(Procurement, testing of magnets) Super-FRS Status (Procurement, testing of magnets) M. Winkler / H. Weick 8th FAIR - Machine Advisory Committee Meeting 26.-27.11.2012 In-Flight energies as high as 1500 MeV/u
Outline Super-FRS in the new Organisation Structure List of Major Milestones SC Magnets (Multiplets, Dipoles) Magnet Testing Further Magnets (Energy Buncher, radiation resistant) Target (Area) → Helmut Weick In-Flight energies as high as 1500 MeV/u
Super-FRS in the new Organisation Structure direct WP responsibility indirect WP support
List of Major Project Milestones All contracts closed for major component All major component series production started Building and infrastructure ready for assembly All components installation (incl. testing) Assembly and alignment finished Commissioning without beam Super-FRS - Q4/2016 Q2/2019 Multipletts Q2/2013 Q4/2015 Q4/2018 Q1/2019 Dipoles Q3/2013 Q2/2015 Q2/2017 Magnet Testing Q1/2012 Q4/2013 Target Q4/2014 Q1/2017
Superferric Multiplets H. Müller, H. Leibrock et al. 24 long multiplets (up to 7 m) Quadrupol triplet up to 3 sextupoles and 1 steerer Octupole coils in short quadrupoles iron dominated, cold iron (up to 37 tons) common helium bath warm beam pipe (38 cm inner diameter) per magnet 1 pair of current leads max. current <300A for all magnets 7 short multiplets (2.6 m) QS configuration Octupole coils in short quadrupoles 5 5
Status & Timeline Superferric Multiplets Approved by FAIR council as German In-Kind Strategy: first production of one long and one short pre-series multiplet Advance talks with selected industry representatives Specification in approval process Tendering documents in preparation in parallel Series production: delivery of one approximately multiplet per month is expected 6 6
Superferric Dipoles IPP, Hefei FCG, H. Müller, H. Leibrock, et al. 24 dipole units are required Iron dominated, warm iron, SC coil Large aperture ±190mm x ±70mm; 50 ton Prototype built and tested by FAIR China Group Statement at the 5th IKRB Meeting, Oct. 9, 2012 (On a possible CEA contribution to the Super-FRS Dipoles) The IKRB recommends to the Council to authorize FAIR launching the tender action for the Super-FRS Main Dipoles. The IKRB takes note that CEA offers to the GSI management to take over engineering works and contract follow-up tasks after successful tender and contract adjudication. CEA proposes this as an In-kind contribution from CEA to the FAIR project. CEA estimates such engineering support at a value of 2.43 M€. (For information: The total cost-book value of these items amounts to 8,345,655.00 €.The suggested engineering support by CEA is not a separate item of the cost book). IPP, Hefei
Timeline Superferric Dipoles Timeline according discussion with CEA Overall production time of 4 years estimated Delay due to the ‚additional‘ tendering via FAIR 8 8
Magnet Testing (Current Status) P. Schnizer et al. Collaboration with CERN Technical discussion on Work Packages Contract → Collaboration Committee CERN: Frederic Bordry, Lucio Rossi GSI: Oliver Kester, Egbert Fischer Technical Coordinators CERN: Johan Bremer GSI: Pierre Schnizer CERN: ready for testing Q1 / 2015 Next steps: Working out the details of work packages (so far 7 WP are identified: Cooling & Ventilation, Cryogenics, Electrical Power, Magnetic measurements, Power converters, Preparation for operation, Quench protection/energy extraction) 9 9
Magnet Testing (Current Status) P. Schnizer et al. Collaboration with CERN Technical discussion on Work Packages Contract → Collaboration Committee CERN: Frederic Bordry, Lucio Rossi GSI: Oliver Kester, Egbert Fischer Technical Coordinators CERN: Johan Bremer GSI: Pierre Schnizer CERN: ready for testing Q1 / 2015 Next steps: Working out the details of work packages (so far 7 WP are identified: Cooling & Ventilation, Cryogenics, Electrical Power, Magnetic measurements, Power converters, Preparation for operation, Quench protection/energy extraction) 10 10
Magnet Testing (Current Status) P. Schnizer et al. Tests to be performed at CERN (Hall 180) Using part of the infrastructure still present from the ATLAS magnet test station Building will be equipped with two over-head cranes (40T and 60T) 11 11
Radiation Resistant Magnets C. Mühle C. Will P. Vobly et al. Normal conducting magnets using mineral insulated cable (MIC) 3 dipole, 3 quadrupole, and 2 sextupole magnets Includes remote connectors and alignment Prototype dipole built and tested by BINP Prototype dipole is delivered and assembled at GSI Handling tests under way Production time is estimated to be ≈3 year No In-kind, but Russia gave a quotation Target area Quadrupoles Dipoles Sextupoles
Energy Buncher (SC Magnet) VECC, India Indian In-kind, FAIR Council approved 3 dipole units (30° deflection angle, superferric) Very large aperture (x = ±350mm, y = ±100mm); expected weight of 115 ton 3 Multiplets, Q-S config. (warm aperture ±300mm) 1 Multiplets, QT (warm aperture ±300mm) Advanced design for dipole (VECC); Review foreseen for spring 2013 VECC established contact to industry, → production time expected to be ≈3 years (dipoles) Problem will be magnet testing (on-site ?) LEB cave as alternative testing hall under discussion 13
... to be continued by Helmut Weick ... 14