Patent Number: 047755091
Section: description

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS FIG. 1 shows schematically the only components concerned by the invention of a nuclear fuel assembly which may include, in a usual way, an upper end piece 10 and a lower end piece 12 connected together by guide tubes 14. On the guide tubes 14 are mounted several grids 16 spaced apart along the assembly. Some at least of the grids are fixed to the guide tubes 14 and hold the fuel rods 18 in position in a regular array. The assembly described by way of example has a hexagonal cross-section and the grids 16 hold the rods in position at the nodal points of an array or "Lattice" whose elementary cell is an equilateral triangle whose sides are parallel to the plates which form the girdle 20 of grid 16. Guide tubes 14 are substituted for the rods 18 at some nodes of the array. Some at least of the grids 16 are as shown in FIGS. 2 to 5. They each include a plurality of beds of mutually parallel plates for holding and spacing the rods, fixed to the girdle 20 and spaced in the longitudinal direction. In the embodiment shown in FIGS. 2 to 5, the grid 16 has three beds of plates, each bed being perpendicular to the longitudinal axis of the assembly. Each bed is formed of a series of mutually parallel plates. The plates of the set forming the top bed 24 are at 60.degree. from the plates 22 and 23 and all the plates are fixed to the girdle in a conventional way, generally by welding. In the construction shown in FIGS. 2 to 5, the girdle is formed of a flat bent metal strip and the plates of the three beds are undulated or corrugated at the spacing pitch of the rods. In order to provide resilient holding of the latter, support means are provided on the girdle and on the plates. The support means include two rows of support bosses 26 and 28 provided on the girdle 20, halfway between the beds of plates (FIG. 2). The bosses are formed by portions cut out in the metal strip which forms the girdle 20 and bent so as to projet inwardly of the girdle. The support means further include, on each of plates 22, 23 and 24, resilient tongues for engagement with the rods. Some of these tongues, designated 30, have an S-shape so as to cooperate with adjacent rods of the lattice. Others, designated at 32, only project from a single side. They will more particularly be provided at a position where the plates define a pocket for receiving not a fuel rod 18 but a tube 14. With such an arrangement, each rod is supported at four points at the level of each bed. The four support points are offset angularly by 120.degree. when passing from one bed to the next. The girdle and the plates may be formed, in a conventional way, from an alloy called "INCONEL", from stainless steel or from a zirconium based alloy. Each guide tube 14, such as the one shown in dot dash lines in FIGS. 3, 4 and 5, is fixed to each of the three beds of the grid 16. Fixing is advantageously provided by means of a split sleeve or sheath 34, as shown in FIGS. 6 and 7. Each sleeve 34 is fixed to a guide tube 14, at a suitable position, by imprisoning the guide tube in the sleeve, as is clear from FIG. 6. The presence of the longitudinal slit 38 in the sleeve provides the flexibility required for inserting the guide tubes and clamping them. Pairs of flats 40, 42 and 44 formed on the sleeve are provided for positioning and retaining the associated plates 24, 23 and 22. These plates may be welded to the sleeve 38 or simply positioned. On this latter assumption, in a variant of construction shown in FIGS. 8 and 9 (where the members already shown in FIGS. 6 and 7 bear the same reference numbers), the plates have punctured portions 36 for imprisoning the lugs 48 formed for this purpose in sleeve 34, these punctured portions then serving as rod supporting elements. The grid shown in FIG. 2 further includes fins 50 formed on the edge of the girdle and facilitating the introduction of the assemblies in the core, simultaneously with mixing of the coolant. In the grids shown in FIGS. 2 to 9, the beds of plates 22, 23 and 24 are disjointed and separated by a gap which is of the same order as the height of the plates. But it would also be possible to use jointing beds, the plates of one bed being engaged with those of the adjacent bed, or on the contrary the gap between the beds may be increased. The plates may further be provided with mixing fins, so as to provide both a supporting function and a function of mixing the fluid streams. These fins may have one of the constructions which will now be described, in their application to grids having a mixing function. These mixing grids may be alternated with support grids in the same fuel assembly. The mixing grids must provide the best compromise possible between requirements which are to some extent contradictory. Their neutron absorption must be as low as possible, which leads to reducing as much as possible the mass of material which forms them and in choosing, as far as possible, a material with a small capture section such as a zirconium based alloy. The mixing fins must homogenize the flow and reduce the temperature differences by causing transverse redistribution of the coolant streams. But the presence of the fins must not cause an increase of the pressure loss such that there is an unacceptable reduction of the flow rate. The distribution of the plates in several beds offset in the axial direction decreases the pressure loss. When the plates are provided with fins, these latter may be distributed axially between the beds so as to obtain a three-dimensional effect. Several exemplary types will now be described with advantageous distributions, leading to different flow modes, some of which are particularly well adapted to a triangular mesh and others to a square mesh. By way of a first example of a mixing grid, FIG. 10 shows a lattice of 5.times.5 rod reception pockets 18. Grid 16a, a fraction of which is shown, includes two spaced beds 50 and 52. The beds are connected together by corner rods or bars. Each bed includes plates oriented in two different directions, but each bed is incomplete in that a pocket is only completely defined by plates belonging to the two beds. It can be seen, for instance, that bed 52 includes plates 56 oriented in a first direction and plates 58 oriented in the perpendicular direction. The set of plates having the first direction is completed by plates 60, disposed in staggered fashion with respect to the first ones, but belonging to bed 50. Plates 56, 58, 60 include means for mixing the fluid streams. These means are formed of half-fins each placed on a single elementary pocket and disposed in opposite pairs at the corners of the pockets. In the variant of construction shown in FIG. 11, plates 56 have complete fins 62 cut out in a non-emergent window of the plates. FIG. 11 also shows centering fingers 64 which may have a construction similar to that shown in FIG. 2. In a further variant of construction, shown