CM31 - Vacuum System Update Mike Courthold Matt Hills 1.

Slides:



Advertisements
Similar presentations
Liquid Hydrogen Absorber
Advertisements

Hydrogen Pre-Operation Safety Review 4 th October 2011 Hydrogen R&D System Operational Procedures and Test Plan M Courthold.
MICE OsC – 22 nd June 2010 Liquid-hydrogen system and absorber M Hills T Bradshaw M Courthold S Ishimoto W Lau I Mullacrane P Warburton.
Vacuum Vessel Production Readiness Review
Status of the AFC at RAL Tom Bradshaw John Cobb Wing Lau Matt Hills Elwyn Baynham Mike Courthold Victoria Bayliss MICE Project Board 28 th June 2011.
Collaboration meeting, RAL, 4 th – 7th November 2009 Andrew Moss ASTeC Collaboration meeting, RAL, 10 th – 13 th november 2009 MICE RF Amplifier Status.
MICE Superconducting Solenoids: Status and Update RAL: T W Bradshaw M Courthold J Rochford M Hills D Baynham Oxford: J Cobb W Lau S Yang MICE.
23 October 2005MICE Meeting at RAL1 MICE Tracker Magnets, 4 K Coolers, and Magnet Coupling during a Quench Michael A. Green Lawrence Berkeley Laboratory.
Installation Issues Steve Virostek Lawrence Berkeley National Lab MICE CM23 at ICST, Harbin January 13, 2009.
Cooling Channel Summary Michael S. Zisman Center for Beam Physics Accelerator & Fusion Research Division Lawrence Berkeley National Laboratory MICE Collaboration.
CM26 – 26 th March 2010 Step IV: Liquid Hydrogen Infrastructure M Hills M Courthold T Bradshaw I Mullacrane P Warburton.
1 MICE Absorber working group Columbia, 13 June 2003 MICE Hydrogen System. Preliminary HAZOP. Elwyn Baynham, Tom Bradshaw and Iouri Ivaniouchenkov,
9 June 2006MICE CM-15 Fermilab1 Progress on the MICE Cooling Channel and Tracker Magnets since CM-14 Michael A. Green Lawrence Berkeley Laboratory.
Safety Review: RF Issues Derun Li Absorber Safety Review December 9-10, 2003 Lawrence Berkeley National Laboratory Berkeley, CA
MICE Project Board 23 rd September 2010 Liquid Hydrogen and General Infrastructure M Hills T Bradshaw M Courthold S Griffiths T Hayler S Ishimoto A Lintern.
1 Superconducting Magnets for the MICE Channel Michael A. Green Oxford University Physics Department Oxford OX1-3RH, UK.
Spectrometer Solenoid Fabrication & Testing Update Steve Virostek Lawrence Berkeley National Lab MICE CM24 at RAL June 1, 2009.
1 Infrastructure at RAL Iouri Ivaniouchenkov, RAL MICE Collaboration CERN, 29 March 2003.
Matthew Hills Hydrogen System – Piping and Instrumentation Diagram.
12 March 2006NFMCC Meeting, IIT, Chicago1 Progress on the MICE Cooling Channel and Tracker Magnets Michael A. Green Lawrence Berkeley Laboratory.
Hydrogen Delivery System – R&D Activities T W Bradshaw M Courthold M Hills J Rochford Daresbury Controls Group etc…
MICE Hydrogen System Design Tom Bradshaw Iouri Ivaniouchenkov Elwyn Baynham Columbia Meeting June 2003.
MICE Collaboration Meeting Harbin, China 13 – 17 January 2009 Integration Issues By Wing Lau, Oxford University.
Electrical & Control CM40 Daresbury Laboratory. CM40 Electrical Infrastructure Update RRM2 Latest Latest on Installation Progress Rack Allocations Racks.
The MICE vacuum system Presented by Mark Tucker at CM-39, 26 June 2014.
Assembly, Installation and Interfaces Steve Virostek Lawrence Berkeley National Lab RFCC Module Design Review October 21, 2008.
MICE - UK Project Progress Roy Preece 30 th April 2013.
SuperFRS Multiplett and Dipole Vacuum Interfaces Multiplett: Insulation vacuum: Insulation Vacuum Pumping flanges: Two CF flanges of the size DN160 must.
MICE RFCC Module Update Allan DeMello Lawrence Berkeley National Laboratory MAP Winter Collaboration Meeting at JLab, Virginia February 28, 2011.
Status and Integration of the Spectrometer Solenoid Magnets Steve Virostek Lawrence Berkeley National Lab MICE RAL June 15, 2007.
Date Event Global Design Effort 1 Technical System Review John Noonan, ANL Yusuke Suetsugu,KEK Paolo Michelato, INFN Milano.
