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Engineering aspects of the Detector interface

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NLC - The Next Linear Collider Project. Knut Skarpaas VIII. May 1999 ... Con: ECAL and HCAL must be split to remove (may require difficult rigging) Option 4 ... – PowerPoint PPT presentation

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Title: Engineering aspects of the Detector interface


1
Engineering aspects of the Detector interface
  • Knut Skarpaas VIII

2
Detector interfaces
  • Collider hall
  • Final magnet supports
  • Assembly Sequence

3
Collider Hall Geometry
  • Detector Size
  • Currently modeling structure for small US design
  • Small detector has a strong following
  • Magnet support for last quads fairly rigid
  • Compact package reduces deflections
  • Detector group is further along on this design
  • We are in continuous contact with many of the
    detector working groups

4
Collider Hall /Detector Assembly Procedure
  • Assembly staged during beamline commissioning
  • Must shield detector assembly area from the beam
  • Movable barrier
  • Temporary support for beamline
  • Must act like detector
  • Final focus assembly dependent on magnet support
    method
  • Cantilever
  • Support tube
  • Access to Detector Sub-components
  • Vertex detector
  • Central tracker
  • Endcaps may be captive
  • Segment endcaps

5
Magnet support options
  • Design goals for various support options
  • Minimize deflections
  • Minimize unsupported span
  • Put support near critical deflection points
  • Put support near massive items
  • Current cantilever option has support near mask
    centroid
  • Maximize moment of inertia (minimize sag)
  • Tubular support advantageous
  • Will need access ports to work on / install
    magnets
  • Minimize mass supported by tube
  • Some mask forces may be transferred to the doors

6
Design goals for various support options cont.
  • Material requirements
  • Minimize radiation length of material near
    Interaction Point
  • Cantilever design has no material at IP
  • Radiation hard design
  • Adhesives / polymers may degrade
  • Interface with required detector components
  • Vertex detector in bore (if support tube)
  • If cantilever, support vertex detector from mask
    tips or from central tracker
  • Masks (held by cantilever or inside support tube)
  • Tungsten masks are massive
  • 2500 lb requires support for door opening
  • Central tracker hugs outer bore (or masks)
  • Pass through steel in door

7
Design goals for various support options cont.
  • Door opening to be minimized to reduce Br near
    quads
  • Clearances
  • Assembly clearances
  • Allow for gravitational deflections
  • Current cantilever deflects .16 with door open
  • Seismic clearance
  • Site specific
  • Services
  • Vertex cables in bore (if support tube)
  • Cooling for vertex detector
  • Vertex detector requires 170k nitrogen gas
  • Foam or vacuum insulated lines
  • Foam lines are large (2)
  • Luminosity monitor cables / cooling
  • In bore for most options

8
Assembly sequence
  • Must be able to put detector together first time
  • Must be able to access various components for
    servicing
  • Minimize time to get to buried components
  • Vertex servicing
  • Central tracker servicing

9
Allow for magnet positioning
  • Coarse adjust
  • First time alignment
  • Remote alignment to remain within fine adjustment
    range
  • Magnet Coarse Adjustment options
  • Actuation
  • Screw
  • Ramp
  • Cam
  • Bellows or piston with liquid or gas
  • Piezo
  • Drive style
  • Motor (stepper or servo)
  • Can not be used in high magnetic field
  • Drive shafts can transmit torque into bore
  • Wind up problems can be eliminated with proper
    gear boxes
  • May contribute too much heat / vibration
  • Motor (hydraulic / pneumatic) (rotary or linear)
  • Seals may be a problem in high radiation areas
  • Gas may be too compressible

10
Fine adjust
  • Get to final magnet location
  • Active positioning
  • Needs to be radiation hard
  • Non-magnetic
  • Fine Adjustment Options
  • Due to the fast response, and non-magnetic
    properties of piezo electric actuators, this is
    our current choice

11
Interferometer compliant
  • Several configurations possible
  • Maximize stability / minimize detector
    penetrations
  • Holes / windows in support allow sight to magnets
  • Vacuum / gas transport lines
  • Vacuum requires a joint to the stabilized object
  • Transport lines can transmit vibration
  • If vacuum is used with windows, windows may shift
    beam
  • Gas is nice, but index of refraction changes with
    temperature
  • Heat from electronics may shift beam

12
Support tube
  • Tube passes through detector
  • Support styles possible
  • Simple Simple
  • Deflection is maximum stress is high in center
  • The center is a bad place for high stress since
    it has a smaller moment of inertia and requires
    minimal material
  • Fixed Rolling
  • Deflection is smaller stress is high on ends
  • Fixed-Intermediate Support- Intermediate
    Support-Rolling
  • Tricky stress allocation
  • Central tracker group does not like this option
  • They would like to put detectors near the inner
    masks

