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CLIC08 workshop CLIC module layout and main requirements G. Riddone, on behalf of the CMWG 15.10.2008 Home page of the TBM WG:

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Presentation on theme: "CLIC08 workshop CLIC module layout and main requirements G. Riddone, on behalf of the CMWG 15.10.2008 Home page of the TBM WG:"— Presentation transcript:

1 CLIC08 workshop CLIC module layout and main requirements G. Riddone, on behalf of the CMWG 15.10.2008 Home page of the TBM WG: http://clic-meeting.web.cern.ch/clic- meeting/CLIC_Module_Wkg/index.htm

2 CLIC08 - Module layout and requirements, GR, 15.10.2008 2 Content Introduction and general CLIC parameters Layout Main components Module configurations Main system requirement Conclusions

3 MAIN BEAM RF network Power Extraction and Transfer Structures Accelerating Structures BPM Quadrupole DRIVE BEAM Quadrupole BPM CLIC two-beam scheme 3 CLIC08 - Module layout and requirements, GR, 15.10.2008 CLIC is based on the two-beam acceleration method in which the RF power for sections of the main linac is extracted from a secondary, low-energy, high-intensity electron beam running parallel to the main linac (drive beam).

4 CLIC layout CLIC08 - Module layout and requirements, GR, 15.10.2008 4

5 5 Several activities

6 CLIC Main parameters Module design based on latest CLIC parameters Sector length based on the same number of PETS per sector Sector length based on the same number of PETS per sector CLIC08 - Module layout and requirements, GR, 15.10.2008 6 Total per linac Accelerating structures: 71406 PETS: 35703 Total per linac Accelerating structures: 71406 PETS: 35703

7 CLIC08 - Module layout and requirements, GR, 15.10.2008 7 Layout definition Optimisation of accelerating structures Definition of number of acc. structures fed by a PETS Definition of MB module length,  MB interconnection lengths Definition of length for PETS From module length, deduce available length for quad.,BPM and interconnections Check feasibility and reiterate if necessary -Module length driven by acc. structure length - Layout optimisation important for filling factor  high filling factor  higher efficiency -Module length driven by acc. structure length - Layout optimisation important for filling factor  high filling factor  higher efficiency

8 Module main types and numbers 8 Standard module Total per module 8 accelerating structures 8 wakefield monitors 4 PETS 2 DB quadrupoles 2 DB BPM Total per linac 8374 standard modules Total per module 8 accelerating structures 8 wakefield monitors 4 PETS 2 DB quadrupoles 2 DB BPM Total per linac 8374 standard modules CLIC08 - Module layout and requirements, GR, 15.10.2008

9 Module main types and numbers 9 Special modules Total per linac Quadrupole type 1: 154 Quadrupole type 2: 634 Quadrupole type 3: 477 Quadrupole type 4: 731 Other modules - modules in the damping region (no structures) - modules with dedicated instrumentation - modules with dedicated vacuum equipment - … Total per linac Quadrupole type 1: 154 Quadrupole type 2: 634 Quadrupole type 3: 477 Quadrupole type 4: 731 Other modules - modules in the damping region (no structures) - modules with dedicated instrumentation - modules with dedicated vacuum equipment - … CLIC08 - Module layout and requirements, GR, 15.10.2008

10 10 Main components: structures Accelerating structure (A. Grudiev) PETS (I. Syratchev) octant ACS: Pulsed surface heating temperature rise, accelerating gradient and maximum surface electrical field AS PETS

11 Main components: RF network PETS and accelerating structures are connected via waveguides and choke mode flanges  choke mode flanges allows the power transmission without electrical contact between waveguides. This device should be flexible in order to permit independent alignment of two waveguides. Waveguide length optimisimation based on losses, phase advance and RF to beam timing considerations High power load are needed at the outlet of the accelerating structures (1 load per two accelerating structures) CLIC08 - Module layout and requirements, GR, 15.10.2008 11

12 Main components: quadrupoles CLIC08 - Module layout and requirements, GR, 15.10.2008 12 Aperture radius:13.0 mm Integrated gradient: 14.3 Tm/m Nominal gradient: 67.1 T/m Total length:270 mm Magnet width:390 mm Magnet weight:180 kg Distance between opposite coils: 118 mm Water cooling Aperture radius:4.00 mm Integrated gradient: 70 (170, 270, 370 ) Tm/m Nominal gradient: 200 T/m Total length:420 (920, 1420, 1920) mm Magnet width:< 200 mm Magnet height:< 200 mm Magnet weight:~ 75 (110, 135, 270) kg Water cooling Drive beam Main beam T. Zickler, CLIC07

