Dipole magnet for CBM: current status

Elena.Litvinenko CBM Collaboration Meeting Dubna 17 Oct 2008 1

P.G. Akishin, A.V. Alfeev, V.S. Alfeev, V.V. Borisov,

V.V. Ivanov, E.I. Litvinenko, A.I. Malakhov,

E.A.Matyushevskiy

JINR, Dubna

The task definition

The main task is to provide the design of a magnet with:• the working angular acceptance at least of 50° for the

height of a gap (1.2 m) and 60° for the width of a gap (1.4 m), and, for the mounting inside the gap MVD/STS detectors, the sizes of its rectangular part should be at least 1.2 x 1.2 m ;

• the magnetic yoke size along the beam is equal to 1 m;• the integral of the magnetic field in the region of the

yoke of the magnet along the beam from 1 to 1.2 T*m;• the magnetic field distribution, which is similar to the

map “FieldMuonMagnet”, that is the current standard for the magnetic field for CBM simulations.

Technical drawing

1. Beam; 2. Rack; 3. Coil; 4. Adapter; 5. Filler; 6. Support of a magnet; 7. Magnetic screens.

The conceptual project of a magnet

Yoke of the magnet

• Yoke material: magnetically soft steel with the low content of carbon

• Yoke sizes: 280 (310) x 260 x 100 [cm]

1.4 m 1.2 m2.6

0.33 m

Windings («the Cossack saddle»)

The top part of a winding with cryostat

Coil Nitric screen

Cryostat

Top part of cryostat (front view)

Top & bottom cryostats with connectors (back view)

1.216 m

0.328 m

two adapters: - current connection;- elements of monitoring systems;- transportation of helium and nitric.

SC winding cross-section

Vacuum casing

4.5˚K< 80˚K 300˚K

Nitric screen

Helium vessel SC cable

Cover of a vacuum casing

Helium pipe

Support of the nitric screen

Hatches

Pipe of the nitric screen(circulating liquid nitrogen) 328 mm

General view of the magnet

Filler facility: - evacuation of energy;- inputs for submission of liquid helium and liquid nitrogen.

Magnet geometry implementation for TOSCA

Comparison with “MuonMagnet”

Used in CBM: “MuonMagnet” New design: “Muon4”

Blue – FieldMuonMagnetRed - FieldMuon4

|By| (z) x=y=0 (target: z=0 cm)

|B| (z,y) x=0 (target: z=0 cm)

Vertical plane along the beam:

|By| (z,y) x=0 (target: z=0 cm)

Vertical plane along the beam:

|B| (x,y) z=0 (target position)

Vertical plane perpendicular to the beam:

|By| (x,y) z=0 (target position)

Vertical plane perpendicular to the beam:

|B| (x,y) z=50 cm (magnet yoke center)

|By| (x,y) z=50 cm (magnet yoke center)

|By| (x,y) z=50 cm (in the limits of Station 4)

|B| (x,y) z=100 cm (edge of the magnet yoke)

|By| (x,y) z=100 cm (edge of the magnet yoke)

|B| (x,y) z=160 cm (RICH entrance)

|Bxy| (x,y) z=160 cm (RICH entrance)

|Bxy| = sqrt (Bx2+By2)

Let us consider Standard and Compact RICH cases:

Data obtained from materials published on the site CbmRichMeeting Twiki

|B| (x,y) z=180 cm (photodetector plane for Compact RICH)

|B| z=180 cm (photodetector areas for Compact RICH)

0.047 (->0.04)0.058

0.042 (0.04->0.036)

|Bxy| z=180 cm (photodetector plane for Compact RICH)

|Bxy| z=180 cm (photodetector areas for Compact RICH)

0.047 (->0.03)0.0494

0.028 (->0.015)

|B| z=190 cm (photodetector plane for Standard RICH)

|B| z=190 cm (photodetector areas for Standard RICH)

0.034 (->0.03)0.068 (->0.03)

0.034(->0.029)

|Bxy| z=190 cm (photodetector plane for Standard RICH)

0.038 (->0.03)

0.023 (->0.02)

Geometry implementation for Geant (cbmroot)

Yoke+Coils

+Nitric Screen

+Cryostat

+Magnetic Screens & Basement

Compatibility with STS geometry

I) The suggested engineering design of the superconductive dipole magnet for CBM provides the following characteristics:

angular acceptance is 50° for the height of the gap (1.2 m) and 60° for the longest part of the width of the gap (1.4 m), and the sizes of the rectangular part of the gap 121.6 x 120 cm should be suitable for the mounting of MVD/STS detectors;

the magnetic yoke size along the beam is equal to 1 m; the integral of the magnetic field in the region of the yoke of the

magnet along the beam is equal to 1.07 T*m when the current through the coils is set to a value 0.781 MA (in the case of “MuonMagnet” the current equal to 1.447 MA corresponds to the integral equal to 1.01 T*m);

the distribution of By component of the magnetic field along the beam axis is very close to the map “FieldMuonMagnet”;

the mean values of the the new magnetic field in the regions, in which the RICH photodetectors are to be placed, are about 300 Gs for the last calculated field map.

