Patent Number: 052326551
Section: description

DETAILED DESCRIPTION The skeleton portion shown in FIG. 1 may belong to a skeleton having the same general structure as that of conventional fuel assemblies for pressurized water reactors, i.e., having an upper end piece 10 and a lower end piece 12 both formed with openings for passing coolant and interconnected by guide tubes 14 which carry grids (not shown). Such a skeleton structure will not be described since it is fully disclosed in numerous prior publications, e.g., EP-A-0187578, providing a description of an assembly that can be modified to implement the invention. Each of the guide tubes 14 of the type shown in FIG. 1 is connected to the lower end piece by means constituting a particular embodiment of the invention and enabling easy disassembly while nevertheless being simple in structure. The portion of these means belonging to the end piece 12 consists of a bore 18 which advantageously includes an inlet chamfer 20 to facilitate insertion of the means carried by the guide tubes 14 into the end piece. The portion of the means carried by the guide tube is constituted as a simple peg 16 whose top portion is fixed in the tube 14 and whose bottom portion is divided by slots 22 into a plurality of fingers 24 (there being four fingers separated by two slots in a cross configuration in the embodiment shown in FIGS. 1 and 2). The fingers are sufficiently thin to be resilient. The bottom portion terminates as a tapered region constituting a cone that facilitates insertion of the peg into the bore 18. Each finger 24 includes a shoulder 26 disposed at the base of the tapered region and located at a distance from a shoulder 28 between the top and bottom portions of the peg that is equal to the thickness of the end piece 12. The extent to which the shoulder 26 projects and the width of the slots 22 are selected so that the fingers, when in their relaxed state, are held captive in the lower end piece, but when the fingers are bent inwardly, the shoulders 26 can pass along and within of wall 18. The guide tubes 14 are generally made of a zirconium base alloy such as one of the alloys known under the name "Zircaloy" whose mechanical properties, particularly after irradiation, are insufficient for making peg 16. The peg is advantageously made of stainless steel or of one of the alloys known under the name "Inconel", which is difficult to weld to zirconium base alloys. For that reason, the pegs 16 are generally fixed to the guide tubes 14 by crimping. In that example shown in FIG. 1, each guide tube 14 bears against a shoulder of the top portion of the respective peg and is fixed by crimping in a groove 29 in the top portion using a technique that is well-known. To allow a throttled flow of coolant through the peg, thereby obtaining hydraulic damping in the event of an element dropping inside the guide tube 14, a small diameter hole 30 is generally formed along the axis of the top portion of the peg 16, opening out between the fingers 24. The projecting portion 45 may be designed to define a dead volume 47 suitable for receiving small debris and for preventing blockage of hole 30. The guide tubes may be fixed to the upper end piece 10 by known structural means. In particular, when it is desired to be able to disassemble and reassemble the end piece simply, e.g., to replace the elements, threaded sockets may be used that are provided with respective thin skirts which are deformable in notches of the end piece in order to prevent them from rotating (see FR-A-2465916). In the embodiment shown in FIG. 1, the connection between each guide tube 14 and the upper end piece 10 is made by crimping. To this end, the passage for receiving a guide tube in the end piece comprises in succession from top to bottom: a cylindrical portion in which a crimping groove 32 is formed; a slightly flared portion separated from the cylindrical portion by a shoulder 34 and having a crimping groove 36; and a cylindrical bottom portion. The connection is performed as follows: The guide tube is inserted into the end piece and is positioned axially relatively thereto. It is crimped by deformation into the groove 36. The danger of separation is avoided by forcibly inserting a ring 38 having a top thin skirt which is deformed into groove 32. As shown in FIG. 3, the lower end piece 12 is installed on the guide tubes 14 advantageously held in their set positions by crossed combs, merely by displacing the end piece 12 in the direction indicated by arrow f.sub.0. The pressure of the bevel 20 on the tapered end of the peg 16 causes the fingers thereof to bend. When the end piece 12 comes into abutment against the shoulder 28, the fingers 28 have just passed through the end piece and spread apart. The shoulders 26 snap behind the end piece. The embodiment shown in FIGS. 4 and 5 differs from that described above by including means that are easily installed and removed for preventing the fingers from moving towards one another when they are in place. These means, shown by way of example, are constituted by a ring 42 extending over an angle of 270.degree. and terminated by rectilinear portions that are inserted in the slots between the fingers 24. The ring is retained in a groove in the peg and prevents the fingers from moving towards one another. Assembly is performed as in the embodiment of FIGS. 1 to 3. The ring is installed in the groove situated beneath the end piece 12 after fingers have snapped into place. The lower end piece can be disassembled very easily. Optionally, after removing the rings 42, all of the pegs are pushed back simultaneously using a single tool 44 provided with studs 46 having respective conical bearing surfaces. As shown in FIG. 6, moving the tool in the direction of arrow f.sub.1 successively causes the fingers 24 to move towards one another and then the guide tubes to move upwardly. It will also be possible to lower the pegs of the tool 44 and then to pull the end piece 12 downwardly. The tool may also be used during assembly to avoid excessive friction between the fingers and the end piece. In a third embodiment, shown in FIG. 7, the radial thickness of fingers 24 decreases towards their ends, thereby optimizing the stresses in the fingers 24 and their stiffness. This result is easily obtained by cutting the fingers out from a blank that has two or more diameters in succession. In the embodiment of FIG. 7, the top portion of the peg includes a second circumferential groove 48. This groove may be used to make a second crimp on the guide tube 14. However, by providing the groove in a reduced-diameter region of the top portion, it also makes it possible to crimp a tubular cartridge 50 which is considerably shorter than the guide tube. The cartridge, which is generally a few tenths of millimeter thick, has the function of throttling the upward leakage path in the event that an element drops down inside the guide tube, and it therefore acts as an hydraulic damper. The cartridge 50 is mounted as a sliding fit inside the guide tube and is capable of bearing on a shoulder of the top portion and of being crimped in the groove 48 before the guide tube is put into place and crimped. Whichever embodiment is adopted, the connection between the guide tubes 14 and the bottom end piece 12 is achieved by means that are simple, comprising a single piece in addition to the guide tubes and the end piece. Manufacturing and inspection costs are small. Assembly time in the factory is short, as is the time required for any subsequent disassembly and reassembly operations.