Patent Number: 043364608
Section: description

DETAILED DESCRIPTION OF THE DISCLOSED EMBODIMENT Referring now to the drawing in which like numbers indicate like elements throughout the several views, it will be seen that there is a cask 10 of a generally cylindrical shape suspended from a lifting yoke 12. The cask 10 generally comprises a hollow thick-walled cylindrical metal body 14 having a top end 16 and bottom end 18, a removable closure lid 20 removably attached to the top end of a non-removable closure 22 permanently fixed in the bottom end, thereby defining a generally cylindrical chamber 24 (FIG. 5) for accepting conventional nuclear fuel assemblies. The size and shape of the cask 10 may be varied to accommodate differently designed fuel assemblies, typical of which are PWR, BWP, Biblis/Westinghouse XL and the like. The cask 10 is provided with pressure relief valves (not shown) for relieving pressure which may build up in the chamber 24 due to heat generated by spent nuclear fuel contained therein. The cask 10 is also provided with drain valves (not shown) for draining liquid from the chamber 24. The cask 10 may therefore be of the wet cavity or the dry cavity type. Both pressure relief valves and drain valves are well known in the art and their design for use in combination with the cask 10 is within the skill of the art. The removable lid 20 is attached to the top end 16 of the body 14 by a plurality of bolts 26. The lid 20 fits inside a flange 28 to provide a tight seal to the chamber 24. Additional techniques for assuring a tight seal, such as providing one or more elastomeric O-rings interposed between the body 14 and the lid 20, may also be used. The non-removable closure 22 is secured in the bottom end 18 of the body 14 by suitable means, such as by welding, so that the chamber 24 is sealed both ends when the lid 20 is in place. Disposed about the central portion of the body 14 is a neutron shield 30 to provide additional neutron attenuation. The neutron shield 30 may comprise a 1.96 inch thick layer of water-extended polyester (WEP) encapsulated in a channel, or a borated water-ethylene glycol solution contained in a 1.8 inch thick annular tank. The WEP material is a solid matrix of hardened polyester plastic and encapsulated water-boron-ethylene glycol liquid droplets. The water-extended polyester is retained and hermetically sealed by an epoxy potting compound. Disposed adjacent the top end 16 of the body 14 is a tie down plate 32 used for securing the cask 10 to a transport vehicle as will be described in more detail hereinbelow. Disposed on opposite sides of the body 14 adjacent the top end 16 of the cask 10 are a pair of multiple element trunnions 34, 36. Each trunnion 34, 36 is comprised of a plurality of elements to provide dual load path redundancy to the trunnions which bear the full weight of the cask 10 when it is lifted. In this manner, should one element fail, that portion of the weight of the cask 10 supported by that trunnion will be supported completely by the remaining element of that trunnion. Optionally, a pair of multiple element trunnions 37a, 37b may also be disposed on opposite sides of the body 14 adjacent the bottom end 18 of the cask 10. Formed in the surface of the body 14 of the cask 10 is a cylindrical groove 38 and an annular groove 40, as best seen in FIG. 2 and 3. Interposed between the cylindrical groove 38 and the annular groove 40 are a plurality of threaded holes 42 for receiving the threaded ends of bolts 44 which secure the trunnions 34, 36 to the body 14. Each trunnion 34, 36 includes an inner trunnion element 46 and an outer trunnion element 48. The inner element 46 is composed of a solid piece of material having a plurality of holes 50 therein to pass the bolts 44 therethrough. The inner element 46 also includes a boss 52 of the same size and shape as the cylindrical groove 40 so as to be received in the cylindrical groove when the trunnions 34, 36 are bolted to the body 14. The outer element 48 is hollow and fits over the inner trunnion 46 and is received in the annular groove 42 when bolted in place. The outer trunnion 48 also has a plurality of holes 54 therein for passing the bolts 44 therethrough. Two flanges 56, 58 define a channel or groove 60 in the outer element 48. The groove 60 is designed to receive the lifting yoke 12 and thereby prevent it from accidentally slipping