Patent Number: 047388200
Section: description

DETAILED DESCRIPTION OF THE INVENTION Reference will now be made in detail to several present preferred embodiments of the invention, an example of which is illustrated in the accompanying drawings. In the drawings, like reference characters designate like or corresponding parts throughout the several views. In FIG. 1, a (typically 13.5 foot long) nuclear fuel assembly 10 is shown in vertically foreshortened form. The fuel assembly 10 is the type used in a pressurized water reactor (PWR) and basically includes a bottom (or lower) nozzle 13 for supporting the assembly on the lower core plate (not shown) in the core region of a nuclear reactor (not shown), and a number (typically 24) of longitudinally extending (typically 12 foot long) guide thimbles 14 which project upwardly from the bottom (or lower) nozzle 12. The fuel assembly 10 further includes a plurality of transverse grids 16 axially spaced along the guide thimbles 14 and an organized array of elongated fuel rods 18 transversely spaced and supported by the grids 16. Also the assembly has a top nozzle 20 attached to the upper ends of the guide thimbles 14. The lower ends of the guide thimbles 14 are attached to the adaptor plate 22 of the bottom (or lower) nozzle 12. In this region, each guide thimble 14 typically is surrounded by a grid sleeve (not shown). With such an arrangement of parts, the fuel assembly 10 forms an integral unit capable of being conventionally handled without damaging the assembly parts. As mentioned above, the fuel rods 18 in the fuel assembly 10 are held in spaced relationship with one another by the grids 16 spaced along the fuel assembly length. Typically each fuel rod 18 contains nuclear fuel pellets of uranium dioxide (not shown). A liquid moderator/coolant, such as water or water containing boron, is pumped upwardly through the guide thimbles 14 and along the fuel rods 18 of the fuel assembly 10 in order to extract heat generated therein for the production of useful work. To control the fission process, a number of control rods (not shown) are reciprocally movable in the guide thimbles 14 located at predetermined positions in the fuel assembly 10. In FIG. 1, a nuclear reactor fuel assembly bottom nozzle to guide thimble attachment system is shown for a first embodiment of the apparatus of the invention, in which a bottom-insertable, two-headed bolt 24 is used for the attachment. By "bottom-insertable" is meant insertable from the bottom of the fuel assembly. The bottom nozzle adaptor plate 22a has a bore 26. The lower end of the guid thimble 14 has an attached (e.g. welded) bottom end plug 28. The bottom end plug 28 has a threaded axial passageway 30 which is aligned with the bottom nozzle adaptor plate's bore 26. The two-headed bolt 24, seen in FIGS. 2 and 3, has a longitudinal flow hole 32 to allow passage of coolant. The shank portion 34 has a threaded section 36. The first head 38 is sized to block passage through the bore 26, while the second head 40 is sized to allow passage through the bore 26 and the passageway 30. The two-headed bolt 24 is placed in the bore 26 and threadably inserted in the passageway 30. The first head 38 is proximate the bottom nozzle adaptor plate 22a while the second head 40 is proximate the guide thimble bottom end plug 28. By that is meant the second head 40 faces in the direction of the top nozzle 20. Typically, the two-headed bolt is installed at the time of fuel assembly original manufacture. The fuel assembly skeleton typically is assembled on its side at the fuel plant. Since the fuel assembly has not been irradiated yet in a nuclear reactor, there is no need to do this assembly work under water, and there is no problem gaining access to the bottom nozzle attachment area of the fuel assembly. The first head can be any standard bolt head, but a preferred first head 38 has a face 42 that includes a polygonal-shaped recess 44. In an exemplary arrangement, the bore 26 includes a countersunk bore portion 46 which surrounds the first head 38 and which has a detent 48 into which the first head 38 is crimp-locked to prevent loosening. The second head can be any standard bolt head, but a preferred second head 40 has a plurality of longitudinally-extending, peripheral, generally flat surfaces 50. In this case the second head would extend above the bottom end plug far enough for a socket wrench (for example), acting from above, to unthread the two-headed bolt. It is noted that if the second head 40 had a wrenching feature that was a polygonal-shaped recess, then it would not have to extend above the bottom end plug to be unthreaded by an allen wrench (for example) acting from above. The two-headed bolt 24 arrangement allows for bottom insertion during manufacture to attach the bottom (or lower) nozzle 12 to the guide thimbles 14. Presently, single-headed bolts or screws are bottom inserted for this attachment. The two-headed bolt 24 arrangement allows for top unthreading to detach the bottom (or lower) nozzle 12 from the guide thimbles 14 without having to invert the fuel assembly 10. Presently, the fuel assembly must be inverted for this detachment. Such disassembly work on an irradiated fuel assembly must be done under water. The bottom nozzle of an irradiated fuel assembly may be removed as one of the steps during a fuel assembly reconstitution procedure or during a spent fuel rod consolidation procedure. Hence, in these cases, the two-headed bolt 24 arrangement allows for fuel assembly reconstitution or spent fuel rod consolidation without inverting the fuel assembly. To remove the bottom nozzle 12 from the guide thimbles 14 of the fuel assembly 10, the fuel assembly 10 is placed in a generally upright position, or at least with its top nozzle 20 higher than its bottom nozzle 12. Then, a long-handled wrench is inserted into each guide thimble 14, from the top nozzle 20 towards the bottom nozzle 12, and into engagement with the second head 40 of the two-headed bolt 24. It is noted