Patent Number: 044787863
Section: description

BEST MODE FOR CARRYING OUT THE INVENTION In FIG. 1, 1 designates a fuel channel formed from Zircaloy.RTM. sheet and positioned around sixty-four fuel rods 2. The walls of the fuel channel are each provided with a stiffening ridge 3 in the form of a folded-in sheet-metal portion running along the entire height of the fuel channel, or as an alternative, a ridge formed as a strip 3' of Zircaloy.RTM. running along a predominant part of the vertical extension of the fuel channel. The strip 3' may either be welded to the inner side of a continuous sheet-metal wall, or four such strips may be welded to four L-shaped sheet-metal elements in such a way that a substantially square fuel channel is formed. The wall portion, to the inner side of which the strip 3' is welded, or alternatively the strip itself, is arranged to project forward somewhat, thus obtaining a suitable sliding surface for a control rod. Along a predominant portion of its length, the fuel channel is provided with a stiffening device 4, which is made of Zircaloy.RTM. and with a cruciform cross-section. The stiffening device 4 has a central water tube 5 with four welded-on hollow wings 6, which are each attached to a ridge 3 or 3'. Each wing 6 is composed of two parallel, vertical sheet-metal walls 7 and a wall 8 arranged perpendicular thereto and at a distance to the ridge 3 or 3'. Each wall 8 is rigidly attached to a corresponding ridge 3 or 3' by means of a plurality of rivets 9, which are each passed through a distance block 10, thus forming a plurality of horizontal channels 11 between each wall 8 and the corresponding ridge. Said channels form pressure-equalizing, hydraulic connections between the four fuel box sections which are defined by means of the stiffening device 4. The lower ends of the stiffening wings 6 are provided with end walls in which inlet openings 12 for water are arranged, the cavity 6' of the stiffening device 4 thus being traversed with water in a vertical direction, thus obtaining a favourable moderating effect. As shown in FIG. 1, the total average cross-sectional area of cavities 6' and tube 5 is the dominant part of the total average cross-section of stiffening device 4. The inlet openings 12 are communicating with the nozzle of the fuel assembly via corresponding openings made in a bottom grid supporting the fuel rods 2, or in a cruciform member similar to the member 90 described below. The nozzle may be similar to the nozzle shown in FIG. 3a. A plurality of fuel rod spacers surround the fuel rods within a corresponding quadrant of the fuel channel 1 and are accomodated within a partial channel limited by two stiffening wings 6 together with two mutually perpendicularly oriented portions of fuel channel walls. In each quadrant, such spacers are arranged at different levels, each spacer surrounding a group of sixteen fuel rods. Each such group of fuel rods can then be inserted and removed individually. In the embodiment of a fuel assembly according to the invention as shown in FIGS. 2, 3 and 3a, each of the walls of the fuel box 20 is formed with one single, relatively long, vertical stiffening strip 21. Alternatively, each wall may instead be formed with a folded-in sheet-metal portion having the same shape as the ridge 3 in FIG. 1. The fuel rods of the fuel assembly are designated 22. The fuel assembly has a central, relatively thick water tube 23 which together with twelve thinner water tubes 24 are arranged in a cruciform configuration. In different level areas, the water tubes 23 and 24 are connected to each other by means of four wavy, substantially L-shaped bands 25 of Zircaloy.RTM., which are welded to each other and preferably also to the water tubes 23 and 24. Thus, the water tubes together with the bands 25 attached to them constitute a stiffening device 26 having a substantially cruciform cross-section. In each of the spiders formed by the bands 25 the spider arms are arranged in rigid mechanical connection with a stiffening strip 21 with the aid of a block 27 welded to the end of the spider arm, which block 27 is inserted into a corresponding hole in the stiffening strip 21 and attached thereto by a welded joint 28. Within each quadrant of the fuel box 20, the fuel rods 22 are positioned with the aid of a plurality of spacer devices 29 arranged at different levels, each spacer device then only surrounding fuel rods arranged in the corresponding quadrant. The fuel rods of the quadrants constitute corresponding groups which can be inserted and removed individually. Alternatively, spacers may be used