Patent Number: 052689484
Section: description

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Looking now in greater detail at the accompanying drawings, FIG. 1 is a perspective view illustrating the upper end of a typical assembly for a nuclear fuel bundle of the general type that is described in greater detail in the aforementioned U.S. Pat. No. 4,064,004. The details of the fuel bundle itself are not important to the present invention, except to note that a typical fuel bundle includes a plurality of vertically extending control rod guide tubes 10, the lower ends of which are secured to a lower support plate or tie plate (not shown) and the upper ends of which are received within an upper end fitting or upper support plate 12. As explained above, it is necessary from time to time to remove the fuel rods (not shown) which normally extend vertically at a position beneath the upper support plate 12, and these fuel rods are removed by first disconnecting, and then removing, the upper support plate 12 from its mounting on the upper ends of the guide tubes 10. The present invention relates to a locking assembly, which is generally indicated by the reference numeral 14 in FIG. 1, that normally locks the upper support plate 12 in position on the guide tubes 10, but which can be easily manipulated to unlock or disconnect the upper support plate 12 from the guide tubes 10 for removal therefrom. One embodiment of the locking assembly 14 of the present invention is illustrated in FIGS. 2-4 and includes a collar 16 that is fixed to the upper end of each guide tube 10, the collar including a radially extending shoulder 18 that normally is received within a recess at the bottom surface of the support plate 12 as best seen in FIGS. 3 and 4, whereby the support plate 12 is supported on the upper ends of the shoulders 18 of each collar 16 in the fuel bundle. The collar 16 also includes a sleeve 20 that extends axially up through a cylindrical opening 22 in the support plate 12, the opening 22 also being provided with a generally rectangular slot 24 extending radially outwardly in opposite directions from the opening 22. The upper end of the sleeve 20 is provided with two oppositely extending projections 26 which correspond generally in shape to the slots 24 in the support plate 12. A generally annularly shaped locking member 28 is rotatably mounted on the sleeve 20, and is provided with depending feet 30 which are flared outwardly at the lower ends thereof for engaging an interior annular surface of the support plate opening 22 (see FIGS. 3 and 4), whereby the locking member 28 is freely rotatable within the opening 22 but is restrained from any axial movement relative to the support plate 12. The locking member 28 is provided with a transversely extending slot 32, the outer ends of which correspond generally in shape to the support plate slots 24, and the upper surface of the locking member 28 is provided with two apertures 34 for receiving the prongs 36 of a operating tool 38 for a purpose to be described in greater detail presently. The annular body portion of the locking member 28 presents an exterior annular surface 40 that is formed with two pairs of oppositely disposed detents 42 and 42' which are preferably arranged in circumferentially spaced relationship to one another, as best seen in FIG. 2. A locking cup 44 is provided which consists of a relatively thin annular wall portion 46 formed of a suitable metal, and being provided with a pair of oppositely disposed spring biased ears 48. The locking cup 44 is also provided with a generally flat lower wall portion 50 having an opening therein for receiving the sleeve 20, and the locking cup 44 is provided with oppositely disposed depending tabs 49, only one of which is visible in FIG. 2, which are received within recesses 51 (see FIG. 2) in the support plate opening 22 to anchor the locking cup 44 against rotational movement. As best seen in FIGS. 3 and 4, the rotatable locking member 28 is received within the confines of the annular wall 46 of the locking cup 44, with the exterior annular surface 40 of the locking member 28 closely adjacent the interior surface of the locking cup annular wall 46, and with the bottom wall 50 of the locking cup 44 contained between the body portion of the locking member 28 and the upper surface of the support plate 12. Since, as described above, the locking member 28 is retained on the support plate 12 by the depending feet 30, the locking cup 44 is likewise maintained as an integral part of the operating unit by virtue of the bottom wall 50 being positioned between the locking member 28 and the support plate 12. In operation, the collar 16 is welded or otherwise fixed to the upper end of the guide tubes 10 and is disposed with the radially extending projections 26 aligned with the slots 24 in the support plate 12, and the rotatable locking member 28 is normally at its locking position illustrated in FIG. 3, at which position the locking member slot 32 is out of alignment with the projections 26 and the support plate slots 24, and the body portion of the locking member 28 is positioned between the projections 26 and the slots 24 to lock the support plate 12 in place on the guide tubes 10. At this locking position, the spring biased ears 48 in the locking cup 44 are deflected inwardly and positively engage one pair of detents 42 to resiliently maintain the locking member 28 against rotation. When it is desired to remove the support plate 12 from the guide tubes 10 for purposes described above, the tool 38 is manipulated to insert the prongs 36 thereof in