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Large-acceptance dipole magnet GLAD

 

Responsible: GSI and CEA Saclay.

Contact persons: Haik Simon (magnet) and Thomas Hackler (kryogenic system)

 

General Information  Milestones  Literature

General Information

For the variety of experiments to be performed within the R3B project, a zero-degree superconducting dipole magnet has been designed and constructed. The main parameters of the spectrometer are: (i) A large vertical gap providing an angular acceptance of ±80 mrad for neutrons; (ii) A maximum bending angle of 40°, ensuring an acceptance close to 100% even for experiments with very different magnetic rigidities of the beam and the fragments; (iii) A high field integral of about 5 Tm, which allows a bending angle of 18° for a 15 Tm beam (e.g. 1 GeV/nucleon 132Sn or 500 MeV/nucleon 8He) or 14° for 20 Tm beams, the maximum rigidity provided by the Super-FRS. A momentum resolution Δp/p of around 10-3 can be achieved by tracking the particles with high resolution (see here). The design includes four superconducting coils which are tilted to match the required acceptance angle for the particles of interest. The side coils are optimized to reduce the fringe field, and guarantee a low magnetic field in the target region, where detectors have to be placed.

The GSI cite preparation and installation of the GLAD magnet and Helium liquifier plant has been done in common work with FAIR@GSI cryogenic project team, GSI cryogenic group, GSI electric power group and GSI magnet group. The magnet has been has been delivered in November 2015 to GSI. In February 2016 together with its large vacuum chamber the magnet has been moved into Cave C, where it will be used in experiments until the R3B experimental hall is built at the FAIR.

GLAD magnet in the Cave C at GSI.
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GLAD magnet in the Cave C at GSI.
GLAD magnet in the Cave C at GSI.
GLAD Milestones

February 2016

  • On February 11 the large-acceptance dipole magnet GLAD has been moved to Cave C. Here, it will be used in different secondary-beams experiments until the R3B Cave at FAIR is built. Four days late, also the vacuum chamber has been moved into the Cave C. More photos can be found here.
Arrival of the GLAD magnet in Cave C.
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Arrival of the GLAD magnet in Cave C.
Arrival of the GLAD magnet in Cave C.

 

November 2015

  • On November 5th, the GLAD magnet has been moved into the Target Hall at GSI, see Photos below.
RBRB GSI
GLAD in front of the Target Hall at GSI.
RBRB GSI
GLAD in front of the Target Hall at GSI.
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GLAD in front of the Target Hall at GSI.
GLAD in front of the Target Hall at GSI.
GLAD in front of the Target Hall at GSI.
GLAD in front of the Target Hall at GSI.
RBRB GSI
RBRB GSI
RBRB GSI
Transport traverse to be connected to the GLAD magnet.
RBRB GSI
GLAD magnet on the crane.
RBRB GSI
GLAD is moved with a crane to the entrance of the Target Hall.
RBRB GSI
GLAD in front of the Target Hall entrance.
RBRB GSI
GLAD is moved inside the Target Hall.
RBRB GSI
GLAD in the Target Hall.
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Transport traverse to be connected to the GLAD magnet.
GLAD magnet on the crane.
GLAD is moved with a crane to the entrance of the Target Hall.
GLAD in front of the Target Hall entrance.
GLAD is moved inside the Target Hall.
GLAD in the Target Hall.
Transport traverse to be connected to the GLAD magnet.
GLAD magnet on the crane.
GLAD is moved with a crane to the entrance of the Target Hall.
GLAD in front of the Target Hall entrance.
GLAD is moved inside the Target Hall.
GLAD in the Target Hall.
RBRB GSI
RBRB GSI
RBRB GSI
RBRB GSI
RBRB GSI
RBRB GSI
  • On November 4th the GLAD magnet has arrived to GSI. More infos and photos will follow.
G. Otto
GLAD in front of the target hall at GSI.
fileadmin/Kernreaktionen/GLAD_arrival.jpg
GLAD in front of the target hall at GSI.
GLAD in front of the target hall at GSI.
G. Otto

September 2015

  • Factory acceptance test for the GLAD magnet has been performed and approved on September 23rd.

August 2015 

  • GLAD has been transferred from the CEA Saclay to the transport company in Paris and is being prepared for a transport to GSI.
The GLAD magnet is leaving CEA Saclay.
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The GLAD magnet is leaving CEA Saclay.
The GLAD magnet is leaving CEA Saclay.

April 2015 

  • On April 24 FAIR has approved the GLAD Technical Design Report. 

