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Proposal for quadrupole families

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Presentation on theme: "Proposal for quadrupole families"— Presentation transcript:

1 Proposal for quadrupole families
Winni Decking, Bernward Krause, Sasha Petrov Winni Decking

2 Assumptions Magnet families grouped to reduce production cost, simplify production and installation. Savings in investment cost to be compared with disadvantages in operating costs. Where possible, existing magnets (or magnet designs) should be used. In many cases the present magnet specifications can be adopted. Selection of magnetic material (or combination with non-magnetic material) should ensure that quadrupoles are operated outside the remanence and are excitable to saturation. The ratio of bore radius to quadrupole length should not be smaller than ¼. The maximum pole tip field should be around 1 T (or conservative 0.75 T). Winni Decking

3 Assumptions The maximum/nominal/minimum energy in the different sections is: I1: MeV B1: MeV B2: GeV CL…: GeV The magnet bore radius should not be smaller than I1: 20 mm B1: 20 mm B2: 20 mm CL…: 25 mm Und. : 10 mm Winni Decking

4 Distribution of integrated gradients
Maximum integrated quadrupole gradient for all warm XFEL magnets, assuming maximum energy (i.e. 0.15/0.8/3/25 GeV) along the beamline. Maximum integrated quadrupole gradient for all warm XFEL magnets, assuming nominal energy (i.e. 0.15/0.5/2/17.5 GeV) along the beamline. Winni Decking

5 Quad Families Name Length [m] Max. Int. Grad. [T/m*m] Bore-radius [m]
Max. Bpole [T] Location Count QA 0.1 10 0.01 1 Undulators 126 QI 0.2 0.025 0.125 Injectors 26 QC 2 0.25 Bunch Compressors Field quality 10-4 on a radius of 0.6 x r 45 QD 4 0.5 18 QE 6 0.75 Beam Distribution 55 QF 0.35 / 0.5 14 1 / 0.75 100 QH 0.7 / 1.0 28 46 QG 80 0.05 Dump Hera QC: L=1.0, Int. Grad=19 T/m*m 3 Optimization and final layout of quadrupoles at Efremov institute (St. Petersburg) Proposal expected by end of this year Winni Decking

6 Apertures in the XFEL Winni Decking Winni Decking

7 Beam Stay Clear (smallest aperture required for the beam and its halo)
Definitions Beam Stay Clear (smallest aperture required for the beam and its halo) Magnet Aperture or Magnet bore (largest possible outer vacuum chamber dimension) Magnet bore – vacuum chamber wall thickness - alignment tolerance Physical required inner vacuum chamber dimensions Winni Decking

8 Remark Numbers always describe the semi-major and semi-minor axis of an ellipse Winni Decking

9 Physical Required Aperture
Includes resistive and geometric wake from vacuum chamber, collimators, kicker vacuum chamber Winni Decking

10 Winni Decking

11 Collimators and spoilers Kicker vacuum chamber
Remarks Inner vacuum chamber radius 20 mm in collimation / beam switch yard section Exceptions: Collimators and spoilers Kicker vacuum chamber Switch yard septum section Winni Decking

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