which are each arranged to surround all the fuel rods surrounded by the fuel channel and also the water tubes 23 and 24. The fuel rods 22 rest on a bottom grid 22', supported by a nozzle 20' which is mechanically and hydraulically connected to the fuel channel 20. The nozzle 20', which is provided at its lower end with an inlet opening for water flowing through the fuel assembly, also supports a cruciform water distributing member 90 for the water flowing through the tubes 23 and 24. The water distributing member 90 is formed with four hollow, radially directed arms 90', which make an angle of 90.degree. with one another. The arms extend from the mid-portion of the distributing member, which mid-portion supports the central water tube 23 which, similar to tubes 24, is hydraulically connected to the hollow water distributing member 90. Each of the four arms 90' supports one group of three water tubes 24. The water distributing member 90 has a cruciform bottom 91, which is provided with four inlet openings 92. The arms 90' are provided with a plurality of connecting tubes 93 intended to constitute hydraulic connections between the distributing member 90 and the water gaps located outside the fuel assembly. Other embodiments of the invention have nozzles similar to the nozzle 20'. In certain cases, however, especially when the vertical water passageways of the stiffening device are in hydraulic communication with the outside of the fuel channel via a plurality of openings in the fuel channel walls, an alternative design is used in which the connecting tubes 93 and the bottom 91 are omitted. In the embodiment shown in FIGS. 4 and 5, the fuel rods 31 of the fuel assembly are surrounded by a fuel channel 30, in which each wall is provided with a stiffening ridge in the form of a stiffening strip 32 fixed by welding. Alternatively, the strip 32 may be replaced by a folded-in wall portion. In the same way as shown in FIG. 3, a relatively large water tube 34 is arranged together with twelve smaller water tubes 35 in a cruciform configuration. In each of a plurality of different levels, a plurality of mechanical connecting elements 36 are arranged between mutually adjacent water tubes, so that said water tubes together with the connecting elements 36 form a stiffening device 37 which has a substantially cruciform cross-section. The mutual distance between such levels is at least as large as the vertical dimension of the connecting elements 36, which means that good hydraulic connections are obtained between adjacent quadrants of the fuel channel and thus an efficient pressure equalization therebetween. Each connecting element 36 is arranged to make an acute angle with a vertical plane through the support arms in which they are included, which results in reactor coolant upon passage of a connecting element acquiring a horizontal speed component. As will be clear from FIG. 5, the obliquity is made in different directions for connecting elements disposed at the same level and included in one and the same stiffening wing. Suitably, elements arranged immediately adjacent to each other in horizontal direction are arranged with a deviating deflecting direction from element to element, as indicated in FIG. 5. The horizontal speed components caused by the obliquely arranged elements, give the effect that a flow of cooling water, which in a lower portion of the fuel channel is flowing along a certain fuel rod only, may further up be distributed among a plurality of fuel rods. Thus, a more even temperature distribution is obtained. Instead of welding the connecting elements 36 directly to the water tubes, the water tubes may advantageously be provided with sleeves 39 and the connecting elements be welded to said sleeves, as shown in FIG. 6. The quadrants of the fuel channel each includes a bundle of sixteen fuel rods. These are surrounded by a plurality of spacer devices 38 arranged vertically one after the other. Each spacer device comprises a plurality of spacer grid cells sufficient in number to accommodate a minor portion, usually one-fourth, of the total number of fuel rods in the fuel channel. In the fuel assembly shown in FIG. 13, each wall of the fuel channel 41 is made with a strongly folded-in mid-portion so as to form four hollow stiffening wings 43. Each of these is attached to a central water tube 44 with the aid of a plurality of rigidly fixed connecting members 45, arranged at a mutual vertical distance, or alternatively, with the aid of flexible connecting members 45'. The cavities of the stiffening wings constitute vertical passageways 43' which are supplied with water of relatively low temperature via a plurality of openings 46 in the bottom grid of the fuel assembly. The passageways 43' may be formed without any horizontal communication with the outside of the fuel channel by defining each passageway 43' in a direction radially outwards by means of a welded channel wall 42 with no through-holes. As an alternative, a perforated channel 42" may be used. By choosing the thickness of the channel wall 42 or 42", the demands made with regard to the safety of the reactor against earthquakes are taken into account. If these demands are relatively small, instead of walls according to any of alternatives 42 and 42", there may be used a plurality of, for example curved, connecting elements 42' arranged one after the other in a vertical direction and with a mutual distance. In this way an unnecessary great stiffness of the fuel assembly may be avoided, and reduced friction forces may be obtained at contact surfaces between fuel assembly and control rod. A design according to FIG. 13 implies that fuel channels for a plurality of reactors, with greatly varying demands regarding seismic safety, may substantially be manufactured by the same method, the same tools and the same materials. The adaptation to specific reactor demands is made by a suitable dimensioning of the channel walls 42, or 42", or of the connecting elements 42' if these are used instead. In FIGS. 14 and 15, 51 designates a fuel channel surrounding sixty-four vertical fuel elements 52, which are positioned by means of a plurality of spacers (not shown) of the type shown in FIG. 4. The fuel channel also surrounds twelve water tubes 54 having a relatively small cross-section and a central water tube 53 of relatively large cross-section. At a lower level six water tubes 54 are each provided with a flattened portion 58 and the central water tube 53 with a flattened portion 59. Corresponding flattened portions 58' and 59' are to be found at an upper level. At said lower level, the flattened tube portions 58 and 59 are squeezed betweem two straight, horizontal bars 55, and at said upper level two bars 55' are arranged in a corresponding manner. Seen from above, the bars 55 make an angle of 90.degree. with the bars 55'. Four vertical bars 57 are each included in a fuel channel wall, each of the horizontal bars 55 being fixed to two bars 57 located opposite to each other by means of screws 60. A plurality of horizontal bars 55 are fixed to each of the bars 57. An arrangement shown on FIGS. 14 and 15 has the advantage, compared with the designs of FIGS. 3 and 4, that the minimum distance between a connecting member attached to the water tubes and the nearest fuel rod is larger with the arrangement shown in FIGS. 14 and 15 than with the designs shown in FIGS. 3 and 4. It will be clear from the foregoing that all the embodiments of a fuel assembly according to the invention shown on the drawings are well suited for a division of the fuel rods into four bundles. The fuel rods surrounded by the fuel preferably are distributed in four equally large bundles, each bundle or assembly including a plurality of spacer devices, each spacer device being designed to position a minor portion only, usually one-fourth of the total number of fuel rods in the assembly. When using such spacer devices, it is possible to deviate from the conventional principle, according to which the number of grid cells arranged in one and the same horizontal plane is equal to the total number of fuel rods in the fuel box, and it has proved that this may lead to a number of different advantages. A fuel assembly according to the invention is preferably made in such a way that a plurality of groups of the above-mentioned, partially positioned space devices are arranged axially one after the other in the fuel box, each group then containing a plurality of spacer devices arranged at least at two different levels, and the spacer devices of each group together positioning all of the fuel rods surrounded by said fuel box. Examples of locations of fuel assemblies constructed in this manner are shown schematically with the aid of FIGS. 7, 8, 9, 10, 11, 12, the four quadrants of the fuel boxes being designated A, B, C, D, and each spacer with S and an index, each one of the above-mentioned groups of partially positioned spacers having an index characteristic of the group. The arrangement of the spacers described with reference to FIGS. 7-12 involves a number of advantages, among other things an improved water redistribution between portions of the fuel assembly having different loads.