Patent Number: 051749505
Section: description

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS As indicated above, a grid according to the invention can be used in a fuel assembly having a hexagonal cross-section with two sub-structures, such as the assembly 10 shown in FIG. 1, in which only some fuel rods 14 have been shown. The support structure has two end pieces, an upper end piece 16 and a lower end piece 18, and guide tubes 20 and 24 replacing the rods at certain nodal points of the network of rods. The first sub-structure comprises the guide tubes 20, upper end piece 16 and a plate 23 movable within the lower end piece 18. The guide tubes pass through the bottom wall 22 of the end piece 18, in which they are vertically slidable. The first sub-structure further comprises the uppermost grid 12, which is intended to carry the fuel rods 14, and for this purpose is provided with means for clamping the fuel rods, i.e., some at least of the intermediate grids 13. The lowermost grid may also be fixed to the guide tubes 20. The connections of the guide tubes 20 of the first sub-structure, of grid 12 and of the bottom wall of the upper end piece 16 are shown by crosses in FIG. 1. The second sub-structure comprises the lower end piece 18, the other guide tubes 24 and a plate 28 movable vertically in the frame portion of the upper end piece 16, above the bottom wall 22 of piece 16. The guide tubes 24 pass through the bottom wall and are slidable therein. The second sub-structure may also comprise a central instrumentation tube 29. Springs 30, four in number for example, are placed between the plate 23 and a flange 32 formed at the lower part of the frame of the lower end piece 18. The springs exert a force on plate 23 tending to hold it applied against the bottom wall of plate 18. Rods 34 fixed to the lower end piece 18 guide the springs 30 and the plate 23. The fuel assemblies have been loaded in the reactor, the lower end piece 18 of each assembly rests on the core support plate 36. Springs 30 support the first sub-structure and hold plate 23 in position. When the upper core plate 38 is lowered, the pressure which it exerts on the upper end piece 16 is added to the weight of the first sub-structure. When the reactor is operating, the coolant exerts on the first sub-structure a force which tends to apply the upper end piece 16 against the upper core plate 38. The force which the coolant exerts on the second sub-structure, much smaller than that which it exerts on the first sub-structure, is absorbed by springs 30 without raising the lower end piece 18. The intermediate grids 13, for holding the rods in position at the nodal points of a triangular network, may be devoid of springs for supporting the rods and may have the construction shown in FIGS. 2 and 3. Each grid is formed by assembling together a plurality of sets of plates which are all made from an alloy having a low neutron absorption, generally a zirconium-base alloy. The grid 13 may be regarded as comprising a belt 40 and plates defining cells for receiving respective fuel rods 14, only one of which is shown schematically in FIG. 2. The belt may be formed b a metal strip of zirconium-base alloy which is bent into a hexagonal shape, or by strip sections each having a length equal to that of one side of the belt, the sections being joined together by welding, for example by electron beam or laser beam welding. To reduce the number of types of components, it is however more advantageous to form the belt of three plates 42 having the same shape as the internal plates 44, to which the internal plates are welded or brazed. The internal plates 44, 46 and 48 belong to three sets crossed at 120.degree. with respect to each other. All plates extend between two opposite faces of the belt and are angled at 120.degree. in the middle. They will in general form a single bed, obtained interlocking plates 44, 46 and 48. To this end, slits 49 whose length is equal to half the width of the plates are formed in the latter. One at least of the sets of plates 44, 46 and 48 has slits directed in opposite directions on opposed sides of the medium bend of the plate. As illustrated, plates 44 are inserted on plates 46 and 48 already assembled. Once interlocked, the plates are secured permanently together, for example by welding points at the intersections, using well-known techniques. For correct positioning of plates 44, 46 and 48 of the belt, the plates 42 which form the latter may comprise openings 51 receiving lugs (not shown) projecting from the end edges of plates 44, 46 and 48. As mentioned above, the plates may be provided with means for bearing rigidly or resiliently on the rods. Such bearing means may be embossments formed by press-shaping the plates, e.g., tongues press-cut and shaped or may be springs, which makes it possible to form a grid having plates of zirconium-base alloy and springs of "Inconel", having greater mechanical strength but on the other hand higher neutron absorption. The plates (or at least the internal plates 44, 46 and 48) may have a shape corrugated at the distribution spacing of the fuel rods when it is desired to reduce the spacing pitch. Bosses may be provided on all types of cells (diamond-shaped, herringbone, hexagonal). Support is less essential for the central hexagonal cell, for it is generally for an instrumentation tube. FIGS. 4A, 4B, 4C and 4D show, as examples, different bosses which may be used, formed by stamping and local pressing of the plates, in the form of buttons 50 (FIGS. 4A and 4D) or bridges 52 (FIGS. 4B and 4D). Bosses 50 may be provided on the wall of the central hexagonal cell for centering the instrumentation tube 56 (FIG. 4C). The cells may be provided with means for holding the rods axially in position, which means are formed by springs added to the plates or stamped in the plates, as in the case of conventional grids. The hexagonal cell shown schematically in FIGS. 5A and 5B comprises, in addition to bosses 52, a spring 58 formed by stamping a leg in a plate, shaping the stamped leg and end welding it at 60. Spring 58 could also be added. FIG. 6 shows a herringbone cell comprising two bosses 50 and two springs 58 which are added or formed by stamping. In all cases, the presence of spot welds or of a welding bead increases the mechanical strength of the grid. In still another embodiment, shown in FIG. 7, a fuel rod 14 is held in position by springs 60 having the same form as the bridge-shaped bosses 52, but cut out. The same type of spring could be used in herringbone cells. In most assemblies, some at least of the grids are provided with fins for mixing the coolant streams. The diamond-shaped cells as well as the herringbone cells of a grid in accordance to the invention may be thus equipped. FIG. 8 shows, by way of example, a diamond-shaped cell having two fins 62 formed as lugs attached to the plates, on one edge thereof, and bent. The area of such fins 62 may be greater than that found in grids where each cell is hexagonal, because the available space between the rod and the plate is greater. Such fins may be provided on cells also having bosses and/or springs for centering and/or holding the rods. FIG. 9 shows, by way of example, the orientation and flow of the fluid streams obtained using fins of the kind shown in FIG. 8. It will generally be advantageous to offset two successive grids 13 angularly by 60.degree., so that the fuel rods of a radial slow towards a corner of the grid, are alternately supported in a diamond-shaped cell and supported in a herringbone shaped cell.