 

December 2014

  • The power-supplay and quench-anaysis systems of the GLAD magnet, see photos below have been delivered on December 2 to GSI.
Quench-anaylsis system.
Power-supply system.
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Quench-anaylsis system.
Power-supply system.
Quench-anaylsis system.
Power-supply system.
  • After optimizations of the compressor control system the R3B Kryo team started in the middle of 2014 with the integration of the expansions turbines and the required extension of the UNICOS control system. Before the real start of the coldown of the coldbox with rotating turbines, several simulations had to be done in order to test the control system. In the first step, the control system was tested with fixed values, and in the second step the turbines were simulated with frequency generators. After these successful simulations the turbines were physically integrated in the coldbox to start testing under real conditions at the beginning of December. On 12.12.2014 the R3B coldbox produced the first liquid Helium after over 12 years of downtime. The 18 l vessel inside the coldbox was filled completely. For January 2015 power measurements of the plant are planned.

 

November 2014

  • The vacuum chamber of the GLAD magnet has been delivered to GSI on November 6, see photos below.
Vacuum chamber at the entrance of the testing hall.
Vacuum chamber on the crane.
Vacuum chamber of the GLAD magnet.
Inside view of the vacuum chamber.
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Vacuum chamber at the entrance of the testing hall.
Vacuum chamber on the crane.
Vacuum chamber of the GLAD magnet.
Inside view of the vacuum chamber.
Vacuum chamber at the entrance of the testing hall.
Vacuum chamber on the crane.
Vacuum chamber of the GLAD magnet.
Inside view of the vacuum chamber.

September 2014

  • At the CEA-Saclay, the coils have been installed inside of the GLAD cryostat.
Cryostat with integrated coils at the beam exit.
Side view of the GLAD cryostat with integrated coils.
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Cryostat with integrated coils at the beam exit.
Side view of the GLAD cryostat with integrated coils.
Cryostat with integrated coils at the beam exit.
Side view of the GLAD cryostat with integrated coils.

 

July 2014

 

  • The vacuum chamber of the GLAD magnet, see photo below, has been built by the VA-TEC company. The final surface preparations are beeing performed. It is expected that the chamber will be delivered to GSI in week 45.
Vacuum chamber of the GLAD magnet.
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Vacuum chamber of the GLAD magnet.
Vacuum chamber of the GLAD magnet.
  • The compressor of the R3B cryo plant passed successfully the first overnight run with the new UNICOS control system. The high and low pressures were regulated constantly, and the coldbox without turbines was also integrated in the system. Almost all pressure and temperature sensors can now be read out with UNICOS. Different flow directions through the coldbox were realized by manually driving valves with UNICOS. The modification of the cooling water system in order to reduce the noise inside the target hall was also successfully tested. For the bypass valve two additional small valves for the starting and stopping phase of the compressor were installed and tested successfully as well.

June 2014

  • The GLAD cold mass has been successfully integrated into the lower half of its cryostat, see picture below.
GLAD magnet with integrated cold mass.
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GLAD magnet with integrated cold mass.
GLAD magnet with integrated cold mass.

April 2014

  • UNICOS sample system for controlling the GLAD cryosystem has been installed. The UNICOS will be used for the whole FAIR cryosystem controls.
Layout of the UNICOS controls of the GLAD cryosystem.
UNICOS control unit.
fileadmin/_migrated/pics/GasExchange.JPG
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Layout of the UNICOS controls of the GLAD cryosystem.
UNICOS control unit.
Layout of the UNICOS controls of the GLAD cryosystem.
UNICOS control unit.

March 2014

  • Long term compressor test over three days has been successfully passed. During this test the coldbox was connected the first time after over ten years to a compressor system and a continuous Helium flow was generated through the coldbox.

February 2014

  • Cryo plant tubing has been installed, and with this cryo plant is almost fully installed.
Part of the cryo plant containing cold box and oil absorber.
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Part of the cryo plant containing cold box and oil absorber.
Part of the cryo plant containing cold box and oil absorber.

January 2014

  • On January 14, the compressor, an important part of the GLAD magnet cryoplant, has been successfuly put in operation.

December 2013

  • Test of the cold mass and coils has been successfully performed. Nominal current of 3584 A has been reached on December 5.

July 2013

 

  • Vacuum chamber for the large-acceptance dipole magnet GLAD has been designed and order for its construction has been put.
GLAD magnet and its vacuum chamber.
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GLAD magnet and its vacuum chamber.
GLAD magnet and its vacuum chamber.

 

 

  • Detailed specifications for the ramped power converter system for the GLAD magnet have been approved by the CEA-Saclay, and the system has been ordered. An overview of the power converter system is given in the figure below.
Overview of the power converter system for the GLAD magnet.
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Overview of the power converter system for the GLAD magnet.
Overview of the power converter system for the GLAD magnet.

May 2013

  • On May 22, 2013 further step in building up the GLAD magnet cryoplant (upgraded TCF 50 Helium liquifier) has been achieved - the compressor building has arrived to the GSI cite (see figure below). The compressor is installed outside the target hall on the west side inside a 6 m container, which is equipped with a special noise insulation. It is a water-cooled rotary srew compressor with 1:1 drive, with no power transmission losses and reduced maintenance costs. It provides a helium mass flow of 61.3 g/s. The compressor dimensions are 2650 x 2180 x 2120 mm3 and weight of 5.4 t, its rated motor power amounts to 200 kW and working pressure is 13.5 bar.
Installation of the compressor building.
fileadmin/_migrated/pics/compressor_GLAD.jpg
Installation of the compressor building.
Installation of the compressor building.

