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Estimation of the Force on the Syringe Tie-Rods from Fringing Magnetic Fields Steve Kahn 5 April 2006.

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Presentation on theme: "Estimation of the Force on the Syringe Tie-Rods from Fringing Magnetic Fields Steve Kahn 5 April 2006."— Presentation transcript:

1 Estimation of the Force on the Syringe Tie-Rods from Fringing Magnetic Fields Steve Kahn 5 April 2006

2 Tie-rod location

3

4 Tie-rod Specifications Indicate that They Should Be Non-Magnetic 1.1.1 Tie Beam 1.1.1.1 The tie beam shall be a demountable, rigid attachment joining the drive cylinder and the pump cylinder rods so that all three move simultaneously. 1.1.1.2 The tie beam shall be fabricated from SS304L or SS316L. However Stainless Steel 17-4 PH was used. –This stainless steel is martensitic in structure. –It is significantly stronger than SS304: Yields at 110 Kpsi instead of 25 Kpsi for SS 304L –It is however Strongly Ferromagnetic in all conditions. (Allegheny-Ludlam’s description). Can we use this material for the Merit syringe system or do we send it back and risk schedule delays?

5 Calculate the Field at the Tie-rods The upper figure shows the geometry of the solenoid: –Coils in red –Tie-rod is in blue Tie-rod is assumed to have the B-H properties of 1010 steel for these calculations. The lower figure shows the falloff of the field along the axis. The field at the front edge of the tie-rod (closest to the magnet) is –B Z =0.49 T –B R =0.25 T These are the fields with out the presence of iron which will distort the fields locally.

6 The Force Can Be Obtained by Integrating the Maxwell Stress Tensor on a Surface Surrounding the Steel The force from the Maxwell stress tensor is given by the following equations where the integration is performed over a surface that surrounds the steel: Since we have a 2D (cylindrically symmetric) model, the force is reduced by a factor that corresponds to the circumference subtended by the tie-rods. –I have assumed that all eight tie-rods are at the same radius which over estimates the force.

7 Summary of Force Results Force along the axial direction: –The total force on the “iron cylinder” is –36123 newtons. –The tie-rods subtend 20 cm (8 one inch rods) on a 220 cm circumference. This is an over estimate since half of the tie-rods are at a larger radius. –This gives a total force on all the tie-rods of -2580 newtons. Minus sign means toward the magnet. Radial Force: –Total radial force on “iron cylinder” is –19715 newtons. –The force on each tie-rod is -224 newtons. Minus sign means forward the axis.

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