13
Cantilever
  • Tube is installed from each tunnel
  • May be mounted to a pier extending into pit
  • While running, support is near mask CG
  • Simple Simple
  • Deflection is maximum when door is open
  • Deflection good while running
  • Fixed Simple
  • Deflection is smaller but stress is high on one
    end

14
Detector / final focus options
  • Option 1
  • SLD style detector
  • Pro Quick access /easy detector shapes
  • Con Large pit / unstable magnets
  • Option 2
  • SLD like detector with reduced door opening
  • Concrete pillar under magnets (except last 2)
  • Last 2 magnets on short cantilever or held by
    door
  • Door supports trimmed on outside (doors may need
    counter weight)
  • Pro Quick access /easy detector shapes
  • All but last two magnets are on bedrock
  • Con Last magnets rely on detector for stability
    (but could be actively isolated)

15
Detector / final focus options cont.
  • Option 3
  • BaBar like detector split door
  • Concrete pillar under magnets (except last 1)
  • Cantilever last magnet and mask
  • Door supports trimmed on outside (doors may need
    counter weight toward IP)
  • Pro Quick access
  • Con ECAL and HCAL must be split to remove (may
    require difficult rigging)
  • Option 4
  • SLD like detector (cut off outer feet)
  • Key shaped pit
  • Roll detector to open
  • Fixture to open (to hold cantilever)
  • Pro Stable / all but last magnet on bedrock
  • Con Complicated pit / many cables to deal with
    / vac. dis-connect
  • Long down time to get to vertex detector

16
Detector / final focus options cont.
  • Option 5
  • Central detector spool package with Small
    detector layout
  • Top splits in middle (iron and HCAL move to
    sides)
  • Spool cranes out
  • Shake spool
  • Pro Stable
  • Con Complicated pit / hard to get inside spool /
    vac. dis-connect / tricky wiring

17
Assembly Procedures (Small detector /
cantilevered supports)
  • Assemble detector on shielded side of pit
  • Beam line commissioning happens using the real
    doublets on the other side of the pit with a
    temporary support
  • Remove EM magnets on pier and pull doublet back
    into tunnel
  • Rotate the detector to become parallel to the
    beam line
  • Roll the detector into place (including doors)
  • Slide cantilevered support tubes through doors
  • Make up vacuum and transfer load of masks from
    detector to the support tube

18
Vibration Issues
  • Since the extent of vibration amplification
    varies widely with various geometries, emphasis
    until this point has been put on solidifying the
    detector geometry
  • Detector revisions occur biannually
  • As detector shapes and magnet styles become more
    stable, vibration isolation methods will be
    explored further
  • Several possible vibration isolation scenarios
    are being considered
  • Under all conditions, local noise must be
    isolated from the detector
  • Local traffic minimized
  • Pumps on isolators on separate slabs
  • Well thought out plumbing and other services

19
Vibration Issues Continued
  • Find a stable site and make all components rigid
  • Many problems could arise if we do not have a
    Plan B (and the site becomes noisy)
  • Have a rigid detector and a floating (active /
    passive / both) magnet support
  • A permutation of this option may be the most
    practical for a large detector
  • Float the entire detector (or a large portion of
    it) on a gas suspension system
  • A possible air system has been considered which
    incorporates a variable natural frequency which
    allows adjustment for detector mass changes
  • Communication has begun with the LIGO group
  • Work is currently being done at LIGO to stabilize
    a several hundred kilogram mass to 1 nm
  • The LIGO system currently stabilizes a mass to a
    level several orders of magnitude better than NLC
    requirements. However, the system used is not
    currently practical for a physics detector.
    (Their frequency requirements are also different)

20
Thermal Issues
  • A high degree of positional stability requires a
    thermally stable environment
  • Detector will most likely be under a thick (6
    thick) concrete lid for radiation protection
    reasons
  • Large thermal masses should aid thermal stability
  • Thermal excursions happen slowly and require a
    coarse adjustment range for the movers
  • Tunnels which connect to pit are fairly cool at
    this point
  • Should not be a large heat source (and may be
    sealed from pit)
  • Tunnel temperature is set by local cooling tower
    capacities
  • Have looked at wet bulb maximums at several sites

21
Conclusions
  • Detector design is still undergoing changes
  • We are in contact with key people in many
    detector working groups
  • One of the more popular detector choices is being
    structurally modeled currently
  • Several issues will be studied and prototyped in
    the near future
  • Vibration isolation options will be pursued
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