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Workshop on cryogenic & vacuum sectorisation of the SPL Vacuum Sectorisation Paul Cruikshank, CERN Technology Department (TE) Vacuum Surfaces & Coatings Group (VSC)
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Topics Typical Vacuum Instrumentation Cold & RT beam vacuum Cryostat insulation vacuum LHC & LEP inputs LHC Vacuum sectorisation LEP cavity experience Sectorisation Variants for SPL Advantages / Disadvantages 09-11-092Vacuum Sectorisation
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Typical Beam Vac Config 09/11/09 Vacuum Sectorisation 3
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Typical Insulation Vac Config 09/11/09 Vacuum Sectorisation 4
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LHC; Arcs and LSS Arcs: - 8 x 2.8 km = 22.4 km - cryomagnets in a continuous cryostat LHC arc LHC LSS LSS (Long Straight Sections): - up- and downstream of the experiments - 8 x 2 x 250 m = 4 km - room temp and standalone cryo- magnets Cryogenic distribution line QRL
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LHC Vacuum Overview 6 > 300 beam subsectors
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LHC Vacuum Overview A few numbers…. CharacteristicQuantity for LHC machine & distribution line (QRL) Insulation vacuum system length22,4 km & 25 km Welds~ 250 000 (90 000 in-situ) Weld length~ 100 000 m Elastomer joints~ 18000 Elastomer joint length~ 22 000 m Multi-layer insulation~ 9 000 000 m 2 or 200 m 2 /m of cryostat Vacuum subsectors234 Vacuum subsector length214 m (machine) & 428 m (QRL) Vacuum subsector volume~ 80 m 3 Fixed turbo pumps178 Nominal turbo pumping speed0,25 l/s/m of cryostat Fixed vacuum gauges974 Mobile turbo pumping groups36 Mobile primary pumping groups36
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LHC Vacuum Sectorisation LHC Sectorisation Working Group setup in 1995 Consider beam vacuum, insulation vacuum, cryogenic layout Increased flexibility ? Reduce down-time ? Analyse types of intervention Short – diode replacement, weld repair,instrument repair Long – change of cryomagnet Additional equipment required? Implementation Cost ? LHC Project Report #60 – September 1996 Quantifications, recommendations, (dis)advantages, costs 09/11/09Vacuum sectorisation8
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LHC Sectorisation Long Straight sections Low density of cold magnets (30+20+10+10m cryostats in 250m) & lots of RT equipment – needed helium distribution line Beam vacuum sectorisation at each cold warm transition (CWT) Arc Coherent vacuum & cryogenic subsectors to allow local warm- up of 2.8 km continuous cryostat Vacuum barriers and helium plugs every 214 metres - compromise between staged installation, leak localisation, partial warm-up, additional heat inleaks, limit degraded vacuum No beam vacuum sectorisation in 2.8 km continuous cryostat QRL Separation of QRL vacuum from magnet vacuum to allow staged reception and leak localisation in long cryostats 09/11/09Vacuum sectorisation9
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Insulation vacuum sectorisation
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Insulation Vacuum (3) 11 LHC magnet cryostat QRL cryostat Jumpers Vacuum barriers
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Baseline ‘short interventions’ in insulation vacuum subsectors Scenario from LHC Project Report 60 Vacuum barriers every 214m n-2….floating, cold, under vacuum n-1thermal buffer, RT, under vacuum n intervention, RT, vented, W opened n+1thermal buffer, RT, under vacuum n+2….floating, cold, under vacuum With subsector length of 214m, it is necessary to warm-up 642m of the 2.8 km continuous cryostat n n-1 Eg repairs on diode, busbar, line Y, helium leak….but no intervention on beam vac n-2n+1n+2
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Sectorisation of LEP RF Cavities Beam Vacuum Commissioning and installation During the installation and commissioning, the RF cavities shall stay under vacuum to: Limit the contamination by dusts –Without any sectorisation, several venting will be required, increasing the risk of dust contamination. Preserve the RF commissioning on surface –Venting always implies repeating partly the RF commissioning During the pre-commissioning on the surface, absorber blocks have to be installed on the other side of the sector valves to absorb the accelerated electrons emitted by field emission. Once installed in the LEP tunnel, the sector valves were the absorbers. Modules were warmed individually to change tuners or couplers.