off the trunnions. A cover plate 62 (shown partially broken away in FIG. 2) having a plurality of holes 64 therein for passing the bolts 44 therethrough is provided on the outer element 48. The cover plate 62 also includes a flange 66 which extends beyond the flange 58 of the outer trunnion 48 to thereby deepen the groove 60 and provide an additional redundancy to the trunnions 34, 36. That is, if the flange 58 were to fail, the flange 66 would retain the lifting yoke on the trunnions 34, 36. In order to attach the trunnions 34, 36 to the body 14, the inner trunnion 46, the outer element 48 and the cover plate 62 are positioned so that the holes 50, 54, 64 are arranged in axial alignment and the bolts 44 are inserted therein and tightened. The cask 10 may then be lifted by the trunnions 34, 36 using the lifting yoke 12. It will be appreciated by those skilled in the art that the weight of the cask 10, when suspended by the trunnions 34, 36, is applied to both the inner element 46 and the outer element 48 of each trunnion. It will also be appreciated that the boss 52 of the inner element 46, when received in the cylindrical groove 38, and the outer element 48 when received in the annular groove 40, form separate shear registers. The weight supported by each of the trunnions 34, 36 is therefore applied via two separate and independent paths. Should either the inner element 46 or the outer element 48 of either trunnion fail, the other element is sufficient to support that portion of the weight of the cask 10 supported by that trunnion. It is specifically contemplated that means other than the bolts 44 may be used to detachably attach the inner element 46 and the outer element 48 to the body 14. For example, the annular groove 40 and the annular outer element 48 may be provided with mating threads so that the outer element may be screwed into and out of engagement with the annular groove. Other means of attachment within the skill of the art may also be used. In order to remove the trunnions 34, 36 to permit inspection of the inner element 46 and the outer element 48, the bolts 44 need merely be removed. The inner element 46 and the outer element 48 may then be removed and tested for defects by methods known in the art, such as by x-ray, magnafluxing or the like. If a defect is found, the defective element can be replaced and the trunnions 34, 36 bolted back in position. Referring now more particularly to FIGS. 1 and 6, it will be seen that the lifting yoke 12 generally includes a pair of side arms 68, 70 and a head piece comprising two trapazoidal lifting plates 72, 74 engagable with the side arms and a conventional crane hook (not shown). Each plate 72, 74 also has three holes 76-80 for receiving locking pins 82-86 therethrough. Both the side arms 68, 70 and the lifting plates 72, 74 comprise a plurality of plate elements laminated to provide a single piece. For example, the side arm 68 is comprised of three plates 68a, 68b, 68c fastened together with bolts (not shown). The materials used for the plates 68a-68c are selected so that any two of the plates will support one and one-half the anticipated load placed on the side arm 68 during lifting of the cask 10. In this manner, should any one of the three plates 68a-68c fail, the other two plates are still capable of lifting and holding the cask 10 without breaking. Furthermore, the side arm 68 may be disassembled by removing the bolts holding the plates 68a-68c together, thereby permitting individual inspection of the plates using known techniques, such as x-ray, magnafluxing and the like. If one of the plates 68a-68c is found defective, it may be replaced with an identical plate and bolted back together to form a new side arm unit. The other elements of the lifting yoke 12 are similarly constructed. The side arm 70 includes three plates 70a, 70b, 70c; the lifting plate 72 includes three plates 72a, 72b, 72c; and the lifting plate 74 includes three plates 74a, 74b, 74c. Each element can support one and one half its anticipated load with only two plates; and each element can be disassembled, inspected, replaced, if necessary, and reassembled. In addition to each element of the lifting yoke 12 being disassemblable, the lifting yoke may be disassembled, that is, the side arms 68, 70 are separable from the lifting plates 72, 74. The ends of the lifting plates 72, 74 and the side arms 68, 