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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Implementation Plan WBS exists Working on a “bottoms up” cost estimate The following gives some general outline of our plans for the rest of the facility.
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 In order to meet the requirements in DOE Order 420.2A, Safety of Accelerator Facilities, C-AD has incorporated a description and safety assessment of the new pre-injector into the current Safety Assessment Document for C-AD. At the appropriate time, C-A Department will obtain an approved Accelerator Safety Envelope for the new pre-injector from DOE and perform an Accelerator Readiness Review in accord with 420.2A prior to commissioning and operations. Safety Assessment Document for C-AD SAFETY The C-A Department conforms to the requirements of ISO 14001, Environmental Management System, and OHSAS 18001, Occupational Safety and Health Management System. Thus, in addition to DOE requirements, documentation of environmental protection and occupational safety and health programs for new pre-injector facilities will be prepared and audited by independent parties. This documentation will include: Environmental Process Evaluations for all processes with significant environmental aspects Facility Risk Assessments for all facilities and areas Job Risk Assessments for all jobs Radiation Safety Committee reviews Accelerator System Safety Review Committee Readiness Reviews Work planning Generation of formal procedures
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Work breakdown structure
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 EBIS HARDWARE Electron gun – have detailed design. Will build in house. (Uses many “catalog” parts). Cathodes – procure from Novosibirsk. Collector – Detailed design. Some parts fabricated outside, some in house. Superconducting solenoid – possible fabrication by BNL magnet division. Otherwise, procurement. Trap electrodes, etc. – fabricate in house
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 LEBT – will fabricate components in-house External ion sources: LEVA – have. Easy to make. Hollow cathode – have. Easy to make. Chordis – would procure from Danfysik
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 RF STRUCTURES As presented yesterday, RFQ, IH Linac, and bunchers – Frankfurt/GSI likely RF ps’s – procure, or possibly MIT Bates Lab collaboration. Have vendor quotes for both RFQ/Linac rf systems, and buncher rf systems. RFQ and IH ~ 350 kW amps
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Description# UnitLength Design Vacuum Level< 1x10 -9 Torr Beamline Length 40 m Special Dipole Vacuum Chambers 2 1.8 m Gate Valves, 10” CF 100.14 m Gate Valve 8” CF 80.12m Sputter Ion Pumps, 20 l/s 5 Cold Cathode and Pirani Gauge Set 18 Residual Gas Analyzers 1 Turbopump/Dry Pump Stations, 7 Cryopumps 10 Diffusion Pumps with Baffle 2 NEG cartridge pumps 2 Titanium Sublimation Pumps 4 Insitu Bake Temperature for HEBT line 200C Vacuum Systems
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 SOLENOIDS TypeLength (cm) Aperture Radius (cm) Field (T)Current (A) Voltage (V) E-Gun SolenoidSOL15.2412.70.2230080 Collector SolenoidSOL12.7 0.1530080 LEBT SolenoidSOL24.15.11.252000? QUADRUPOLES TypeLength (cm) Aperture Radius (cm) Gradient (T/m) Current (A) Voltage (V) MEBTPMQ3.5110145010 MEBTEMQ1023345010 MEBTEMQ1023845010 MEBTEMQ1023645010 MEBTEMQ1023845010 LINACEMQ9.21.34445010 LINACEMQ16.21.34245010 LINACEMQ9.21.34445010 LINACEMQ9.21.34445010 LINACEMQ16.21.344.545010 LINACEMQ9.21.34445010 HEBTEMQ20.3251.52535 HEBTEMQ20.32512535 HEBTEMQ20.32522535 HEBTEMQ20.3251.42535 HEBTEMQ20.3251.62535 HEBTEMQ20.32512535 HEBTEMQ20.32512535 HEBTEMQ20.32552535 DIPOLE Bend Angle Gap (cm)Radius Curvature (mm) Field (T)Current (A) Voltage (V) HEBT73°1012801.3328512.6 HEBT73°1012801.3328512.6 Solenoids – fabricate in house MEBT quads – same as SNS MEBT quads HEBT quads – existing (from decommissioned beamline). Dipoles – undecided (probably procure) MAGNETS
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 LEBT Solenoid (H- linac) Pulsed
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Legend CT Current Transformer MW Multiwire Profile Monitor FCFaraday Cup/Beamstop FFCFast Faraday Cup EMEmittance (pepperpot) TOFTime of Flight, Hi-Res & Inline COLCollimator EBIS Diagnostics Layout CT MW MW/FC FC Booster Ring FC FFC CT Quantities CT 8 MW 4 FC8 FFC1 E2 TOF2 COL1 EM COL TOF
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Device EIL LEBTMEBTHEBTTotal TOF High Resolution11 TOF Inline11 Emittance112 Faraday Cup21249 Current Transformer1123 7 Profile Monitor13 4 Collimator11 Mamyrin time of flight – have “prototype”, and detailed design. Inline TOF – have prototype. Pepperpot emittance – Have detailed design. Building prototype. Profile monitors – 3 from Tandem line. 1 procurement. Faraday cups – mixed, homemade, and procured. Collimator – homemade, same design as used at Tandem.
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Schematic of Mamyrin TOF
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Controls: EBIS controls – based on Test EBIS controls. Accelerators & transport lines – standard RHIC-type controls. Cooling systems: Similar to existing units. Power Supplies: Most are standard procurements. Most notable units are: collector ps (15 kV, 15A), pulsed dipole ps’s (12 V, 3000 A ?), and EBIS platform 100 kV isolation transformer/HV pulsing.
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Cooling Systems
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 FACILITY MODIFICATION
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 FACILITY MODIFICATION
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 SCHEDULE
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 R&D $ requested this year from DOE: Main tasks: Fabricate the collector/extraction and test offline. Measure the temperature distribution on the collector, and optimize the electron beam spreading on the collector surface. Put the present test EBIS on a HV platform. Design and fabricate the LEBT line. Measure output beam emittance vs. trap potentials, ion energy, charge state (confinement time), and ion species, at ~ final EBIS parameters. (In addition, this will then allow this source/LEBT to be used for testing of the final RFQ with beam at least one year sooner than if one were to wait for the RHIC EBIS)
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 Schedule “highlights” (present thinking) Year 1: Procure RFQ Procure/fabricate EBIS solenoid Procure 1 RF ps Fabricate EBIS trap region structure Year 2: Building addition Procure linac and bunchers Procure HEBT dipoles Fabricate LEBT components Test RFQ on Test EBIS Fabricate electron gun, collector, chambers, … Preassembly of EBIS in equipment bay Year 3: Procure collector ps Procure 2 nd RF ps Procure HEBT dipole ps Fab/procure diagnostics Install EBIS-to-Linac in final location Operate EBIS in final location Year 4: Install HEBT Test beam through RFQ, Linac Commission full system
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 5-Year Construction Schedule (AY$) (preliminary projection)
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J. Alessi Implementation Plan EBIS Project Technical Review 1/28/05 SUMMARY The Test EBIS has demonstrated that an EBIS meeting RHIC requirements can be built. The RHIC EBIS design incorporates improvements to make it a more reliable device for routine operations. The RFQ and Linac are straightforward, very similar to existing devices. No real issues related to the rest of the beamline or Booster matching. A reasonable design exists for the beamline. We feel that we are ready to begin construction of many components, and can complete design details on remaining components within one year.
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