Patent Number: 039363490
Section: description

DESCRIPTION OF THE PREFERRED EMBODIMENTS In FIG. 1 there is shown a fast neutron nuclear reactor comprising a central zone 1 having plutonium enriched fuel elements, an intermediate zone 2 having more highly enriched fuel elements and a zone 3 of breeder fuel elements. In addition to fuel elements the central and intermediate zone include some control rod guide tubes (only two being indicated and designated `C`) and the inner zone also includes some shut down rod guide tubes (only one being indicated and designated `S`). Except at the periphery of the breader zone 3, the components are generally arranged in modules each comprising a cluster of four components of which at least three are fuel elements. One of the fuel elements of each module is rigidly supported in upright position whilst the remaining fuel elements are tilted towards the rigidly supported fuel element. Where one of the components of the module is a central rod guide tube it may be free standing or may lean on the fuel elements but does not have interlocking bearing pads. FIG. 2 shows a module of four components comprising types X, Y and Z wherein the component type Z is rigidly supported whilst components type X and Y are tilted towards the centre of the cluster as indicated by arrows designated 4. The rigidly supported components are indicated by cross-hatching in FIG. 1 and the four associated components of each module are indicated by broken lines. The arrows 4a in FIG. 1 indicate the loading direction of the components which are not in regular module. Either of components type `X` can be a control rod or shut down rod guide tube but neither type `Y` or type `Z` can be so used; type Y is excluded because stability of the module depends on the interlocking afforded by this component during refuelling of type `Z`, and type Z is excluded because it defines the position of the module with respect to the remainder of the core. The fuel elements, control rod guide tubes and shut down rod guide tubes are generally similar in outward form except that the guide tubes do not have the interlocking bearing pads. A fuel element is shown in FIGS. 3, 4 and 5. Each fuel element comprises a cluster of fuel pins (not shown) enclosed by a wrapper of hexagonal cross-section and designated 5 in FIG. 3. The fuel element has a lower spike 6 which is engageable with a socket associated with a diagrid, for example, as in the manner described in U.S. Pat. No. 3,383,287 whereby the fuel elements are disposed generally upright. The elements types X Y which are arranged to tilt have resilient spikes 6 and the tilt is achieved in conventional manner as disclosed in U.S. Pat. No. 3,383,287 by eccentrically in the diagrid sockets. The rigidly supported element type Z, of course, has a substantially rigid spike 6. The upper end region of the element has a cylindrical portion 7 and the transition from circular section to hexagonal section is effected by a hexagonal taper 8. The transition from hexagonal section to circular section at the lower end region of the element is effected by a circular taper 9. Immediately above the circular taper there is a group of rib like extended corner features or splines 10 projecting outwardly as shown in FIG. 4. Intermediate the ends of the element there are bearing pads 11 in the form of spline like ribs 11a on each side of the wrapper 5. Each pad 11 comprises one full width and one half width ribs 11a which can interlock with co-operating ribs and half width ribs 11a on adjacent fuel elements as shown in FIG. 2. A single bearing pad 11 is shown in FIG. 6 the ribs 11a having taper lead in surfaces 11b and 11c at each end. When a fuel element is being loaded into a reactor core in the presence of installed fuel elements, the fuel element is suspended and lowered to enter the spike 6 alongside the upper cylindrical portion 7 of an installed adjacent element. Further lowering brings the circular taper 9 in contact with a side of the hexagonal taper 8 of the adjacent element so that the fuel element is displaced sideways generally into its correct azimuthal position relative to the centre of the cluster of components. By further lowering of the fuel element the extended corner features 10 abut the sloping hexagonal tapers 8 of the adjacent element and the reaction between the corner features and the adjacent element causes rotation of the element to a position such that the bearing pads 11 will pass between adjacent fuel element wrappers 5, and the wrapper 5 of the suspended element will pass between the pads 11 on adjacent elements. When the fuel element is lowered sufficiently to engage the lower ends of the ribs 11a with the upper ends of the ribs 11a of adjacent elements, the taper lead in surfaces 11b of the ribs assist in radial and fine rotational adjustment of the fuel element, and the taper surfaces 11a assist in radial alignment, to engage the ribs accurately so that the fuel element can be fully lowered and spiked into the diagrid. The interlocking ribs 11a of the bearing pads 11 accurately locate all the components of the cluster and lateral slip of the components is reduced to very small limits. The second construction of nuclear reactor shown in FIGS. 7 and 8 is generally similar to the first construction except that fuel elements only are arranged generally in clusters of six, each resiliently tilted towards a central void to form a circular arch. The central void can be occupied by a free standing control rod or shut down rod guide tube. In FIG. 7 some of the control rod and shut down rod guides tubes are shown and again designated `C` and `S` respectively, but in the breeder zone some of the voids are left vacant some examples being designated `O`. A basic module 12 of six fuel element is enlarged in some regions, for example, the module designated 13 has an additional fuel element appended to it and the module designated 14 has two additional fuel elements appended to it. The appended fuel elements are arranged to tilt towards the centre of the basic cluster.