Patent Number: 052727432
Section: description

DETAILED DESCRIPTION OF THE INVENTION FIGS. 1 and 2 depict an inner key member for use in insertion and removal of fuel rods in accordance with an embodiment of the present invention. The key member, generally designated by 1, comprises an elongated key body 2 having a pair of opposite side faces and having a plurality of first projections 3 and a plurality of second projections 4 formed alternately on the opposite side faces in staggered relation to one another. Each first projection 3 is of a trapezoidal shape having an inclined surface 3a directing toward the proximal end of the key body 2, and is adapted to be held in engagement with the peripheral end around an opening 5a formed in each inner strap 5. Each second projection 4 has inclined surfaces 4a and 4b facing the proximal and distal ends thereof, respectively, and is adapted to deflect a spring 5b in a direction away from a dimple 5c opposing thereto when the key member 1 is inserted through the opening 5 into the grid cells of the grid and is operated in a manner as will be described later. In conjunction with the disassembling of a nuclear fuel assembly, the method of insertion and removal of the fuel rods using the aforesaid key member will now be described. First, a nuclear fuel assembly 10 as illustrated in FIG. 8 is horizontally placed on an assembly base which may be the same one as that used during the assembling operation or may be another similar base. The nuclear fuel assembly 10 placed on the assembly base includes a pair of top and bottom nozzles 11 and 12 spaced apart from each other, and a plurality of, e.g., nine grids G1, G2, G3-G9 arranged between the top and bottom nozzles 11 and 12 in a spaced relation to each other. Each of the grids G1 to G9 includes a plurality of inner straps 5 intersecting generally perpendicular to each other to define a plurality of grid cells therein and a plurality of outer straps 6 intersecting perpendicular to each other and covering the inner straps 5 to complete outermost grid cells defined by the inner straps. Provided on the strap walls defining a respective grid cell are opposed pairs of dimple 5c and spring 5b which cooperate with each other to constrict the fuel rod 15 therein. In each of the grids G1 to G9, an opening 5a is formed at each of the intersections of the inner straps 5 for enabling the insertion of the inner key member 1, whereas openings 16 are also formed in the outer straps 6 for enabling the insertion of the key members therethrough. A plurality of control-rod guide pipes 13 are inserted through the grid cells of the grids G1-G9, and are secured at their one ends to the grid G1 through inserts or sleeves I and at the other ends to the bottom nozzle 12. In addition, a plurality of measuring instrument pipes 14 are inserted through the grid cells disposed at the central portion of the grids, and are secured at their one ends to the grid G1 through the inserts I and at the other ends to the bottom nozzle 12. Specifically, each of the control rod-guide pipes 13 and the instrumentation pipes 14 is provided with a bulged or enlarged portion, and is secured to each of the grids G2 to G9 with the bulged portion being fixed to the grid through a sleeve S1 or S2. In each of the control rod-guide pipes 13, that portion between the top nozzle 11 and a position displaced a predetermined distance from the grid G3 toward the bottom nozzle 12, as well as those upper and lower portion (left and right portions in FIG. 8) sandwiching the grid G2, are formed into larger-diameter portions 13a, whereas the remaining portions are formed into a smaller-diameter portions 13b. Furthermore, a plurality of fuel rods 15 are inserted through the grid cells of the grids and held by the grids by being urged by the springs formed on the straps of the grids G1 to G9 towards the dimples opposing thereto. The nuclear fuel assembly 10 thus constructed is secured on the assembly support in a horizontal manner, and the top nozzle 11 is removed from the control-rod guide pipes 13 and the measuring instrument pipes 14. Subsequently, a cutter 20 or a cutting device is secured on a support (not shown) which is arranged adjacent to the top nozzle 11 disposed on the aforesaid base. As depicted in FIG. 9, the cutter 20 includes an elongated outer tube 20a; a pushing rod 20b inserted through the outer tube 20a for sliding movement therealong; a spring-accommodating tube 20c threaded on the forward end of the outer tube 20a and having an end plate; a spring-retaining member 20d of a rod-like shape disposed in the spring-accommodating tube 20c for sliding movement therealong and having an enlarged portion at a side adjacent to the outer tube 20a; and a coil spring 20e disposed around the spring-retaining member 20d so as to act between the end plate of the spring-accommodating tube 20c and the enlarged portion of the spring-retaining member 20d to urge the retaining member 20d away from the end plate. A tubular guide member 20f, which has an elongated aperture 20i formed therein so as to extend longitudinally thereof, is threaded on the forward end of the spring-accommodating tube 20c. In addition, a pushing member 20g, which is provided with a radially outwardly protruding member 20h threaded thereon, is threaded on the forward end of the spring-retaining member 20d, and is accommodated in the tubular guide member 20f for sliding movement therealong with the protruding member 20d being engaged with the elongated aperture 20i. Furthermore, a cutter blade 20j is accommodated in the tubular guide member 20f for rotation about a shaft 20k which is journaled on the guide member 20f so as to extend transversely thereof. The pushing member 20g has an inclined face 201 formed at its forward portion, and is adapted to engage with the rearward end of the cutter blade 20j. In operation, the pushing rod 20b is forwarded, the inclined face 201 of the pushing member 20g is brought into engagement with the cutter blade 20j to bring the cutting edge portion of the cutter blade into engagement with the inner peripheral surface of the control rod-guide pipe 13 or the measuring instrument pipe 14, and the outer tube 20a and hence the spring-accommodating tube 20c and the guide member 20f are rotated circumferentially to turn the cutter blade along the inner peripheral surface of the control rod-guide pipe 13 or the measuring instrument pipe 14, whereby the control rod-guide pipe 13 or the measuring instrument pipe 14 is cut by the blade in its circumferential direction. In the cutting operation of the control rod-guide pipe 13 or the instrument pipe 14 by means of the cutter 20, the cutter 20 is inserted into the control rod-guide pipe 13 or the instrumentation pipe 14 from the upper end thereof (from the left end in FIG. 8), and that portion of the pipe which is located at a position slightly displaced from the opening 16 of the grid G1 toward the bottom nozzle 12 is first cut. Thereafter, the cutting is successively carried out at a respective position displaced slightly from the opening 16 of each of the grids G2 to G9 toward the top nozzle 11. In the foregoing, different kinds of the guide member 20f are prepared in advance so as to be used for pipes of different diameters. Specifically, in the cutting of the smaller diameter portions 13b of the control rod-guide pipes 13, a guide member 20f of a smaller diameter is mounted on the cutter, whereas in the cutting of the larger diameter portions 13a of the control rod-guide pipes 13 and the instrumentation pipe 14, a guide member of a larger diameter is used. Thus, after each of the control rod-guide pipes 13 or each of the measuring instrument pipes 14 is cut into a plurality of cut pipes A1 to A8 or B1 to B8, the inner peripheral surfaces of the cut pipes are examined with an endoscope to confirm that the cutting is properly carried out, following which the cutter 20 is removed from the base. Subsequently, a bulging apparatus, not shown, is secured on the base, and the cut pipes are subjected to bulging operations, in the order of from A1 to A8 B1 to B8), thereby reducing the longitudinal length of each cut pipe. As a result, the cut pipes A1 to A8 and B1 to B8 are deformed away from the openings 16 for inserting the key members. Thereafter, outer key members for deflecting the springs on the outer straps 6 and the inner key members 1 for deflecting the springs on the inner straps 5 are detachably attached to the outer straps 6 and the inner straps 5. In operation, the inner key member 1 is inserted through the opening 16 into a respective one of the openings 5a (see FIG. 3). Then, the inner key member 1 is turned 90 degrees about its longitudinal axis (see FIG. 4), and is caused to move forwardly (see FIG. 5). With this movement, the inclined surface 3a of each first protrusion 3 formed on the one side of the inner key member 1 is guided by the peripheral end of the opening 5a, and the first protrusion 3 is brought into engagement therewith, whereas the inclined surface 4a of the second protrusion 4 is brought into abutment with the spring 5b to be urged thereagainst, and finally the protruding surface of the second protrusion 4 is brought into abutment with the spring 5b to deflect the spring 5b in a direction away from the dimple 5c opposing thereto. The above operation is repeatedly carried out to insert a great number of inner key members 1 into the grids G1 to G9 (see FIGS. 6 and 7), and hence the springs 5b on the inner straps 5 can be reliably deflected without damaging the fuel rods 15. Furthermore, in order to confirm that the fuel rods 15 may be removed easily from each of the grids G1 to G9, a force to hold the fuel rod, i.e., force to draw out the fuel rod, is measured, and then the bulging apparatus is removed from the base, following which the bottom nozzle 12 is removed. Subsequently, after drawing the fuel rods 15 out of the grids G1 to G9 using a pull-in device (not shown), the inspection of the thus drawn fuel rods 15 is commenced. In the foregoing, in conjunction with the method for drawing out the fuel rods, there is disclosed a method which comprises, prior to the removal of the fuel rods from the grid cells of the grids, cutting the prescribed portions of the control-rod guide pipes and the measuring instrument pipes, and shortening the pipes by enlarging them to thereby ensure the spacings for the insertion of the key members. This method may be modified as follows. More specifically, a cutter 40 modified from the aforesaid cutter 20 is prepared. The modified cutter 40 is similar to the cutter 20 in that it includes the outer tube 20a; the pushing rod 20b inserted through the outer tube 20a for sliding movement therealong; the spring-accommodating tube 20c threaded on the forward end of the outer tube 20a; the spring retaining member 20d disposed in the spring-accommodating tube 20c for sliding movement therealong; the spring 20e acting between the spring-accommodating tube 20c and the retaining member 20d to urge the retaining member 20d away from the end plate of the spring-accommodating tube 20c; the guide member 20f detachably threaded on the spring-accommodating tube 20c; and the pushing member 20g with the protruding member 20h secured to the spring-retaining member 20d. However, a pair of cutter blades 20p and 20p, each of which has a cutting edge portion at its forward end and an inclined surface 20m at its rearward end, are secured to the guide member 20f for rotation about the common shaft 20k which is journaled on the guide member 20f. In addition, the pushing member 20g includes a pair of inclined faces 20q and 20q sloping so as to approach each other in a forward direction, and the cutter blades 20p are arranged so that the cutting edge portions as well as the inclined surfaces 20m are directed in different directions, whereby the inclined faces 20q of the pushing member 20g are adapted to be in engagement with the inclined surfaces 20m, respectively. Thus, in the modified cutter 40, when the pushing rod 20b is forwarded, the inclined faces 20q of the pushing member 20g are brought into pressing engagement with the inclined surfaces 20m of the cutter blades 20j, thereby bringing the forward cutting edge portions of both of the cutter blades 20j into engagement with the inner peripheral surface of the control rod-guide pipe 13 or the measuring instrument pipe 14. Then, the outer tube 20a, and hence the spring accommodating tube 20c and the guiding portion 20f, are caused to move backward in a longitudinal direction of the pipe to thereby form an opposed pair of slits 41 in the pipe. In the formation of slits 41 in the bulged portion 42 of each of the control rod-guide pipes 13 and the instrument pipes 14, the cutting operation is repeated twice to provide circumferentially equally distributed four slots in each pipe (see FIG. 12). Furthermore, each slit 41 is formed such that when the bulged portion 42 is pressed into a smaller diameter, the width of the slit 41 becomes smaller than the inner diameter of the sleeve S1 or S2. Thus, the slits are formed in the bulged portion of each of the control rod-guide pipes 13 and the instrument pipes 14, and then the control rod-guide pipes 13 and the instrument pipes 14 are removed from the grids by just pulling them out. Thereafter, the same procedures as mentioned above are repeated. As described above, since the key member in accordance with the present invention includes a plurality of first projections adapted to be held in engagement with the opening of the strap and a plurality of second projections adapted to be held in engagement with the spring to deflect the spring away from the dimple facing thereto, the key member can be employed to release the constrictive engagement of the fuel rods with the springs and dimples. Therefore, sufficient cell space required for the assembling and/or disassembling of the nuclear fuel assembly can be ensured without using a special device such as a spring-deflecting jig of an expander type. Furthermore, inasmuch as the aforesaid key member can be employed in both for insertion and removal of fuel rods, the insertion and removal of fuel rods, or the disassembling or assembling of the nuclear fuel assembly can be effected very efficiently without damaging the fuel rods.