in FIG. 12, two opposite half-fins 64 are formed by stamping and deformation in each window of a plate 56. FIG. 13 shows an advantageous distribution of the half fins 66 in the case of a grid 16b having two beds 50 and 52, each bed being formed of a set of plates all having the same direction, the plates of one set being orthogonal to the plates of the other set. The half-fins 66 carried by the same plate are spaced apart at regular intervals, equal to the dimension of a pocket and directed alternately in one direction and in the other. The projection on the same plane of two sets of fins leads to a complete lattice of orthogonal fins. But, contrary to what would happen if all the plates were in the same plane, each lattice of fins causes its own cross flow mode. This flow mode is shown schematically by the arrows F1 in so far as bed 50 is concerned and F2 in so far as bed 52 is concerned. On its passage through the first bed, the air gaps of the same direction are swept in a given direction by the coolant. On passing through the second bed, it is the air gaps of perpendicular direction which are swept in their turn. In the variant of construction shown in FIG. 14, each of the two beds 50 and 52 of grid 16c include half of the fins belonging to one set of fins parallel to a first direction and another half of fins of the set directed in the orthogonal direction. In other words, in a given set, each plate belongs alternately to the upper bed and to the lower bed. In a given bed, the plates belonging to a set (plates 56 for example) include two half-fins at each intersection with the plates 58 of the other set, the two half-fins being in opposite directions. And plates 58 of the same bed include two half-fins in the middle of the space which extends between two crossing points. In axial projection, the superimposition of the two fin lattices again leads to a complete lattice of opposite fins. But, if all the fins were in the same plane, they would generate a circumferential coolant current about each rod. On the contrary, in the grid shown in FIG. 14, the two half fins which, about a given rod, cause the flow of the coolant about the rod, are situated at different axial sides and promote the appearance of a helical current more favorable from the mixing point of view. The plates may include, instead of the straight plates of FIGS. 13 and 14, plates bent in the form of a staircase or in crenellated form. FIGS. 15 and 16 show schematically two possible arrangements of the plate in a two bed grid, each plate having a staircase shape (FIG. 15) or a crenellated shape (FIG. 16). Other combinations are further possible, having two or three superimposed beds. In yet another variant of construction, the beds are jointing and some of the plates of each bed have lugs criss-crossing with other beds. This solution has the advantage of providing good mechanical strength and facilitating the distribution of the fins, particularly in the case of a rectangular mesh lattice. FIGS. 17 to 20 show possible construction of a three-bed grid, the plates of each bed 22, 23 and 24 being bent in the form of a staircase. It can be seen that the arrangement of the plates is such that, in projection, they completely define the pockets: FIG. 18 is such a top view of the three beds of a grid, showing the superimposition of the plates of the three beds, represented for the sake of clarity respectively in continuous lines, broken lines, dotted lines. Some pocket walls include grid sections placed one above the other. The beds may then be secured together in a simple way by providing the plates, in the sections in coincidence, with securing lugs 60 (FIG. 19). These lugs may be interfitted with each other as shown schematically in FIG. 20. Another solution consists in forming, in some of the lugs, buttons such as 62 which engage in recesses in the associated plates. The number of lugs may then be reduced. Another solution consists in providing fixing by rivets or spot welding. The rivets may also form means for centering the rods. A grid thus formed has the advantage of good mechanical strength and simple manufacture, especially when it uses centering rivets. The arrangement of the plates in two perpendicular directions introduces heterogeneities promoting mixing. Finally, the fins may be disposed both in the upper layer and in the lower layer. When the grid has three beds of plates, it is possible to distribute the mixing fins in the three beds. In particular, a bed with three grids may be provided for reconstituting by superimposition a half-fin arrangement of the kind shown in FIG. 21 or the half-fin distribution shown in FIG. 22 which may be termed "braided lattice" and which creates diagonal and opposite flows in the air gaps between rods. For that, the following may be provided: an upper bed of plates 24 having a braided lattice of half-fins organizing in a first direction; a middle bed of fins 23 having fins in a similar braided arrangement, but on opposite direction; a lower layer not having any fins, but only lugs for fixing it to the upper and middle beds so as to create a mechanicaly rigid grid. Each cell containing a rod is then provided with two half-fins, one belonging to the upper bed and the other to the middle bed, which tends to cause the coolant to rotate in spiral fashion about the rod in one direction which changes when going from one cell to the next cell. With this combination of two braided lattices, we find again the effects of the network shown in FIG. 21, but using fins placed in two planes offset in the general flow direction and whose relative distribution is shown in FIG. 22a. The design which has just been described in the case of a square lattice is directly transposable to the case of a triangular lattice. The plates are then bent at 60.degree. and not at 90.degree. and the lower bed is complete so as to define a triangle of plates about each rod and not a diamond shape. With this arrangement, the support element carried by the plate may be perpendicular to each rod. The plates of the lower bed may be provided with lugs for fixing to the upper and middle beds. FIGS. 23 and 24 show respectively a possible construction of the three beds and the fin arrangement obtained by the superimposition of these three beds. It will be generally seen that the invention provides great flexibility of construction and permits the most advantageous solution in each case. The plates may be straight or bent in the form of a staircase or in crenellated form; the beds may be non-jointing; the fins may be provided on one or more beds so as to provide a mixing function. The fins may be stamped in the plates themselves and be placed at the level of the air gaps between rods because of the absence of crossing of plates at the same level. The plates may have a perforated or crenellated shape. Finally, it is possible to brace the beds so as to ensure good mechanical strength, possibly using means which also participate in centering the rods.