Status of Detector Solenoid and Anti-DID

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Presentation transcript:

Status of Detector Solenoid and Anti-DID 2017/9/28 Yasuhiro Makida, Takahiro Okamura Design study about ILD solenoid including Anti-DID has been carried out with the cooperation of Hitach and Toshiba. Recently, Anti-DID design and stress analysis is in progress. Hitach is analyzing stresses in the Anti-DID, which has same dimensions and parameters described in TDR. Toshiba is analyzing stessed in the Anti-DID, which has smaller and simpler dimensions, because of realistic transportation.

Hitachi Study Same dimension in TDR Turn # 412 turn/coil X 3 coil Solenoid Current 22.4 kA B-H curve From TDR Iron dimension From 3D CAD data

Design Study by Hitach Anti-DID Stress Ana. 80 mm Edge Current Conductors 80 mm Edge Anti DID coil is set on Solenoid Shell. No inward displacement . Coil windings with edge structure Windings Outer Shell Contact 10 mm Edge Bonding Contact Bonding Inner Shell Solenoid Shell Cross Section of Anti DID structure

Displacement Stress Max 0.5921 mm Max 66.9 MPa Solenoid End Solenoid Center Max 44.8 MPa Max 0.5408 mm MPa

Windings Windings Outer Shell Edge Inner Shell Solenoid Shell Contact 10 mm Contact 10 mm Bond Bond Edge Contact Contact Contact Contact Inner Shell Solenoid Shell Solenoid Shell End Max 0.5407 mm Center Max 0.452 mm Max 44.8 MPa Max 185 MPa

TOSHIBA Study TOSHIBA is considering smaller and simpler anti-DID, which meet the field requirement. Anti-DID coils are wound in a factory and are set on solenoid in an assembly build on-site.

Design Study by Toshiba Solenoid Field I.R. (mm)29.7 3215 Axial turn # 40 O. R. (mm) 3570 Radial turn # 11 L (mm) 7350 Total turn # 440 Conductor axial W (mm) 61.3 Current (kA) 22.5 Conductor radial W (mm) 32.3 Current Density (A/mm2) 11.4 Ampere Turn (MAt) 29.7 B=4.56T Sored Energy 2.16GJ

Design Study by Toshiba Anti-DID I.R. @ Curve (mm) 3760 Straight region elevation angle (degree) 30 O. R. @ Curve(mm) 3768 Radial turn # 150 L @ straight (mm) 1200 Thickness turn # 2 Winding W (mm) 1000 Total turn # 300 Winding Thickness (mm) 8 Current (A) 1067 Conductor Width (mm) 6.67 Current Density (A/mm2) 40 Conductor Thickness (mm) 4 Ampere Turn (MAt) 0.32 B=0.036T Sored Energy 0.179GJ

Design Study by Toshiba Anti-DID alternative configuration

EMF in Anti-DID with Yoke and Solenoid Fx (MN) Fy(MN) Fz(MN) Opera EXCEL Coil 1 1.59 1.15 -0.33 -0.44 0.00 Coil 2 -1.59 -1.17 Coil 3 -1.76 -1.27 -0.56 -0.43 Coil 4 1.76 1.28 Coil 1 Calculated Area at Curve Coil 2 Calculated Area at Straight Coil 3 Coil 4 B field by Opera → EMF by Excel

Design Study by Toshiba Anti-DID EMF Straight 1 X Position (mm) Straight 2 X Position (mm)

Design Study by Toshiba Anti-DID EMF Curve 1 Angle from vertical center(degree) Cureve 2 Angle from vertical center(degree)

1 2 EMF @ straight 3 1 4 3 4 7 2 5 8 6 5 6 7 8 1

1 2 EMF @ curve 4 3 2 1 3 4 8 7 6 5 5 6 7 8

Design Study by Toshiba Anti-DID Support Anti DID coils are supported by frame wall raising from outer support shell of the main solenoid.