70 fit together with mating slots so that the side arms are hung from the lifting plates rather than being welded thereto. This not only permits disassembly of the lifting yoke 12, but also dispenses with the need to inspect the integrity of welds. The end 88 of each of the side arms 68, 70 is open hook or J-shaped, with the radius of the opening being slightly greater at the mouth 71 of the opening than at the crotch 73. The ends 88 of the side arms 68, 70 are designed to engage the groove 60 in the trunnions 34, 36 attached to the cask 10 in the manner best shown in FIG. 1. It will be appreciated by those skilled in the art that the flange 56 of the outer element 48 and the narrowing of the opening at the crotch 73 of the side arms 68, 70 guides the side arms into engagement with the groove 60 and that the flanges 58, 66 prevent the side arms from sliding out of the groove. Thus, the lifting yoke 12 provides a redundant means for lifting the cask 10 by the trunnions 34, 36. During transport of the cask 10, for example, from a reactor site to a reprocessing plant, it is essential to protect the cask against damage from a crash or impact. The present invention therefore provides a pair of removable impact limiters 90, 92 for engagement with the ends 16, 18 of the body 14 of the cask 10 (FIGS. 4 and 5). Both impact limiters 90, 92 are essentially the same in design and comprise an annular collar 94 encircling a central domed section 96 having a convex impact surface. The domed sections 96 of the impact limiters 16, 18 are of essentially the same diameter as the outside diameter of the body 14 of the cask 10 and generally fit flush against the closure 22 and the lid 20 respectively. The inside diameter of the annular collar 94 is only slightly greater than the outside diameter of the body 14 so that the annular collar can slip over the ends 16, 18 of the body. The domed section 96 is attached to the annular collar 94 such that when the domed section is seated against the lid 20 or the closure 22, a portion of the annular collar extends over the body 14. Both the annular collar 94 and the domed section 96 are essentially hollow metal shells filled with a crushable substance, such as balsa wood or California redwood. Holes 98 are provided through the domed section 96 so that bolts 100 can be inserted therethrough. The bolts 100 engage threaded holes 102 in the edge of the body 14 in the bottom end 18 to thereby secure the impact limiter 92 thereto. Bolts 104 also engage threaded holes 106 in the flange 28 at the top end 16 of the body 14 to thereby secure the impact limiter 90 thereto. It will be appreciated that in a head-on collision the domed sections 96, 98 would come into contact with a flat obstruction before the annular collars 94. Furthermore, as the domed sections 96, 98 collide with a flat obstruction, only the central portion of the domed section would initially contact the obstruction, with a progressively larger area coming in contact as the central portion collapsed and the collision continued. In this manner, the force of a collision is spread out over a longer period of time than would occur if the impact limiter were flat. The forces exerted on the cask 10 in a collision are therefore reduced over those experienced by the cask having a flat impact limiter. The overall operation of the disclosed cask is now considered. When a nuclear fuel assembly at a nuclear power plant is exhausted for fissionable reaction purposes, the fuel assembly must usually be removed from the reactor vessel so that a new fuel assembly may be substituted therefor and the old fuel assembly transported to a reprocessing plant for recycling or to a storage facility for long term storage of the spent nuclear fuel. In order to perform this operation, an empty cask 10 is transport to the reactor site. It will be assumed that the nuclear reactor plant is equipped with a conventional crane and crane hook used at most nuclear reactors for the purpose of removing fuel assemblies from the reactor vessel. The lifting yoke 12 is assembled for lifting the cask 10 by placing the lifting plates 72, 74 on opposite sides of the crane hook. The pins 82-86 are then inserted through the holes 76-80, thereby securing the lifting plates 72, 74 in place. The side arms 68, 70 are then suspended from the ends of the lifting plates 72, 74 by engaging the slots in the upper