Patent Number: 054066000
Section: claims

1. A container for containing and transporting spent nuclear fuel, comprising: a structural shell defining a cavity for receiving spent nuclear fuel and first and second end apertures opening into the cavity, the shell having a first end portion formed of a first material and a second end portion formed of a second material, the first end portion being joined to the second end portion, wherein the first material has a higher load-bearing strength than the second material;  a bearing surface defined on the first end portion and engageable to enable hoisting of the container;  a first closure securable to the first end portion of the shell to seal the first end aperture;  a second closure securable to the second end portion of the shell to seal the second end aperture; and  a radiation absorbing shield layer affixed to the shell.  the shell has a tubular configuration;  the first end portion of the shell has a tubular configuration and is formed from a first metal; and  the second end portion of the shell has a tubular configuration and is formed from a second metal, the first end portion being welded end to end to the second end portion.  first and second trunnion mounting structures secured in opposing disposition to the first end portion of the shell; and  first and second trunnions, each defining a base and a bearing surface, the base of each trunnion being releasably securable to a corresponding one of the trunnion mounting structures, whereby the bearing surfaces of the trunnions can be grasped to hoist the container.  the second closure comprises a second closure plate welded proximate its perimeter to the second ends of the inner shell and the structural shell to create airtight joints therewith; and  the first closure comprises:  the first closure comprises a first closure plate that is releasably securable to the first end portion of the shell, whereby when secured to the shell the first end aperture of the shell is sealed and when released from the shell permitting loading and unloading of spent nuclear fuel through the first end aperture into the cavity; and  the second closure comprises:  a second closure plate secured to the second end portion of the shell to seal the second end aperture of the shell, the second closure plate defining a central access aperture; and  an access cover plate releasably securable to the second closure plate, whereby when secured to the second closure plate the access aperture is sealed, and when released from the second closure plate permitting access through the access aperture into the cavity of the shell to facilitate unloading of spent nuclear fuel through the first end aperture of the shell.  the access aperture shield assembly comprises an annular first shield member filled with a neutron absorbing shield material and defining a central aperture therethrough, the first shield member being releasably securable to the second closure plate to block a perimeter region of the access aperture, thereby reducing its effective width; and  a second shield member selectively securable to the first shield member to shield the central aperture defined in the first shield member. 2. The container of claim 1, wherein: 3. The container of claim 2, wherein the first metal comprises a high alloy stainless steel. 4. The container of claim 1, further comprising: 5. The container of claim 4, wherein the first and second trunnion mounting structures each comprise an annular sleeve secured to the first end portion of the shell, the base of each of the first and second trunnions having a cylindrical configuration and being receivable within the corresponding sleeve. 6. The container of claim 5, further comprising third and fourth trunnion mounting structures secured to the shell at a location spaced along a length of the shell from the first and second trunnion mounting structures, and third and fourth trunnions releasably securable to the third and fourth trunnion mounting structures. 7. The container of claim 5, wherein each of the first and second annular sleeves is formed from the first material used to form the first end portion of the shell. 8. The container of claim 5, wherein each of the first and second trunnions defines an internal trunnion cavity, the trunnion cavity being filled with a neutron absorbing shielding material. 9. The container of claim 8, wherein the internal trunnion cavity of each of the first and second trunnions is defined by a recess formed through the base of the trunnion, the neutron absorbing shielding material being enclosed within the trunnion cavity by a backing plate secured within and covering the recess. 10. The container of claim 1, further comprising a key way secured to an exterior surface of the shell, the key way being formed from perimeter frame members that are secured to the shell, thereby defining an engaging structure for use in securing the container during transportation, wherein at least a portion of the perimeter frame members are formed from the first material used to form the first end portion of the shell. 11. The container of claim 1, wherein the structural shell has a tubular configuration and first and second ends defining the first and second end apertures, further comprising a tubular inner shell having first and second ends, the structural shell being assembled coaxially over the inner shell to define an annular space there between, wherein the first closure is secured to the first ends of the structural shell and the inner shell and the second closure is releasably securable to the second ends of the structural and inner shells. 12. The container of claim 11, wherein: 13. The container of claim 12, wherein the first annular sealing surface on the annular member comprises a hardened metal inlay. 14. The container of claim 11, wherein the annular space between the structural shell and the inner shell is filled with a gamma absorbing shield material. 15. The container of claim 14, wherein the radiation absorbing shield layer comprises a jacket secured about an exterior surface of the structural shell and filled with a neutron shielding material. 16. The container of claim 1, wherein the first end portion of the shell defines a first annular sealing surface and the first closure defines a corresponding second annular sealing surface, wherein the first annular sealing surface comprises a hardened metal inlay. 17. The container of claim 16, wherein an annular groove is formed in the second annular sealing surface on the first closure, the annular groove having a half-dovetailed cross section. 18. The container of claim 1, wherein the radiation absorbing shield layer comprises a shield jacket comprising a jacket skin secured about an exterior surface of the shell, the jacket skin being filled with a neutron absorbing shield material. 19. The container of claim 18, wherein the shell defines a longitudinal axis, further comprising a plurality of elongate reinforcing members, embedded within the neutron shield material between the exterior surface of the shell and the jacket skin in a disposition parallel to the longitudinal axis of the shell, each reinforcing member being bent lengthwise along a longitudinal axis to define a corner edge and first and second free edges, wherein the first and second free edges of the elongate member contact one of the structural shell and the jacket skin and the corner edge of the reinforcing member contacts the other of the structural shell and the jacket skin. 20. The container of claim 1, wherein: 21. The container of claim 20, further comprising an access aperture shield assembly containing a neutron absorbing shield material, the access aperture shield assembly being securable to cover the access aperture when the access cover plate is removed from the second closure plate, thereby reducing streaming of neutron particles through the access aperture. 22. The container of claim 21, wherein: 23. The container of claim 1, wherein the structural shell defines a longitudinal axis, further comprising at least one elongate rail member secured within the cavity to an interior surface of the cavity and disposed in parallel relationship to the longitudinal axis of the shell, the rail member being constructed from a hardened, low friction metal.