the apertures 34 of the locking member 28, and the tool 38 is then rotated to impose a predetermined torsional force on the locking member 28 which results in the spring biased ears 48 being deflected outwardly by the camming action of the moving detents 42, whereby the locking member 28 is easily rotatable about the sleeve 20 until the second pair of detents 42' are positioned adjacent the spring biased ears 48, which then deflect inwardly to engage the detents 42' and resiliently maintain the rotatable locking member 28 at its unlocked or release position with the slot 32 therein aligned with both the projections 26 and the support plate slots 24. It will be apparent that this procedure for rotating the locking member 28 is quick and simple, and when all of the locking members 28 for each of the locking assemblies 14 associated with the support plate 12 have been rotated to their unlocked positions, the support plate 12 can be easily removed from the upper ends of the guide tubes 10 by lifting it upwardly so that the projections 26 can pass through the openly aligned slots 24 and 32. It will also be apparent that after the support plate 12 has been removed from the guide tubes 10, the locking assembly 14 remains integrally fixed to the support plate 12 and guide tubes 10 so that there are no loose parts which must be kept track of, and the rotatable locking member 28 is resiliently and positively maintained at its unlocked position by virtue of the spring biased ears 48 engaging the detents 42', so that when the support plate 12 is again to be positioned on the guide tubes 10, the locking member 28 of each of the locking assemblies 14 will be properly positioned to permit passage of the projections 26 through the aligned slots 24 and 32, all without any manipulation or adjustment of the various locking assemblies 14. Moreover, once the support plate 12 is properly positioned on the guide tubes 10, it is again a relatively simple matter to manipulate the tool 38 so that the prongs 36 engage the apertures 34, whereupon the locking member can be rotated back to its locked position with the spring biased ears again engaging the detents 42. A second embodiment of the present invention is illustrated in FIGS. 5-8, and it consists of a locking assembly 52 that includes a collar 54 having a radially extending shoulder 56 that supports the support plate 12 in the same manner as that described above, and a cylindrical sleeve portion 58 that is welded or otherwise secured at the upper end of the guide tube 10, the sleeve portion extending up through the opening 22 in the support plate 12 so as to be coextensive therewith. A rotatable locking member 60 includes an annular wall portion 62 formed of suitable metal, and has a pair of oppositely disposed spring biased ears 64 that are deflected inwardly from the interior surface of the annular wall portion 62. A pair of projections 66 extend outwardly from the annular wall portion, and they have a shape corresponding generally to that of the support plate slots 24. The rotatable locking member 60 also includes a flat bottom surface 68 that is slidably mounted between the top surface of the sleeve 58 and an end portion 70 that is welded or otherwise secured at the upper end of the guide tube 10 whereby the rotatable locking member 60 is axially contained between the sleeve 58 and the fixed end portion 70, while still being freely rotatable about the guide tube 10. The end portion 70 is provided with an outwardly extending shoulder 72, and a depending annular portion 74 that extends within the confines of the annular wall 62, the exterior surface of the annular portion 74 being formed with two pairs of opposed detents 76,76', only one detent in each pair being visible in FIG. 5. In operation, the rotatable locking member 60 is normally positioned as shown in FIG. 6 with the projections 66 thereof engaging the upper surface of the support plate 12 and maintaining it in a locked position between such projections and the shoulder 56. At this locked position, the spring biased ears 64 resiliently engage one pair of detents 76 to resiliently maintain the rotatable locking portion 60 at its locked position. When it is desired to remove the support plate 12 from the guide tubes 10, a hollow cylindrical tool 78 having notches 80 formed in the bottom edge thereof is passed over the end portion 70 and the rotatable locking portion 60 until the notches 80 receive therein the projections 66, whereupon the tool 78 is rotated to impose a predetermined torsional force on the rotatable locking member 60 which, by virtue of the camming action of the detents 76, causes the spring biased ears 64 to be deflected outwardly and permit rotation of the rotatable locking portion 60 until the spring biased ears 64 reach the other pair of detents 76' and deflect inwardly to resiliently maintain the rotatable locking portion 60 at its unlocked position as shown in FIG. 7. At this unlocked position, the projections 66 are aligned with the support plate slots 24, and when all of the locking assemblies 52 in the fuel bundle are moved to, and maintained at, their unlocked positions, the support plate 12 can be lifted off of the guide tubes 10 with the slots 24 passing over the aligned projections 66. Again, as was the case with the first embodiment, it will be noted that after the support plate has been removed, all of the locking assemblies 52 remain integrally fixed at the end of the guide tubes 10 without any loose parts, and the rotatable locking members 60 of each locking assembly 52 are maintained in their unlocked position by