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Shield Module Design Considerations Adam Carroll Van Graves July 3, 2014.

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Presentation on theme: "Shield Module Design Considerations Adam Carroll Van Graves July 3, 2014."— Presentation transcript:

1 Shield Module Design Considerations Adam Carroll Van Graves July 3, 2014

2 2Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 Overview Capability to remotely remove and reinstall the shield modules is required Shield module concept is He-cooled tungsten spheres Current shield modules weigh up to 200 tons Cradle needs to be sized to support shielding Tungsten Shielding SC1 Cradle SC2

3 3Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 20to2T5m120cm4pDL Shielding Module Volumes 123456 ModuleVolume (m^3)Weight (MT)*Weight (ton) 113.16152.0167.6 20.8910.311.9 37.4586.095.0 420.57237.6262.0 511.75135.7150.0 612.61145.6160.5 *Assuming density of 19,250 kg/m^3, packing factor of 60%

4 4Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 Shield Supports Current concept is simple stand integrated with cryostat Provides curved shelf to support shield weight without transferring load to cryostat Mounted to base platform that can be moved laterally out of beam line Some design considerations – Inter-coil forces – Shielding module support & removal – Stability under weight – Space requirements – Shorter preferred in height and along beam axis Leg footprint: 100mm X 1600mm Shelf thickness: 40mm

5 5Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 Translating the shielding Shielding Options for shield module extraction – Sliding material, low friction material to reduce force required to drag shielding Best materials not radiation tolerant Steel on steel: µ s = 0.5 – 0.8 Steel on brass: µ s = 0.35 – Tracked wheels, removes significant shielding space, difficult due to high weights, may be possible – Rollers, removes significant shielding space, but rad-hard and reliable – Lubricants likely not allowed Rollers considered for this presentation

6 6Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 31 cm 60 cm Shielding Cut Away for Roller Shielding cutaway required to allow space for rollers Potentially could be optimized to provide more shielding, but a significant localized shielding reduction will always be required

7 7Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 Hilman Rollers Rollers High weight capacity required – First concept is commercially available hardware with adequate capacity Minimum of three pairs required Continuous line of rollers reduces stress on cradle (see two slides forward for comparison)

8 8Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 Cradle Stress Initial cradle design with the addition of a track is insufficient to support the weight of the shield. Transforming the cradle into a tube significantly improves its strength.

9 9Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 Max Stress ~15ksi Max Stress above yield Cradle Stress Continuous rollers produce lower stress on cradle Other potential worse case loading situation may occur as the shield module is extracted, those situations will need to be considered to continue the conceptual design Three Pair Continuous Note: images don’t use same scale

10 10Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 Cradle Buckling Buckling of the cradle was analyzed ~55x load factor calculated – Buckling not a concern in current concept Horizontal forces from inter- coil attraction/repulsion not considered

11 11Managed by UT-Battelle for the U.S. Department of Energy Shield Module Design Considerations 3 July 2014 Conclusions Remotely handling the shielding modules is a significant challenge Rollers are an option, optimization to reduce shielding loss required Cradle requires some strengthening to handle the shielding load Extraction procedure and tooling concepts need to be developed Smaller shielding modules beneficial from remote handling perspective – One shield per coil, one coil per cryostat – Cryostat performance must be considered – More utility connections required – Increases number of inter-coil forces if each coil is in its own cryostat – More and/or larger gaps between cryostats

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