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Target Magnets & Shielding Bob Weggel Particle Beam Lasers, Inc. Magnet Optimization Research Engineering, LLC. March 5, 2012 1.

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Presentation on theme: "Target Magnets & Shielding Bob Weggel Particle Beam Lasers, Inc. Magnet Optimization Research Engineering, LLC. March 5, 2012 1."— Presentation transcript:

1 Target Magnets & Shielding Bob Weggel Particle Beam Lasers, Inc. Magnet Optimization Research Engineering, LLC. March 5, 2012 1

2 Isometric View of Three Target-Magnet Designs Design IDS120h (top), IDS120i (middle) & IDS120j (bottom) [courtesy Van Graves] 2

3 Cross Sections of Target-Magnet Designs [courtesy Van Graves] IDS120h: I.R.’s step down gradually from 120 cm to 45 cm; minimal gaps between coils IDS120i: Large gaps between cryostats; I.R.’s = [120, 100, 80, 60] cm; gaps at [3, 9, 15] m IDS120j: 3 coils per cryostat; I.R.’s = [120, 90, 70, 50] cm; gaps at [4,10,15] m; z max = 20 m 3

4 Cross section of Coils & Shielding Vessels of IDS120h Tubes & flanges: = 7.85 g/cm 3 ; shielding = 10 g/cm 3 ; Outer ≈ 30 tons/m; Inner ≈ 8 tons/m. 4

5 Isometric View of Meshed Shielding Vessels of IDS120h 5

6 Sag of Shielding Vessel vs. Length L & Wall Thickness t O.R. max = 114 cm; I.R. min = 60 cm; γ = 7.85 g/cm 3 ; γ shielding = 10 g/cm 3 ; t in = ½t out ; ~30 tons/m. With t out = 4 cm, t in = 2 cm & L = [6, 7, 8, 9] m, sag FEM = [1.5, 2.5, 4.1, 6.4] mm  Limit L to 8 m. 6

7 Sag of Shielding Vessel vs. Length L & Wall Thickness t O.R. max = 58 cm; I.R. min = 16 cm; t out = 4 cm; t in = 2 cm; γ = 7.85 g/cm 3 ; γ shielding = 10 g/cm 3 ; ~8 tons/m. When L = [6, 6½, 7, 7½, 8] m, sag = [2.0, 2.9, 4.0, 5.4, 8.0] mm  Limit L to 7 m. 7

8 8

9 Normalized Maximum Hoop Stress σ* ≡ σ max / (B 1 j 1 a 1 ) a 1 ≡ I.R. of coil; a 2 ≡ O.R. of coil; B 1 ≡ B(r=a 1 ), B 2 ≡ B(r=a 2 ); j 1 ≡ current density 9

10 On-Axis Field Profile B(z)of Target Magnet IDS120j = 20 T over the 75-cm length centered at z = −37.5 cm. B(z=15 m) ≈ 1.5 T. 10

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13 Field Magnitude |B| ≡ (B r 2 +B z 2 ) ½ of Target Magnet IDS120j Maximum field = 20.4 T; contours at 1.5 T and integer values from 1 T through 20 T 13

14 Hoop Strain σ hoop in Magnet of Copper Hollow Conductor 700-MPa coil banding limits σ hoop in each coil to 0.35%; contour interval = 0.02%. 14

15 σ hoop in Copper & Nb 3 Sn Magnets (Most-Upstream Cryostat) Maximum hoop strain in each coil is 0.35%; contour interval = 0.02%. 15

16 σ hoop in Coils of Cryostat #2 (NbTi Conductor) Maximum hoop strain in each coil is 0.35%; contour interval = 0.02%. 16

17 σ hoop in in Coils of Cryostat #3 (NbTi Conductor) Maximum hoop strain in each coil is 0.35%. 17

18 σ hoop in Coils of Cryostat #4 (NbTi Conductor) Maximum hoop strain in two upstream coils = 0.35%; max.(σ hoop ) in downstream coil also is 0.35% if one adds an identical set of coils downstream. 18

19 Target Magnet “DS120j5”: Optimized I.R. of Flanking Coils I.R.’s of coils in cryostats #2-#4 are [120, 90, 116] cm, [76, 70, 75] cm & [67, 50, 67] cm. 19

20 On-Axis Field Profile B(z)of Target Magnet IDS120j5 Maximum field error is nearly 30% less than in design IDS120j. 20

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