that the wrench can enter the guide thimble as easily as can a control rod and removal of the top nozzle is not required. The wrench is used to overcome any crimp-lock and unthread the two-headed bolt 24 which will fall away. When all the two-headed bolts are thus removed, the bottom nozzle 12 will fall away. Typically, such work occurs on an upright fuel assembly suspended underwater in the spent fuel pit of the nuclear reactor, with a laterally-movable tray or bucket placed beneath the fuel assembly to collect the deattached two-headed bolts 24 and the detached bottom (or lower) nozzle 12. The top nozzle 20 is removed by methods known to those skilled in the art, such methods forming no part of this invention. Typically, the spent fuel rods 18 are pushed out the bottom of the fuel assembly skeleton and are consolidated into containers. In the case of removed defective fuel rods, the replacement fuel rods are pulled into the fuel assembly skeleton from the bottom for fuel assembly reconstitution. Pulling fuel rods into the fuel assembly skeleton from the bottom also is a preferred method of original fuel assembly manufacture and avoids the problem of top loading of fuel rods where the advancing rod impinges on a mixing vane grid damaging the vane and/or scratching the rod. In FIG. 4, a nuclear reactor fuel assembly bottom nozzle to guide thimble attachment system is shown for a second embodiment of the apparatus of the invention, in which a top-insertable bolt fastener 52 is used for the attachment. By "top-insertable" is meant insertable from the top of the fuel assembly. The bottom nozzle adaptor plate 22b has a threaded bore 54. The lower end of the guide thimble 14 has an attached (e.g. welded) bottom end plug 28. The bottom end plug 28 has an axial passageway 30 which is aligned with the bottom nozzle adaptor plate's bore 54. The bolt fastener 52, seen in FIGS. 4 and 5, has a longitudinal flow hole 56 to allow passage of coolant. The shank portion 58 has a threaded section 60. The head 62 is sized to block passage through the passageway 30. The bolt fastener 52 is placed in the passageway 30 and threadably inserted in the bore 54. The head 62 is located in the guide thimble 14 proximate the guide thimble bottom end plug 28. By that is meant the head 62 faces in the direction of the top nozzle 20. Typically, the bolt fastener is installed underwater on an upright irradiated fuel assembly at the time of fuel assembly reconstitution. However, it is possible to install the bolt fastener arrangement at the time of fuel assembly original manufacture (in place of the two-headed bolts previously discussed). The head 62 can be any standard bolt head, but a preferred head 62 has a face 64 that includes a polygonal-shaped recess 66. In an exemplary arrangement, the head has a locking cut 68 which is crimped-locked to the inside wall of the guide thimble 14 to prevent loosening. The bolt fastener 52 arrangement allows for top insertion during reconstitution to attach the bottom (or lower) nozzle 12 to the guide thimbles 14. Presently, bolts or screws are bottom inserted for this attachment. The bolt fastener 52 arrangement allows for top threading to attach the bottom (or lower) nozzle 12 to the guide thimbles 14 without having to invert the fuel assembly 10. Presently, the fuel assembly must be inverted for this attachment. Such assembly work on an irradiated fuel assembly must be done under water. The bottom (or lower) nozzle may be attached to an irradiated fuel assembly as one of the steps during a fuel assembly reconstitution procedure after the defective fuel rods have been exchanged for replacement fuel rods. Hence, in this case, the bolt fastener 52 arrangement allows for fuel assembly reconstitution without inverting the fuel assembly. To attach the bottom (or lower) nozzle 12 to the guide thimbles 14 of the fuel assembly 10, the fuel assembly 10 is placed in a generally upright position, or at least with its top nozzle 20 higher than its bottom nozzle 12. A bottom (or lower) nozzle 12 is obtained wherein the bottom nozzle adaptor plate 22b has a plurality of threaded bores 54. Then, a long-handled wrench, detachable holding the bolt fastener 52, is inserted into each guide thimble 14 from the top nozzle 20 towards the bottom (or lower) nozzle 12. It is noted that the wrench can enter the guide thimble as easily as can a control rod and this step can be performed with the top nozzle 20 attached. The wrench is used to thread the bolt fastener 52 and then is detached therefrom. When all the bolt fasteners 52 are thus threaded (and crimp-locked, as desired), the bottom (or lower) nozzle 12 will be secured. The bottom (or lower) nozzle 12 used during the reconstitution may be the previously-removed bottom nozzle of, for example, original manufacture or a replacement bottom nozzle providing the adaptor plate has threaded bores. It is noted that if the adaptor plate 22a of the two-headed bolt 24 of FIG. 2 had a threaded bore, then the area of the shank 34 of the two-headed bolt 24 surrounded by such threaded bore would itself be without threads. Similarly, where the guide thimble bottom end plug of original manufacture has a threaded axial passageway (see FIG. 2), the bolt fastener 52 of the reconstituted fuel assembly would have a shank 58 in which the area of the shank 58 surrounded by such threaded axial passageway would itself be without threads (see FIG. 4). Of course, if the bolt fastener 52 were used for original manufacture, as well as for reconstitution, then the guide thimble bottom end plug's axial passageway would not be threaded. It is noted that with the above-described invention, the attachment system allows for a second, third, or any number of reconstitutions of the fuel assembly. It will be apparent that many modifications and variations are possible in light of the above teachings. It, therefore, is to be understood that within the scope of the appended claims, the invention may be practiced other than as specifically described.