Presentation is loading. Please wait.

Presentation is loading. Please wait.

Scientific support Scientific laboratories have the qualified specialists in fields of accelerator physics and technique. They calculate and model the.

Similar presentations


Presentation on theme: "Scientific support Scientific laboratories have the qualified specialists in fields of accelerator physics and technique. They calculate and model the."— Presentation transcript:

1

2 Scientific support Scientific laboratories have the qualified specialists in fields of accelerator physics and technique. They calculate and model the physical and technical processes and equipment in collaboration with Design Department (~ 90 qualified designers) The used tools: 2D&3D Mermaid (magnetic elements) ANSYS (mechanical and magnetic elements) Solid Work (mechanical elements)

3 Accelerator Magnets Magnets (prototypes) for SSC (USA) Magnetic elements for the BESSY-II synchrotron (Germany) Magnetic elements for the Swiss Light Source (Switzerland) Steering magnets for the KEK B-factory (Japan) Dipoles and quadrupoles for the LHC transfer lines (CERN) Four types of dipoles for LHC (CERN) Dipoles and quads for the Grand Sasso transfer lines (CERN) Dipoles and quads and sexts for the SAGA light source (Japan) Quadrupoles for SNS (BNL, USA) Quadrupoles for the SOLEIL booster (France) Sextupoles for Diamond synchrotron (UK) Octupoles and sqew-quadrupoles for the Duke University synchrotron (USA) SR magnetic system (dipoles, quads, sexts and octupoles) for the MLS (Germany) Transfer Line for the Metrology Light Source (Germany) Quadrupoles and Sextupoles for the ALBA (Spain)

4 Prototypes of magnets for SSC (1993) - LEB sextupole magnet. - LEB low/high field quadrupole magnets. - LEB steering magnet. Accelerator Magnets

5 BESSY-II booster synchrotron (1995) Design, manufacture and installation in the tunnel Accelerator Magnets Transportation of the magnet assembly

6 Accelerator Magnets KEK B steering magnets (1997) BINP has designed and fabricated correction magnets for the high energy (HER) and low energy (LER) rings of the KEK B-factory.

7 Accelerator magnets SLS (1999-2000) 306 quadrupole and sextupole magnets Installation and alignment

8 Accelerator magnets

9 MBI and MQI for LHC injection transfer line (1999) Accelerator magnets ParameterUnits Value Number of magnets 360 Specified operating fieldT1.81 Gapmm25 Magnetic lengthm6.32 Good field region:mm   Integral field quality  Bdl/  Bdl in the good field region 0404 Current peak at B=1.81TA5270 Dissipated power at B=1.81TkW11 Overall lengthmm6700 Overall width:mm584 Overal1 heightmm367 Total weightkg8800 ParameterUnitsValue Number of magnets 180 Nominal gradientT/m53.5 Bore diametermm32 Effective lengthm1.4 Good field region over X, Y :mm  20 Field quality  G/G,  Gdl/  Gdl in the good field region   2  10 -3 Current peakA530 Overall lengthmm1500 Overall width:mm392 Overal1 heightmm411 Total weightkg1070 Dissipated powerkW11

10 Accelerator Magnets “Warm” magnets MBW MBXW MBG L: 3.4 m 3.4 m 6.3 m B: 1.4 T 1.4 T 1.9 T No: 24 35 78 MCIA correctors CERN 2002-2003 100 Horizontal/Vertical. correctors L = 0.45 m B = 0.3 T

11 GOLDEN HADRON 2002 Awarded to BUDKER INSTITUTE of NUCLEAR PHYSICS, Russia In recognition of their outstanding achievement in producing MBI and MQI magnets for the Large Hadron Collider at CERN

12 Accelerator Magnets SAGA SR source (Japan), 2003 16 C-shape curved dipole magnets 40 quadrupoles 16 sextupoles

13 Accelerator Magnets Quadrupoles for SNS (BNL, USA) SOLEIL booster quadrupoles (2004)

14 Accelerator Magnets DIAMOND sextupoles (2004-2005) 174 sextupoles + 2 prototypes

15 Accelerator Magnets Transfer Line of the Metrology Light Source (2006) Bending magnet Quad (10) & corrector (8)

16 Accelerator Magnets Magnetic system of the Metrology Light Source (2005-2006) Aperture radius Yoke length Gradient Good field radius dGL/GL Magnetic length Current Power loss 35 mm 165 mm 13 T/m 30 mm ≤ 2*10 -3 200.6 mm 92.7 A 1.3 kW Aperture radius Yoke length Strength Good field radius dSL/SL Magnetic length Current Power loss 38 mm 80 mm 280 T/m 2 30 mm ≤ 2*10 -2 100.2 mm 34 A 240 W Aperture radius Yoke length Strength Good field radius dOL/OL Magnetic length Current Power loss 43 mm 80 mm 2400 T/m 3 30 mm ≤ 2*10 -2 99 mm 6.1 A 12 W

17 Accelerator Magnets Magnetic system of the Metrology Light Source (2005-2006) Bending magnets 100 mA 600 MeV Number of magnets8 Bending angle, deg45 Bending radius, mm1528 Gap, mm50 ± 0.02 Field range, Tup to 1.5 Good field area, mm 2 60 x 36 Homogeneity dB/B  2.5x10 -4

18 Magnetic Field Measuring Systems NMR measuring system (Duke Univ., USA), 1995 3D multi-channel magnetic field measuring system for Babar detector (SLAC, USA), 1998. Rotating coils measuring system (PSI, Switzerland), 1999. Hall probes array magnetic field measuring systems (FEL Duke), 1995; (BESSY), 1997; (PSI, Switzerland), 1999; (SOLEIL), 2005 Sensor for direction of magnet line measuring (BINP, FNAL).

19 Magnetic Field Measuring Systems Rotating coils measuring system (PSI, Switzerland), 1999.

20 Magnetic Field Measuring Systems Hall probe measuring system (SOLEIL, France), 2005.

21 Magnetic Field Measuring Systems MBW magnet field mapping with the Hall probe array. MLS Dipole magnet field mapping with the Hall probe array.


Download ppt "Scientific support Scientific laboratories have the qualified specialists in fields of accelerator physics and technique. They calculate and model the."

Similar presentations


Ads by Google