BDS 11 Vacuum System for BDS [Completeness of RDR] Y. Suetsugu J. Noonan and P. Michelato Design principle Basic design Cost estimation.
MICE CM32 8 th February 2012 Magnet Group Report Vicky Bayliss Victoria Blackmore John Cobb Mike Courthold Roy Preece Mike Zisman 1.
Hydrogen system R&D. R&D programme – general points Hydrogen absorber system incorporates 2 novel aspects Hydrogen storage using a hydride bed Hydrogen.
Hydrogen Pre-Operation Safety Review 4 th October 2011 Results from Helium Commissioning M Hills.
CM1 Thermal Cycle CM1 Warmup –1/4/12 (Wed.) to 1/6/12 (Fri.) (~50 hours) –Verified turbo interlock system works CM1 Cooldown –Began 1/9/12 (Monday) –At.
Issues with variable thickness absorbers Iouri Ivaniouchenkov, RAL MICE Video Conference, 22 Jan
Magnet vacuum vessel w/radiation shield and cold mass in place Magnet leads (left) and the three cryocoolers on the top of the spectrometer solenoid service.
MICE RFCC Module Update Allan DeMello Lawrence Berkeley National Laboratory MICE CM29 at RAL, UK February 17, 2011.
UK Update Package Managers Meeting 001 Roy Preece 13 th January 2014.
CM 28 – 6 th October 2010 LH2 Infrastructure M Hills M Courthold T Bradshaw I Mullacrane P Warburton.
Hydrogen Pre-Operation Safety Review 4 th October 2011 The Hydrogen Delivery System – An Introduction M Hills.
CM27 – 8 th July 2010 LH2 System Progress and Future Plans M Hills T Bradshaw M Courthold I Mullacrane P Warburton.
56 Mhz Vacuum Mike Mapes Mhz Insulating Vacuum TURBO PUMP WITH GATE VALVE AND GAUGE SET MOUNTED ON TANK SIMILAR TO RHIC CRYOSTAT & VALVE.
CM28 - Vacuum System Update Matt Hills Mike Courthold 1.
22 October 2005MICE Meeting at RAL1 Tracker Solenoid Overview Michael A. Green Lawrence Berkeley Laboratory MICE Collaboration Meeting 22 October 2005.
1 Mice Collaboration Meeting CM33 Glasgow University 25 th – 29 th June 2012 STFC Daresbury Laboratory Electrical Infrastructure Report Authors : Ian Mullacrane.
National Ignition Facility Vacuum Systems Presentation to OLAV Workshop, ORNL July 11-14, 2011 NIF Vacuum Subsystems Managers Igor Maslennikov* John Hitchcock.
MICE RF System Overview Derun Li Center for Beam Physics Lawrence Berkeley National Laboratory Andrew Moss STFC Daresbury Laboratory MICE UK.
Hydrogen Control System MJD Courthold TW Bradshaw Y Ivanyushenkov D Baynham.
1 Mice Collaboration Meeting CM27 STFC Rutherford Appleton Laboratory, UK 7 th -10 th July 2010 Daresbury Laboratory Electrical Infrastructure Report Authors.
MICE RFCC Module Update Allan DeMello Lawrence Berkeley National Lab MICE CM25 at RAL, UK November 6, 2009.
Date 2007/Sept./12-14 EDR kick-off-meeting Global Design Effort 1 Cryomodule Interface definition N. Ohuchi.
MICE Construction Project Update: SSs, PRY, Cavities, Tracker… 1MAP Friday Meeting – January 30, 2015 Alan Bross.
LHC Beampipes Ray Veness / AT-VAC FP XII 08Beam Vacuum- R.Veness.
1 MICE Hydrogen system Working group mtg – 01/09/14.
MICE Coupling Coil Vacuum Vessel Fabrication Update Allan DeMello Lawrence Berkeley National Laboratory Coupling Coil Working Group January 28, 2014 January.
Development of Cryo-Module Test Stand (CMTS) for Fermi Lab (R.L.Suthar, Head,CDM, BARC) Cryo-Module Test stand (CMTS) is a very sophisticated equipment.
Fabrication of Remaining Components Allan DeMello Lawrence Berkeley National Laboratory MICE RF Workshop Fermilab June 2, 2014.
Status Report of the Review of Vacuum Systems and Procedures Tug Arkan, Allan Rowe 3/7/
S A Griffiths CM42 June 2015 Electrical & Control.
Installation of the T600 at Fermilab
Completion of the MICE-US construction project
Hydrogen System Update
MICE CM28 Engineering Session Summary (On behalf of Wing)
MICE Meeting at RAL, Oct-23, 2005
MICE Coupling Coil Update
SNS PPU Cryomodule Instrumentation
SNS PPU Cryomodule Instrumentation
Presentation transcript:

CM31 - Vacuum System Update Mike Courthold Matt Hills 1

MICE Cooling Channel Vacuum System 2 Connected to a Pumping trolley

MICE Vacsys Pumps Pump Ref. ModuleVacuum positionPump typePort size Pump requirement specifics Ordering DetailsCommentsLocation No. of Pump s Group Responsib le CC-VP01 Spectrometer Solenoid left and right Magnet vacuum Turbo/Roug hing Pump 100mm (was 25mm) Turbo stack with option to use as just scroll pump. Alcatel Model ATH300 Hybrid Molec PumpPump mounted on a trolley Trolley1 RAL Anesta-Iwata Scroll pump ISP-500CSV Original design asked for a DN 40 port.This is a non-conformance. RAL needs to provide a KF flange at site. CC-VP02, CC-VP03 Warm Cryostat vacuum Roughing pump 40mm (was 25mm) Dedicated dry scroll pump. Anesta-Iwata Scroll pump ISP-500CSV Ditto. Also need to decide if it must be manifolded to end of MICE Hall, or located local to module. Inside hall, local to module 2 RAL CC-VP01 AFC Left, Centre and Right Magnet vacuum Roughing pump 40mm A dry scroll Pump. Pump rate and manufacturer to be decided. Edwards Scroll Vacuum Pump XDS10 1- phase 115/230 V (set to 230 V) for Europe and UK Pump mounted on a trolley (common pumping set) TrolleyN/A RAL HA-VP2a, HB-VP2a, HC-VP2a Hydrogen Safety Pump Turbo Pump 100mm Turbo pump of 150 L/sec and vacuum pressure at this interspace is torr Leybold Oerlikon TURBOVAC SL300 DN 100 ISO-K/16KF Turbo pump to be located on the Mezzanine, behind shielding wall, with backing pump located outside hall. Each module has its own pump and vent line. Pump manufacture to be decided. Nitrogen purge is needed and is provided for by gas bottles. Note: Minimum pipe diameter required is 150mm, even though port is only 100mm. South Mezzanine (behind shielding wall) 3 RAL Max. pipe length from Cryostat to Turbo pump be less than 9.2m so that it maintain a conductance of 43L/sec -- out-gassing rate used in deriving this number is mbar/sec. HA-VP2b, HB-VP2b, HC-VP2b Roughing pump 100mm Dry scroll pump or ATEX approved Rotary Vane + Roots Blower Leybold Oerlikon TRIVAC D65B, ATEX, 3~; Cat : 3i + 3o with RUVAC WAU 251 ATEX KAT.3i/3o T3 Outside Hall 3 RAL HA-VP1 Hydrogen Delivery System Pump Roughing pump 100mmDry scroll pump? Edwards Scroll Vacuum Pump XDS10 1- phase 115/230 V (set to 230 V) for Europe and UK Outside Hall 1 RAL Warm Cryostat vacuum Roughing pump N/A Vacuum provided for by the adjacent Tracker Solenoid module N/A CC-VP01 RFCC module, left and right Magnet vacuum Roughing Pump 40mm A dry scroll Pump. Pump rate and manufacturer to be decided. Pump mounted on a trolley (common pumping set) TrolleyN/A RAL Cavity vacuum NEG pump200mm Rate and manufacturer to be advised Vacuum One CapaciTorr B1300 pump (4H0438) * Base flange with connector and heater * CF160 flange One NEG pump for each cavity; 4 in total. Each NEG pump has its own roughing port which connects to a 100mm main backing line for all 4 pumps. Location of backing pump to be decided. Note: Check whether 100mm diameter backing line is sufficient when manifolded, especially as port size is 200mm. Under RFCC module 4 LBNL This provides the vacuum for the warm Cryostat which also shares the same vacuum with the AFC warm cryostat. Dry N2 required for back filling -- could be from gas bottles Additional nitrogen is needed for the RF tuner actuator. LBL to advise nitrogen pressure, volume and consumption rate, and RAL to decide if this could be provided for by gas bottle. CC-VP04, CC-VP05 Roughing Pump TBD Outside Hall? 2? RAL? 3

