP visit

4
Sources of Information
  • Bernd Petersen, Lutz Lilje, Axel Matheisen, Nick
    Walker, Hans Weise, and others (DESY)
  • Carlo Pagani (INFN)
  • Terry Garvey (LAL-Orsay)
  • Tom Nicol (Fermilab)
  • Don Mitchell (Fermilab)
  • John Weisend (SLAC)
  • TESLA TDR (March 2001)
  • And others!

5
Some History of Changes in Design Features for
TTF Cryomodule
  • Three generations of TTF cryomodule designs
  • TTF-I was module 1
  • TTF-II was modules 2 and 3
  • TTF-III is modules 4 - 8
  • TDR called for some significant changes from all
    of the above such as a longer module with 12
    cavities per module
  • Next -- TTF III is our baseline design
  • X-FEL modules will differ in some details from
    TTF type III
  • ILC modules will begin as a few type III
    prototypes, which are essentially type III with
    the quad at 2 K and supported like a cavity
  • Planning has begun for the next generation ILC
    module design, type IV, based on the type III
    design

6
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7
Features of type III cryomodule
  • Allows for fixed couplers
  • Invar rod and roller bearings allow cavities to
    remain axially fixed while the 300 mm tube
    shrinks
  • Smaller cross section results in standard pipe
    size for outer vessel
  • Axial position of last support changed to stiffen
    structure near quadrupole

8
Cryomodule III model -- helium vessels in the
vacuum vessel
CAD model based on DESY design imported and
modified by Don Mitchell, Fermilab
9
Cryomodule III model -- helium vessels in the
vacuum vessel with input couplers and quadrupole
CAD model based on DESY design imported and
modified by Don Mitchell, Fermilab
10
We have a general consensus regarding what needs
changing
  • Based largely on TTF experience, but also Jlab
    and others
  • Consensus collected by working groups at
    meetings, including but not limited to
  • SLAC (14 - 16 Oct 2004)
  • KEK (13 - 15 Nov 2004)
  • DESY (6 - 8 Dec 2004)
  • Snowmass (August 2005)
  • SMTF collaboration meeting (5 - 7 Oct 2005)

11
Type IV cryomodule will include the following
features from Type III
  • 8 cavities per module
  • Same cooling scheme and cryogenic system concept
  • Same vacuum vessel diameter and 300 mm pipe
    diameter
  • Nearly the same pipe locations and arrangement
  • Same cavity centerline location relative to
    vacuum vessel
  • Same support posts
  • Same thermal shields concept, although coupler
    port locations move
  • Same cavity support detail (300 mm header as
    structural backbone with cavities held by roller
    bearings and invar rods)
  • Same input coupler (at least in terms of mounting
    and interface to vacuum vessel, cavity, and
    thermal shields)

12
Helium vessel supports
13
Support posts
14
Thermal shield installation
15
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16
ILC cryogenic system overview
  • Saturated He II cooled cavities _at_ 2 K
  • Helium gas thermal shield _at_ 5 - 8 K
  • Helium gas thermal shield _at_ 40 - 80 K
  • Two-phase line (liquid helium supply and
    concurrent vapor return) connects to each helium
    vessel
  • Two-phase line connects to gas return once per
    module
  • A small diameter warm-up/cool-down line connects
    the bottoms of the He vessels (primarily for
    warm-up)
  • Subcooled helium supply line connects to
    two-phase line via JT valve once per string
    (12 modules)

17
TESLA cryogenic unit
18
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19
Type IV cryomodule will differ from type III in
the following general areas
  • Cavity iris-to-iris spacing reduced to 283 mm
  • Reduces length from 12.20 to about 11.8 m, get
    0.75 packing
  • Slow tuner modified to allow closer
    cavity-to-cavity spacing (could mean switching to
    blade tuner design, but choice still open)
  • Fast tuner -- new design
  • Quad/corrector/BPM package under center post,
    hung from 300 mm tube, not on rollers (diverging
    from X-FEL)
  • Two major module types, one with quad and one
    without

20
More differences of Type IV cryomodule from type
III
  • Interconnect features modified to accommodate
    input coupler at end of cryostat
  • Quad current leads may be new and different, with
    local impact on thermal shields and vacuum vessel
    ports
  • Provisions for quad power lead connection at
    center of module
  • Some pipe sizes will be increased for lower
    pressure drops with high flow rates -- would like
    to retain long cryogenic unit lengths up to limit
    of 300 mm pipe and cryo plants. Present effort
    includes re-analysis of heat loads, flow rates,
    and cryogenic system thermal process.