December 2012

  • On December 13, 2012 a helium buffer tank needed for the cryostat of the large-acceptance GLAD magnet has been arrived at GSI, see figure below. Its volume amounts to 30 000 l, and gaseous helium will be held inside at an preassure of 13.5 bar. Gaseous helium stored in the buffer will be sent to the helium liquifier where it will be liquified and cooled down to ~4.5 K and then used for the indirect cooling of the cold mass of the GLAD magnet with a two-phase helium thermosiphon.
Helium buffer for the GLAD cryostat.
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Helium buffer for the GLAD cryostat.
Helium buffer for the GLAD cryostat.

October 2012

  • Test of the cold mass is beeing performed at CEA-Saclay. In the figure below, photos of cold mass outside and inside a test cryostat are shown.
GLAD cold mass outside (left) and inside (right) a test cryostat.
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GLAD cold mass outside (left) and inside (right) a test cryostat.
GLAD cold mass outside (left) and inside (right) a test cryostat.
GLAD Literature
  • "Cryogenic Test of the R3B-GLAD Magnetand Status of its Cryostat Production", C. Mayri et al, GSI Scientific Report 2012, PHN-ENNA-EXP-59
  • "Status of the R3B GLAD Magnet Cryosystem", C. Betz et al, GSI Scientific Report 2012, PHN-ENNA-EXP-58
  • "R3B-Glad Magnet R&D Tests Program: Thermosiphon Loop With Horizontal Section, Superconducting Cable Joints at 3600 A, and
    Reduced Scale “Coil in its Casing” Mock-Up"
    B. Gastineau et al,
    IEEE Trans. Appl. Superconduct., vol. 22, No 3, pp 9001004, June 2012
    DOI: 10.1109/TASC.2011.2181471
  • "R3B-Glad Magnet Cold Mass Manufacture: Coils and Casings Fabrication and Integration"
    G. Disset et al,
    IEEE Trans. Appl. Superconduct., vol. 22, No 3, p. 4500804, June 2012
    DOI: 10.1109/TASC.2011.2180288
  • "Thermo-Mechanical Measurements on Impregnated Cu-NbTi Cable Stacks and on a
    Coil Mock-Up of the R3B-GLAD Magnet"
    C. Mayri et al,
    IEEE Trans. Appl. Superconduct., vol. 20, No 3, pp 1985-1988, June 2010
    DOI: 10.1109/TASC.2010.2041336
  • "The R3B-GLAD Quench Protection System"
    Ph. Fazilleau et al,
    IEEE Trans. Appl. Superconduct., vol. 20, No 3, pp 2074- 2077, June 2010
    DOI: 10.1109/TASC.2010.2043516
  • "Temperature Distribution During the Cooling Down of the R3B Magnet Cold Mass"
    C. Pes et al,
    IEEE Trans. Appl. Superconduct., vol. 20, No. 3, pp 1908-1911 , June 2010
    DOI: 10.1109/TASC.2010.2044650
  • "Progress in Design and Construction of the R3B-GLAD Large Acceptance Superconducting
    Dipole Spectrometer for GSI-FAIR"
    B. Gastineau et al,
    IEEE Trans. Appl. Superconduct., vol. 20, No 3, pp 328-331, June 2010
    DOI: 10.1109/TASC.2010.2040169
  • "Progress in the design & construction of the R3B-GLAD superconducting magnet", B. Gastineau et al, GSI Scientific report 2009, FAIR-EXPERIMENTS-17, p. 18.
  • "Design Status of the R3B-GLAD Magnet: Large Acceptance Superconducting Dipole With Active
    Shielding, Graded Coils, Large Forces and Indirect Cooling by Thermosiphon"
    B. Gastineau et al,
    IEEE Trans. Appl. Superconduct., vol. 18 No 2, pp 407-410, June 2008
    DOI: 10.1109/TASC.2008.922529
  • "Mechanical Behavior of the Cold Mass Assembly of the R3B-GLAD Magnet"
    Z. Sun et al,
    IEEE Trans. Appl. Superconduct., vol. 18, No 2, pp 375-378, June 2008
    DOI: 10.1109/TASC.2008.921337
  • "Comparison Between Active and Passive Shielding Designs for a Large Acceptance Superconducting Dipole Magnet"
    B. Gastineau et al,
    IEEE Trans. Appl. Superconduct., vol. 16, no. 2, pp. 485-488, June 2006
    DOI: 10.1109/TASC.2006.871328
  • "Design Study of the Superconducting Magnet for a Large Acceptance Spectrometer"
    A. Dael et al,
    IEEE Trans. Appl. Superconduct., vol. 12, No. 1, p. 353-357, March 2002
    DOI: 10.1109/TASC.2002.1018418