MICE Pumping System – Ancillary Equipment 4 Vacuum positionPump Ancillary EquipmentOrdering DetailsQuantityModule Ancillary EquipmentOrdering Details Quantit y Magnet vacuum Gauge Isolating valve LEYCON Valves, ISO-KF Flange, DN 25 KF, Manually Operated Right-angle valve, aluminum body, DN 25 KF 2Isolating valve LEYCON Valves, ISO-KF Flange, DN 25 KF, Manually Operated Straight-Through Valve, aluminum body, DN 25 KF 1 Gauge head IONIVAC Transmitter ITR 200 S 1Gauge head IONIVAC Transmitter ITR 200 S 1 Pump Isolating Valve LEYCON Valves, ISO-KF Flange, DN 25 KF, Manually Operated Right-angle valve, aluminum body, DN 25 KF 1Burst Disc 1 Module Isolating Valve LEYCON Valves, ISO-KF Flange, DN 25 KF, Manually Operated Right-angle valve, aluminum body, DN 25 KF 1 Cross 4-Way Crosses ISO-KF (Stainless Steel ), DN 25 1 Tee Tees ISO-KF (Stainless Steel ), DN 25 2 Lines Warm Cryostat vacuum Isolating valve LEYCON Valves, ISO-KF Flange, DN 25 KF, Manually Operated Straight-Through Valve, aluminum body, DN 25 KF 1 Gauge head IONIVAC Transmitter ITR 200 S 1 Burst Disc 1 Cross 4-Way Crosses ISO-KF (Stainless Steel ), DN 251 Magnet vacuumSee CC-VP01 Hydrogen Safety Pump See separate H2 system notes Hydrogen Delivery System PumpSee separate H2 system notes Warm Cryostat vacuumN/A Magnet vacuumSee CC-VP01 Cavity vacuum St 185 Getter cartridge NEG pump controller Mains input cable for NEG pump controller (2 meter) Supply output cable for NEG pump controller (3 meter) Mating Connector (female 6 pin) Bursting disc, main isolating valve, gauge head with isolating valve

Issues & Progress Outstanding issues: Insulating vacuums: Need to decide whether roughing pumps or turbo pump stacks are required Which insulating vacuums need to be continuously pumped? What happens when magnets quench or warm up? What size pumping ports will be required? Manifolded system vs pumping trolley(s) vs Sorption pumps –A manifolded system is needed in order to »Be able to continuously pump one or more systems whilst powered »Make changes to the vacuum system whilst powered »Deal with the sudden release of plated-on contaminants (eg N2, O2, H2O) when a magnet quenches –It had thus been decided to make use of a remotely-controlled manifolded system, instead of the originally-planned manually-controlled pumping trolley(s) –This decision has since been challenged by DL staff –A manifolded system will be more costly and difficult to implement –MICE management must consider the pros & cons, make a final decision, and accept the consequences Recent progress: Pumps required for the H2 R&D system have already been purchased and installed The vacuum systems for the AFC cryostat and H2 absorber will always be kept separate from each other, and from other Cooling Channel components, for reasons of safety 5