the spring biased ears 64 so that the support plate can be repositioned on the guide tubes 10 without any movement or adjustment of the locking assembly components. If for some unforeseen reason, use of the second embodiment should result in the spring biased ears 64 losing some of their resiliency through constant expansion and deflection, a further feature of the present invention allows for additional spring biased ears 64 to be crimped into the annular wall 62 using a crimping tool 82 as illustrated in FIG. 8. Even though the shoulder 72 of the fixed end portion 70 extends over the annular wall 62, this shoulder 72 is formed with opposed apertures 84 located directly above one of the pairs of detents 76 and aligned therewith. Accordingly, since the annular wall 62 has a circular configuration as illustrated in FIG. 8, the depending prongs 86 of the crimping tool 82 can be moved downwardly through the apertures 84 in the shoulder 72 and through the aligned detents 76 until the prongs 86 engage and crimp the annular wall 62 to form new spring biased ears 64 therein, all without any necessity of disassembling the locking assembly 52 for this purpose. A third embodiment of the present invention is illustrated in FIGS. 9-11 which illustrate a locking assembly 88 that includes a collar 89 that is welded or otherwise secured at the upper end of a guide tube 10, the collar 89 including a shoulder 90 for supporting the support plate 12, a sleeve portion 92 extending upwardly therefrom, and a plurality of curved fingers 94 that project upwardly from the sleeve 92 with spacings 96 between each of the fingers 94. A relatively thin annular snap ring 98, preferably made from a suitable resilient metal, is formed with a pair of opposed spring biased ears 100 and a spacing 102 between its two ends, and the snap ring 98 is positioned over the upstanding fingers 94 to encircle such fingers with the ears 100 being positioned in two of the opposed spacings 96 between the fingers 94. A movable locking member 104 is provided with an annular sleeve portion 106 that is positioned over, and receives therein, the snap ring 98, and the interior annular surface of the sleeve portion is provided with an inwardly directed protrusion 108 that is received within the spacing 102 of the snap ring 98. The rotatable locking member 104 also includes a pair of oppositely disposed projections 110 having a shape corresponding generally to the support plate openings 24, and the locking member 104 is held in place by a fixed end portion 112 that is welded or otherwise secured at the upper end of the guide tube 10 with the rotatable locking member 104 being sandwiched between the fixed end portion 112 and the sleeve 92 so that it is free to rotate, but is held against axial movement, or separation from the other components. In operation, the rotatable locking member 104 is positioned at its locked position as shown in FIG. 10 with the projections 110 extending over the upper surface of the support plate 12 to lock it in place on the guide tube 10. At this position, the locking member 104 is maintained at its locked position by the spring biased ears 100 resiliently engaging two of the opposed spacings 96 between the fingers 94, and with the snap ring 98 being movable with the rotatable locking member 104 by virtue of the protrusion 108 extending into the snap ring spacing 102. When it is desired to remove the support plate 12 from the guide tube 10, a tool 78 identical to that described above is positioned over the fixed end piece 112 until the notches 80 receive therein the projections 110, whereupon the tool 78 is rotated to cause the spring biased ears 100 to deflect outwardly and permit rotational movement of the locking member 104 until the spring biased ears 100 resiliently engage the other two opposed spacings 96 between the fingers 94, and the locking member 104 is then positioned at its unlocked position as shown in FIG. 11. At its unlocked position, the projections 110 are openly aligned with the support plate slots 24 and the support plate can then be moved upwardly with the projections 110 passing through the slots 24. As with the other two embodiments, the rotatable locking member 104 is resiliently maintained at its unlocked position by the spring biased ears 100 so no adjustment is necessary when the support plate is repositioned on the guide tubes 10, and each locking assembly 88 is integrally fixed on the end of the guide tubes 10 with no loose parts. It will therefore be readily understood by those persons skilled in the art that the present invention is susceptible of a broad utility and application. Many embodiments and adaptations of the present invention other than those herein described, as well as many variations, modifications and equivalent arrangements will be apparent from or reasonably suggested by the present invention and the foregoing description thereof, without departing from the substance or scope of the present invention. Accordingly, while the present invention has been described herein in detail in relation to its preferred embodiment, it is to be understood that this disclosure is only illustrative and exemplary of the present invention and is made merely for purposes of providing a full and enabling disclosure of the invention. The foregoing disclosure is not intended or to be construed to limit the present invention or otherwise to exclude any such other embodiments, adaptations, variations, modifications and equivalent arrangements, the present invention being limited only by the claims appended hereto and the equivalents thereof.