II) The 3D model of the magnet was developed for TOSCA. The magnetic field map was calculated and converted for cbmroot. A new C++ class was developed to support the changes in the symmetry of the field.

III) The Geant geometry of the magnet was created for cbmroot and tested together with the latest available STS geometry.

IV) The final decision about the sizes, shape and positions of the magnetic screens and the basement (and material of the basement) will be made after further studies directed to the magnet optimization.

Conclusion and outlook

Backup slides

|B| (x,y) z=154 cm (end of the magnetic screens)

|By| (x,y) z=154 cm (end of the magnetic screens)

|Bxy| (x,y) z=154 cm (end of the magnetic screens)

|B| and |By| (z,y) in linear scale

“No magnetic screen” vs “Screen” cases

Dipole magnet for CBM: current status

Documents

Transcript of Dipole magnet for CBM: current status

Magnet design, final parameters Paolo Ferracin and Attilio Milanese EuCARD ESAC review for the FRESCA2 dipole CERN 28-29 March, 2012.

RESEARCH and DEVELOPMENT for CBM (at LHE JINR) Yu.V. Zanevsky Laboratory of High Energies JINR, Dubna - NEW INFRASTRUCTURE - FAST GAS DETECTORS - DIPOLE.

Simulation of Quench - FermilabSimulation of Quench In An 11 T Dipole Magnet Charles R. Orozco x 15700N 8/11/2011 . On 19 September 2008, approximately 100 of ERN’s dipole magnets

Design Study of 45-mm Bore Dipole Magnet for 11 to 12 .../67531/metadc... · Design Study of 45mm Bore Dipole Magnet for 11 to 12 Tesla Field Ryuji Yamada & Jonathan Moeller, Fermilab

Aspects of Spontaneous Lorentz Violation · motion obey the symmetry but the solutions do not. e.g., magnet dipole-dipole ints. are spatially symmetric but when a magnet forms the

Cryomodule Magnet - Fermilab · Web viewAt zero dipole current the field harmonics are less than 5 units (1 unit=10-4) at 10 mm reference radius, once the dipole correctors are ramped,

Superconducting Test Results Magnet Division · 2020-02-28 · HTSW/LTSW 2020 12 T HTS/LTS Hybrid Dipole Test Results -Ramesh Gupta. …February 28, 2020 1 Superconducting Magnet

CASE STUDY OF A DIPOLE MODEL MAGNET -A ROXIE W … · CASE STUDY OF A DIPOLE MODEL MAGNET -A ROXIE W ORKED EXAMPLE C. Volling¨ er CERN, 1211 Geneva 23, Switzerland Abstract

Ramped superferric dipole magnet for NESR

Dipole Magnet Design and InnovationsDipole Magnet Design and Innovations, Ramesh Gupta, February 23, 2009 Slide #3 BROOKHAVEN SCIENCE ASSOCIATES 35 mm Dipole Cross-section (Stangenes

Electromagnetism II Week 9. Contents Bar Magnet Bar Magnet Earths Magnetic Dipole Earths Magnetic Dipole Oersteds Rule (RHR1) Oersteds Rule (RHR1) Solenoid.

charge-charge, charge-dipole, dipole-charge, dipole-dipole ... · 01-12-2008 · charge-charge, charge-dipole, dipole-charge, dipole-dipole interaction Masahiro Yamamoto Department

4 Magnet Excitation and Coil Design · Substituting and multiplying the expression for the power per coil by 2 coils/magnet for the dipole, 4 coils/magnet for the quadrupole and 6

Optimal Permanent-Magnet Geometries for Dipole Field ... · Optimal Permanent-Magnet Geometries for Dipole Field Approximation ... real-time control of magnetic devices ... OPTIMAL

The Plasma Magnet - NASA Institute for Advanced Concepts · of the Plasma Magnet Rotating Magnetic Dipole field lines Steady dipole Field generated by Electrons moving Synchronously

charge-charge, charge-dipole, dipole-charge, dipole-dipole ... · PDF filecharge-charge, charge-dipole, dipole-charge, dipole-dipole interaction Masahiro Yamamoto Department of Energy

Optimal Permanent-Magnet Geometries for Dipole Field ...single rotating permanent magnet in any relative position [24]. The above works show the dipole model is an accurate approx-imation

Design of Turkish Accelerator and Radiation Laboratory in ......operating at 260 MHz and 1.3 GHz, one dipole magnet, ve solenoid lenses and an additional one dipole magnet that is

1 Beamline Work. Optics:- Simulation debugging (then redesign..) Commissioning Hardware:- Dipole B1 beampipe installation issue Further magnet measurements.

dipole/induced-dipole and dipole/induced-dipole attractions. Forces ...