21
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22
Cavity Interconnect
23
Module predicted heat loads
24
ILC cryogenic system much larger than TESLA 500
  • 8 cryogenic plant locations
  • Approximately 5 km spacing
  • Each location with 2 cryogenic plants of about
    the maximum size -- each plant equivalent to
    about 24 kW at 4.5 K
  • Each plant about 6 MW wall plug power
  • ILC cryogenics about 100 MW total

25
Module pipe sizes increase
26
(Increase diameter beyond X-FEL)
(Increase diameter beyond X-FEL)
(Review 2-phase pipe size and effect of slope)
27
Some critical open design issues
  • Quad/corrector/BPM package is a major unknown
    right now and goes into the heart of the module
  • Tuner details, slow and fast, but especially fast
    tuner
  • Vibrational analysis, which will be compared to
    measurements for verification of the model for
    future design work
  • Development of module and module component test
    plans
  • Verification of cavity positional stability with
    thermal cycles
  • Design of test instrumentation for the module
  • Robustness for shipping, analysis of shipping
    restraints and loads, shipping specifications
  • Active quad movers(?) A complication

28
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29
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30
Blade tuner concept
31
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32
Other open design issues
  • Design for manufacturability, ease of assembly,
    and cost reduction are always considerations
  • Part of the type IV design effort will also be a
    consideration of other options
  • particularly with respect to quad location and
    support
  • but also perhaps with respect to tuners and/or
    other features
  • level of effort on these options will be dictated
    by our manpower and schedule.

33
Organization of effort
  • An international effort
  • Need division of tasks to make best use of our
    resources
  • Minimize duplication of efforts
  • Take advantage of ideas and expertise
  • Pursue options with parallel efforts
  • Each institution has limited resources
  • Work has begun
  • Fermilab has organized a group to do type IV
    design, other labs have also expressed interest
    and/or begun

34
Type IV probable schedule
  • Design module -- 12 - 24 months (2006 - 2007)
  • Magnet/BPM package
  • Tuners, etc.
  • Integrate into module design
  • Build and test -- 12 - 18 months (2007 - 2008)
  • In addition to module, need module test stand and
    test facility!
  • Total 2 to 3 1/2 years, depending on scope of
    work and availability of resources.

35
X-FEL Modules
  • 100 modules will be industrially produced
  • Brings us to the level of manufacturing
    quantities
  • Some differences from ILC, but much of module
    design and manufacturing is the same
  • Cavity supports, thermal shields, MLI, vacuum
    vessel assembly, internal piping, etc.
  • X-FEL experience will be important and valuable
    part of ILC module development
  • X-FEL module effort will stay ahead of ILC effort
  • Remain in close contact and take advantage of
    similar designs, experience, and industrial input
    to design

36
After Type IV--gt increasing quantities
  • Experience with large quantities of SC magnets
    follows an old engineering rule (factors of 10)
  • 1 prototype
  • 10 pre-production prototypes
  • 100 first production run (X-FEL!)
  • Not throw-aways but slower production, still
    making adjustments, relatively large fraction of
    reject/rework
  • 1000 full production run
  • There are design changes and manufacturing method
    changes at each stage

37
Industrialization, impact on design
  • As we move to production of quantities of modules
    in industry, the design will continue to change
  • Reduction of required labor
  • Less costly materials
  • Less costly manufacturing of components
  • Design for more efficient assembly

38
Type IV is not the (final) ILC design
  • Test results of types III and IV will teach us a
    lot
  • There will be some choices beyond type IV from
    parallel development efforts
  • Industrialization will have a significant impact
    on the design
  • Type IV is the next step in module design for ILC
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