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Sectorisation of LEP RF Cavities Beam Vacuum RF processing is required to increase the accelerating field above 6 MV/m Injection of helium (5.10 -6 mbar, reading on the gauge) onto the cold (4.5 K) RF cavity. Sequence is as follow: Installation of a pumping group with an helium injection line (4 h) Bake out (24 h) Helium injection (3 h) …RF processing… Helium pump down (10 h minimum) needs a partial warm-up to release the condensed helium Need that each module is sectorised to allow for an RF processing
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SPL Sectorisation Variants 09/11/09Vacuum sectorisation15 Continuous Segmented Option B Segmented Option A
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Typical Insulation Vac Config Cost for vacuum system: Draft estimate from S. Calatroni Includes instrumentation, controls, cabling, in-situ leak test Insulation vacuum subsector ~ 90 kCHF Beam vacuum ‘cell’ ~ 90kCHF (cold) + 90kCHF (RT with valves) 09/11/09Vacuum sectorisation16
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SPL Sectorisation Variants Volume types Max ‘Segmented’Max ‘Continuous’ Insulation vacuum volumes - cryomodule 35 ((10+5)+6+(12+2)) 3 200m+90m+212 m Beam vacuum volumes - cryomodule + intermodule 71 35+35+1 7 3+3+1 Insulation vacuum volumes - helium distribution line 5 ? 106m*5 0 or 1 530m Total vacuum volumes11110 09-11-09Vacuum sectorisation17
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Design aspects – vacuum Advantages More modular design Minimise cold equipment – access, alignment, repairs, upgrades, unecessary outgassing, leaks, etc Modules are complete & tested before installation Disadvantages More vacuum equipment eg cold to warm transitions, intermodules More vacuum instrumentation Advantages Compact longitudinal layout – fewer CWT, fewer RF contacts Helium transfer line can be integrated – less vac systems Disadvantages Beam vacuum sectors long- cold sector valves don’t exist! Some sensitive equipment is imprisoned in cryostat - needs vacuum compatibility and validation 09-11-09Vacuum Sectorisation18 SegmentedContinuous
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Installation aspects – vacuum Advantages Minimise tunnel work and problems - modules are complete and tested before installation Fewer problems treated on- line Staged acceptance tests Decoupling of problems Disadvantages Beam and insulation vacuum systems are exposed to tunnel environment – dust contamination? 09-11-09Vacuum sectorisation19 SegmentedContinuous
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Repair aspects – vacuum Advantages Reduced search zone Decoupling of repair and other activities Limit zones of warm-up and opening of vacuum system – cost & downtime Disadvantages Difficult access at cold to warm transitions – not std interconnect design Advantages Less tasks for systematic repairs on modules – venting, repumping.. Disadvantages Equipment will see more thermal cycles – create leaks? 09-11-09Vacuum Sectorisation20 SegmentedContinuous
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Commissioning aspects – vacuum Advantages Precommissioning before installation Staged tests – smoothing of resources, earlier identification of problems Decoupling of problems Recommissioning of ‘weak’ module possible Disadvantages More volumes to commission Disadvantages Cavities need to be recommissioned if vented RF processing with helium required for field above < 6 MV/m – complicated Movable blocks or valves to absorb field emission electrons? 09-11-09Vacuum Sectorisation21 SegmentedContinuous
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Operational aspects – vacuum Advantages Limit zone of degraded ins vacuum (helium leak) Easier diagnosis of problems Disadvantages More equipment (fixed pumping systems & valves) More interlocks More risk of equipment failure More maintenance Advantages Simpler controls Redundancy in fixed pumping systems Disadvantages MCI would affect more equipment 09-11-09Vacuum Sectorisation22 SegmentedContinuous
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SPL Vac Sectorisation – next steps Which sectorisation variants are not possible? Strong vacuum constraints need to be identified & investigated – eg can we expose cavity to tunnel air, etc. Constraints for other technologies to be confirmed For retained variants, advantages and disadvantages presently expressed qualitatively, now need to be quantified in time, manpower and expenditure. Are there other vacuum aspects to add? Continue to get feedback from other operational machines 09-11-09Vacuum Sectorisation23
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Last Slide Thanks for your attention 09-11-09Vacuum Sectorisation24
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ITER/CERN Collaboration - LHC Insulation Vacuum - Paul Cruikshank - 25 June 2009 Semi-standalone cryo-magnet - typical installation and leak test sequence - HELIUM CIRCUIT JUMPER CRYO-MAGNET CRYOGENIC DISTRIBUTION LINE (QRL) CRYO-MAGNET BEAM VACUUM TUBES PUMP + DETECTOR DETECTOR
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