end of the side arms and the ends of the lifting plates. The lifting yoke 12 is then ready to lift the cask 10. It will be assumed that the cask 10 is in the configuration shown in FIG. 1 with the impact limiters 16, 18 not attached to the body 14 and the trunnions 34, 36 attached to the body, although it is intended that the trunnions be removed during transport. The bolts 26 securing the lid 20 are removed, and the hook ends 88 of the side arms 68, 78 are then engaged with the grooves 60 in the trunnions, 34, 36 by lowering the lifting yoke into the appropriate position. The cask 10 is then lifted and lowered into the spend fuel pool containing the spent nuclear fuel assembly. The lifting yoke 12 is then disengaged from the trunnions 34, 36; the lid 20 is removed; the spent fuel assembly is loaded into the chamber 24; the lid 20 is replaced; and the cask is removed from the pool by lifting the cask by the trunnions with the lifting yoke. After the cask 10 has been loaded and removed from the spent fuel pool, the cask is then moved by crane to a waiting transportation vehicle, such as a flat bed railroad car 108 (shown in dotted lines in FIG. 4). The impact limiters 90 and 92 are slidably attached to the car 108 and are intended to remain with the car at all times, except during a collision. The cask 10 is then lowered onto the railroad car 108 so that the bottom impact limiter 16 nests in a pivotable receptacle (not shown). The lifting yoke 12 then continues to lower the cask 10 as the crane traverses forwardly, thereby causing the cask to tip over to a horizontal position. The cask 10 is lowered in such a manner that the tie-down plate 32 is on the bottom side of the body 14. When the cask 10 is in a horizontal position, the lifting yoke 12 is then disengaged from the trunnions 34, 36. The lifting yoke 12 is disengaged from the crane hook by removing the pins 82-86 and removing the side arms 68, 70 from engagement with the ends of the lifting plates 72, 74. The side arms 68, 70, lifting plates 72, 74 and pins 82-86 are then stowed on the railroad car 108 for transport with the cask 10. The cask 10 is secured to the railroad car 108 by inserting bolts (not shown) through a bracket (not shown) into the tie down plate 32. The bolts attaching the cask 10 to the railroad car 108 are of a size and type such that, in a collision, the bolts will shear off, thereby detaching the cask 10 and impact limiters 16, 18 from attachment to the railroad car. Before transport of the cask 10, the trunnions 34, 36 may be removed from the body 14, by removing the bolts 44. The inner element 46, the outer element 48, the cover plate 62 and the bolts 44 are then stowed on the railroad car 108 for transport with the cask. After the trunions are moved, the impact limiters are positioned at the ends of the cask 10. The impact limiters are attached to the top end 16 and bottom end 18 of the cask 10 by inserting bolts 104 and 100, respectively. When the cask 10 reaches its destination, the trunnions 34, 36 are reattached to the body 14 for removal of the cask 10 from the railroad car 108. In the event that the railroad car 108 collides with an obstacle during transport of the cask 10, the cask with the impact limiters 16, 18 attached thereto, may break away from the railroad car, depending on the severity of the collision. Any subsequent collisions of the cask 10 with obstacles are then softened by the impact limiters 16, 18 which are crushable, thereby reducing the possibility of rupture of the cask 10 and release of radioactive substances. To remove the cask 10 from the railroad car 108, the trunnions 34, 36 are reattached to the body 14 of the cask, the tie down bolts are removed from the tie down plate 32, the impact limiter 16 is removed from the top end 16 of the cask by removing the bolts 104 and sliding the top impact limiter away from the cask. The lifting yoke 12 which has been reassembled on a suitable crane hook then engages the trunnions 34, 36 and tilts the cask 10 upwardly from its horizontal position to a vertical position, whereupon it is lifted off the railroad car. It should be understood, of course, that the foregoing relates only to a preferred embodiment of the present invention and that numerous modifications or alterations may be made therein without departing from the spirit and scope of the invention as set forth in the appended claims: