CZ174592A3 - Dismountable nuclear fuel element in a jacket - Google Patents

Description

Technical field

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The invention relates to nuclear fuel cells for light water cooled and attenuated reactors. Such a cell comprises two extensions connected by a shell comprising a bundle of fuel rods held in the eyes of a regular triangular grid by means of grids distributed along the shell and by two perforated plates each connected to the extension, the extensions and the shell having the same outer hexagonal cross section.

BACKGROUND OF THE INVENTION

To date, fuel cells are known whose grilles and whose lower perforated plate which supports the rods are attached to an auxiliary central tube connected to the upper perforated plate. The stainless steel attachments are firmly attached to the zirconium-based alloy housing, non-detachable, by fitting and closing. The top perforated plate is fixed to the housing by detachable fit.

This known article brings numerous disadvantages.

In particular, it is impossible to pick up the bars without completely removing the entire link. Alternatively, it is desirable that the rods can be lifted from the cell either individually to be displaced from the cell of the leaking rod, or in total for reprocessing the radiated fuel.

In particular, it is an object of the present invention to provide a cell which allows the rods to be picked up and replaced and possibly reused after the leaked rods are replaced.

SUMMARY OF THE INVENTION

This object is achieved by the nuclear fuel cell according to the invention, which is characterized in that the top piece is provided with removable connecting means for connection with the top perforated plate and that the fuel rod plugs are also attached to the top perforated plate by removable means the top perforated plate through which the plugs pass.

In particular, the top attachment may be rigidly attached to the adapter plate provided with apertures for the passage of water, and then it is the plate which is detachably attached to the perforated plate.

In a preferred embodiment, the removable fasteners of each plug comprise a suspension cotter pin passing through the plug. The length of the split pin is greater than the diameter of the rod and can be closed between the top perforated plate and the adapter plate. The cotter pins can be inserted into the grooves arranged in the upper surface of the perforated plate and can be closed there by the adapter plate.

When the fuel cell comprises rods with absorbent material replacing the fuel rods in the eyes regularly spaced in the net, the adapter plate may be secured to the top perforated plate by a bolt having a support stop against the adapter plate and a threaded rod to be screwed into the threaded hole cut in the top perforated plate connected to the rod containing the absorbent material. A spring may be inserted between the screw and the end of the absorbent bar plug to hold the bar against the bottom plate.

The bars can be designed either to ensure accurate hold of the bars in the mesh eyes or simply to reduce the lateral oscillation of the bars. In the first case, grilles must be provided with means in which the bars can slide with little friction. In a portion of the lower cell flow (i.e., in the upper portion when the cell is flowing through the descending cooling water stream, as is the case), the grilles may be equipped with water mixing wings.

Lattices can be of several different types.

If the lattice is to ensure accurate holding of the rods, it may have a monoblock construction and may in particular be of the type described and claimed in French Patent Application No. 90 04035.

It is also possible to use bars formed by joining and welding the plates, each having a 120 ° bend in the middle, as described in French Patent Application No. 90 05820. The plates may be provided with protrusions located at one or two different levels and oriented they may be either longitudinal or transverse in such a way as to provide four or eight support points for each rod. This arrangement makes it possible to achieve a mechanical resistance that is the same according to each orientation.

It is also possible to form a grid of rectangular plates assembled in two directions, gripping each other at 60 ° with orientations that vary from one grating to the other.

The plates may further comprise precision holding protrusions or. fixing tabs for mounting on the middle pipe. While another solution consists of attaching grilles to the shell by means of their belts.

In a further exemplary embodiment of the invention, the removable plug fasteners are formed by means of resiliently clamping the plugs comprising springs belonging to the perforated plate.

The invention will be better understood from the description of exemplary embodiments of the invention and from the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary embodiment of a fuel cell according to the invention in an extended position with a portion of the housing cut off. Giant. 2 is a detailed cross-sectional view of an axial plane of the top of the cell. Giant. 3 is a perspective detail view of a suspension of three fuel rods on a perforated plate that is above the member of FIG. Fig. 4 is a top view of the cell of Figs. 1 and 2, showing only a few fuel rods. Fig. 5, similar to Fig. 4, shows a variant embodiment. Fig. 6 shows schematically a set of lattice plates usable for the embodiment of the cell shown in Figs. 1 and 2. 7 is a sectional view of an axial plane of the cell that represents a variation of the embodiment of FIG. and shows one fuel rod. FIG. 8, similar to FIG. 7, shows yet another possible variation of the embodiment. Fig. 9 is a detailed, large-scale view showing the connector between the housing and the upper extension of the cell of Fig. 8 in cross-section along lines IX-IX of Fig. 10. Fig. 10 is a perspective view of the coupling shown in Fig. 9. FIG. 11 is a top view of a portion of the top perforated plate of the member of FIG.

DETAILED DESCRIPTION OF THE INVENTION

The fuel cell 10 schematically shown in FIG.

3 to 3 comprises upper extensions 12 and lower extensions 14, connected by a sheath 16 of hexagonal cross-section. The extensions will generally be of stainless steel, while the sheath will be of low neutron absorption alloy, typically zirconium alloy, of small thickness, usually around millimeters.

The lower attachment 14 is fixed to the housing 16, for example by embedding and engaging, by locally sinking the housing 16 into a cylindrical recess formed in the lower attachment 14. It comprises a cylindrical base designed to be embedded in the core support plate.

The rods 18 containing the fuel material are held in the meshes of a triangular regular grid by means of two perforated plates 20 and 22 and by means of bars 24 regularly spaced along the bundle of rods 18.

The perforated bottom plate 20 is perforated in one part by holes for inserting the lower plugs into the rod and extending them with a reduced diameter, and in another part by holes for the passage of water arranged between the plug receiving holes.

The bottom perforated plate 20, for example of stainless steel, is slidably mounted in the housing 16 and rests on the bottom extension 14. It may be fixed to the housing 16 by fitting and / or to the lower extension 14 by welding.

2 and 3, the upper perforated plate 22 is fixed by mechanical means to the housing 16. For example, it may be mounted on a sheath forming a shoulder which is pressed against the end edge of the sheath and welded to this end along the circumference.

The top perforated plate 22 is intended to hold the fuel rods 10 and to allow them to be lifted upwardly. Therefore, the top plate is provided with openings 19 distributed along the same mesh as the bars and having a sufficient diameter to allow them to pass generally with low friction. The top plug 25 of each rod 18 has a smaller diameter extension 26 that extends through the top perforated plate 22 while leaving a free annular space sufficient to allow passage.

water, and forming a refrigerant absorber, without causing excessive loss of filler, as indicated by arrows f _0th In practice, the diameter of the extension 26 will generally be about half the normal diameter of the rod.

Each extension 26 extends over the top surface of the perforated top plate 22 and extends the suspension cotter pin 28 therethrough. The split pins 28 are inserted into grooves or notches 30 which are parallel to one another, arranged in the upper surface of the perforated plate 22, with a depth approximately equal to the diameter of the split pins g8. These cotters can also be threaded with great friction into the plugs and have a length such that the cotters arranged in the same groove are pressed against each other, as shown in Figures 2 and 3, keeping the bars in a centered position.

The top extension 12 is provided with spring protrusions 29 held by the top plate. It is connected by the detachable connection means to the top perforated plate 22. In the embodiment shown in Figures 1 to 3, the detachable connection means comprise an adapter plate 32, for example a steel plate. firmly. attached to the top extension 12, for example by welding. The lower surface of the adapter plate 32 is pressed against the top perforated plate 22. The adapter plate 32 is provided with apertures 33 that preferably have the same diameter as the apertures 19 in the top perforated plate 22 connected thereto. The adapter plate 32 allows the pins 28 to be closed in their grooves.

The adapter plate 32 is attached to the top perforated plate 22 by removable means (not shown), which may be of various designs.

The fuel cell of the exemplary embodiment shown in FIG. 2 comprises absorbent rods 34 occupying sites in the network for periodically spacing the rods. These absorbent rods do not require coolant passage into the top perforated plate 22. The hole formed in the top perforated plate 22 may thus be threaded for a screw 36 forming a abutment surface 38 against the bottom of the cavity formed in the adapter plate 32. The top of the screw 36 may be formed. a thin skin and deformable to prevent it from rotating in the grooves of the adapter plate 32. The absorbent bars are, for example, six and located at the top of the hexagon. They contain, for example, zirconium oxide and consumer poison.

The screw 36 may have a blind bore to guide the extended portions of the plugs of the absorbent bars 34. The spring 40 may be received internally between the blind bore bottom and the extension. Optional dilatation of the absorbent rod 34 will cause elongation towards the top of the rod and compress the spring 40, while dilatation of the fuel rods 18 will elongate them downwards. To allow for this expansion, the extension of the lower plugs of the fuel rods 18 is inserted into the lower perforated plate 20.

Generally, the top extension 12 will be convergent

P (convergent) locally lowering the lower diameter. Abt, the sorbent rods 34 must be positioned such that the corresponding screws 36 are accessible. For this to be the case, the absorbent bars are positioned at a distance of the sheath as seen in Figure 4, or are used to position a particular semicircular path 41 in the inner partition of the extension, as shown in Figure 5.

The intermediate grids may have different designs. For example, it is possible to use a grid of the kind shown in FIG. 6, which consists of joining and welding the plates in the form of chips.

It can be seen that this lattice, which is shown in the exploded state in Fig. 6, comprises a strip and platelets forming cells to receive each rod. The strip may be formed by a strip of zirconium alloy sheet folded in a hexagonal shape, or may be formed by pieces of strip each having the same length as the side of the strip. These pieces are joined to each other by welding, for example an electron beam or a laser beam. In order to reduce the number of component types, it is still preferable to form a strip of three plates 42 having the same shape as the inner plates to which the inner plates are. welded or attached.

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The inner plates 44, 46 and 48 belong to three sets intersecting each other at an angle of 120 °. All of these plates are located between two opposite faces of the belt and form an angle of 120 ° in the center thereof. In the case of said embodiment, they form a single layer and are provided with grooves of a length equal to half the width of the plates. However, it is also possible to place the plates in several layers joined by the strips. Finally, the grooves may be oblique rather than parallel in the edge of the strips to facilitate the welding of the plates between them.

Protrusions 42 may be provided in the plates 42 located at one or two different levels to secure four or eight support points for each rod. These protrusions may in particular be formed by fragments in the form of cut and deformed strips, longitudinally or transversely oriented. At least some lattices located in a portion of the lower flow of the cell may be provided with wings for mixing coolant fluids as it flows through the cell.

Eight or nine grilles are usually sufficient if the bars containing the fissile material have a height of the order of 2.40 ra.

7 wherein the parts corresponding to those shown in FIGS. 1 to 6 are designated with the same reference numeral, differ in particular in that they comprise a skeleton of zirconium-based alloy construction tubes which can be replaced absorbent bars of the first embodiment, attached to the grilles and extensions. Thus, the housing no longer fulfills the function of providing mechanical strength.

The structural tubes 50 in the number of, for example, six pieces are fixed in a detachable manner to the adapter plate 32 by, for example, a bolt 36 of a comparable design to that of the bolt 36 shown in FIG. They are attached to the bottom perforated plate 20 by means, which may also be removable screws 54.

The top perforated plate 22 is attached to the tubes 50 of the structure. For example, it may comprise feet 56 intended to be welded to the tubes. It carries fuel rods 18, provided, for example, with a plug 57 having an extension limited by a support surface on the plate 22. It is precisely the adapter plate 32 that prevents the rods from being lifted during cooling.

The grilles 24 are attached to the structural tubes 50. They may be stripped and carry feet 58 intended to be welded to the structural tubes 50. These grilles may still be provided with protrusions for laterally holding the fuel rods or, conversely, simply limit their stroke.

Structural tubes 50 may consist of rods containing neutron absorbing material (not shown). These absorbent bars can be held against the hollow fixation screws 54 by a spring supported on the hollow screws 36. A radial clearance of the order of 0.5 mm between the rod and the tube is sufficient to provide a sufficient amount of coolant flow.

The cell may still comprise an auxiliary central tube attached to the grids and to the perforated plate 22 in the same manner as the structural tubes 50 are attached.

Such an article has the advantage that it is easily dismountable from the point of view of reprocessing due to the fact that the housing 16 is attached neither to the fuel rods nor to the extensions, but is simply mounted on the extensions as shown in Fig. 7.

Another embodiment of the cell of the invention shown in FIGS. 8 and 11 comprises a demountable connection between the housing 16 and the upper extension 12. The adapter plate 22 is attached to the housing 16, for example by welding. The fuel rods 18, one of which is drawn, may have the same structure as the rods of Figure 2, but the extension 26 of their upper plugs is connected to a cross beam 62 having a support and centering surface on the perforated plate 22.

The retaining plate 32a is attached in a detachable manner to the top perforated plate 22, for example by a screw 64. Like the adapter plate 32 of FIG. 7, it retains the rods 18 by pressing the crossbars 62 against the top perforated plate 22. The cell may also include absorbent rods constructed in the same manner as the fuel rods. The grilles may be attached to an intermediate central tube, not shown here.

The detachable connection means between the upper extension 12 and the housing 16 may be of the type shown in Figures 9 and 10. The extension comprises an annular abutment surface at the end edge of the housing 16.

The two recesses 66 in the extension 12 serve to insert the retention pins 68 and reset them by the tightening screw 70 from the dot pattern to the solid line position in Figure 9. In this last position, the pins rest on the crossbar of the window 72 cut in the housing. Two holes 74 and 76 at an angle

And, formed in the extension 12, a screw 70 is guided, the head of which rests on the extension.

Note that the pin, when in the down position, releases the housing and allows it to detach from the extension.

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Claims (9)

1. A nuclear fuel cell comprising two extensions (12, 14) connected by a housing (16) comprising a bundle of fuel rods (18) held in the eyes of a regular tracer network by grids distributed along the housing and two perforated plates (20, 22). ), each of which is connected to the nozzle, the nozzles and the sheath having the same external hexagonal cross-section characterized in that the upper nozzle (12) is provided with removable connecting means to the top perforated plate (22) and in that the fuel rod plugs are also fastened to the top perforated plate (22) by removable means to remove the rods (18) of the openings of the top perforated plate through which the plugs pass. Nuclear fuel cell according to claim 1, characterized in that the upper extension (12) is fixedly fixed to the adapter plate (32) fixed to the perforated plate by removable connecting means (36). The nuclear fuel cell of claim 2, wherein the removable fasteners of each fuel rod comprise a transverse cotter pin (28) that extends through the rod stopper, its length being greater than the diameter of the rod and lockable between the top perforated plate (22). ) and an adapter plate (32). Nuclear fuel cell according to claim 3, characterized in that the cotter pins (28) are received in grooves (30) arranged in the upper surface of the perforated plate (22) and the kou (32). 5. Nuclear fuel article according to claim 4, v y indicating is by length for- the train (28) is such that the cotters (28) mounted in the same groove are supported against each other. The nuclear fuel cell of claim 5, wherein the plugs (25) have a smaller cross-sectional extension (26) extending through the apertures of the top perforated plate (22), wherein the cotter pins (28) extend through the extensions that leave annular passages for circulation. coolant between it and the partition wall. Nuclear fuel cell according to any one of claims 2 to 6, characterized in that the adapter plate (32) is attached to the top perforated plate (22) by a screw (36) having a support stop against the adapter plate (32) and a rod, provided with a thread intended to be screwed into a threaded hole in the top perforated plate (22) connected to the rod (34) containing the absorbent material and to retain the rod (34). .- The nuclear fuel cell of claim 2, wherein the removable connecting means comprises bolts (36) connecting the adapter plate (32) to a support structure including an upper perforated plate (22), grilles, and structural tubes (50). The nuclear fuel cell of claim 8, wherein the removable fasteners of each fuel rod comprise a functional head (57) that has a rigid support extension on the top perforated plate (22) retained by the adapter plate (32). 10. The nuclear fuel cell of claim 1. wherein the casing (16) is permanently attached to the top perforated plate (22) and in that the releasable fasteners (60-72) are located between the upper extension (12) and the casing (16).