13 Main components: Instrumentation CLIC08 - Module layout and requirements, GR, 15.10.2008 13 WFM integrated in acc. structure: resolution 1  m, precision: 10  m Drive beam: ~ 47000 devices Main beam: ~151000 devices (~142000 WFM) Drive beam: ~ 47000 devices Main beam: ~151000 devices (~142000 WFM) CLIC note 764 CLIC note 764 mm mm mm  m (lab)

14 Module configurations Several configurations are possible depending on structure technologies and design –Accelerating structures can be made in quadrant or in disks –Structure can be sealed or mounted inside a vacuum tank Two configuration has been studied –In configuration #1, the accelerating structures are formed by four high-speed milled bars which are then clamped together, and the PETS bars and couplers are all clamped and housed in a vacuum tank. –In configuration #2, the ACS are made of discs all brazed together forming a sealed structure, and the PETS are made of octants and “mini-tanks” around the bars. CLIC08 - Module layout and requirements, GR, 15.10.2008 14

15 Module with tank configuration Collaboration with Dubna-JIRN, CEA-Saclay, HIP Configuration #1 CLIC08 - Module layout and requirements, GR, 15.10.2008 15

16 Module with sealed structure configuration Configuration #2 CLIC08 - Module layout and requirements, GR, 15.10.2008 16 Collaboration with Dubna-JIRN, CEA-Saclay, HIP

17 Main technical requirements Structure fabrication and assembly (CERN, HIP, CEA) –Shape accuracy for acc. structures: 5  m –Shape accuracy for PETS: 30  m Alignment/supporting system (CERN, HIP, DUBNA, NIKHEF): possibility to align separately main beam and drive beam independently –Main beam Accelerating structures on girders (cradles mechanically attached to a girder and linked by rods to the adjacent one): alignment system integration Main beam quadrupole on dedicated supports: stabilization and alignment system integration –Drive beam PETS and quadrupoles on the same girders Alignment system integration Tolerances for pre-alignment –accelerating structure pre-alignment transverse tolerance 14  m at 1  –PETS pre-alignment transverse tolerance 30  m at 1  –quadrupole pre-alignment transverse tolerance 17  m at 1s CLIC08 - Module layout and requirements, GR, 15.10.2008 17

18 CLIC08 - Module layout and requirements, GR, 15.10.2008 18 Main technical requirements Stabilization system (CERN, LAPP, SLAC, Monalisa, DESY, CEA-IRFU/SIS,..) –1.3 nm at 1 Hz in vertical direction –14 nm at 1 Hz in horizontal direction Vacuum system –5.10 -9 mbar for main beam (simulation under way to confirm the requirement); –dynamics of the H 2 O pumping in limited conductance systems must be better understood: an experimental set-up is being implemented to study H20 pumping dynamics Cooling system (CERN, HIP, WUT) Dissipated power: –AS: 600 W –PETS: 110 W –7.7 kW for a module Most stringent requirement comes from accelerating structures Different operation modes to be taken into account with different thermal loads All these systems have to be studied taking into account acceleration environment and tunnel integration

19 CLIC08 - Module layout and requirements, GR, 15.10.2008 19 Conclusions The CLIC study is carrying out a number of specialized development programs of subsystems such as high-power rf structure and micron precision alignment, and in parallel the specification for the CLIC module sub-systems is being finalized. Module design and integration have to be studied for different configurations, identifying thus areas needing dedicated study and design. Potential advantages and drawbacks are being evaluated for each configuration. Important aspects of cost are raised and basic parameters provided for other areas of the study. The module study is important as it raises feasibility issues and provides basic parameters for other areas of the CLIC study  synergy with several other working groups, such as beam physics, stabilization, CES, cost and schedule,.. Integration of the systems in terms of space reservation has been done for all the module types and detailed design started for the main systems, such vacuum, cooling, alignment, stabilisation…  work from collaborations is indispensable and highly appreciated CLIC module in CLEX from 2010 –Test/CLIC modules –String of modules

20 Future : from TBTS to TBA TBTS Test module (FP7) and CLIC modules in CLEX Two-beam module strings in next CLIC facility CLIC08 - Module layout and requirements, GR, 15.10.2008 20 H. Braun

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