DE2023342A1 - Nuclear reactor core assembly - containing hexagonal fuel - and breeder rod/sets - Google Patents

Abstract

The fuel and breeder rods are grouped in sets within hexagonal jackets which have spacing and sealing rings around them, typically at the top and bottom of the fission zone and at the head end. In addition, those elements in the outer rows of the complete core have means of compression and sealing surfaces which mate so as to seal the interior of the core from the outside. A controlled coolant pressure is exerted on the outer walls of the jackets, using throttles, to counteract the internal pressures. The wall thickness, hence wt. and cost, of the jackets is reduced.

Description

REACTOR CORE STRUCTURE The invention relates to a reactor core structure with fuel assemblies, where in a box, the rods with fuel and / or Containment material is contained In such fuel elements, in contrast to constructions, which have a boxless arrangement of fuel rods (so-called unthrottled cores given the opportunity to regulate the coolant outlet temperature. Of a Fuel assemblies surrounding boxes are used in particular in fast breeders.

In fuel assemblies in which the fuel rods in a; crate are arranged, there is the problem that the wall on the one hand a sufficient Must have strength, to withstand the internal pressure in the boxes, on the other hand, they should only have a low neutron absorption, so not the efficiency of the nuclear reactor is reduced by excessive neutron withdrawal.

In the previously known core structure with fuel assemblies, in which the fuel rods are arranged in a box, the box has a solid wall and dimensioned for the full pressure difference occurring across the core. From the US Pat. No. 3,317,399 shows that wall thicknesses of up to over 6 mm are required was. The neutron absorption now increases with the mass of the structural material, so that in the interest of a good efficiency of the real fan it is not worthwhile Build fuel assemblies with the smallest possible wall thicknesses.

Therefore, U.S. Patent 3,317,399, cited above Recommended to use the spacers for the fuel rods with the box walls associate. In this way, the box walls are ribbed in such a way that the spacers form the stiffeners. The wall thickness of the box can then be reduced considerably will.

It would also be used to reduce the wall thickness of stinging elements already proposed, the box walls above the gap zone after the fuel assembly head end to be provided with perforations. This is due to the pressure equalization over the gap zone reduces the effective pressure difference towards the element base.

The known and the proposed measures have the disadvantage with it that additional expenditure is required for all fuel assemblies.

The inventor has therefore set himself the task of constructing a reactor core to propose in which the wall thickness of the fuel assemblies with very little effort degraded.

can be. This object is achieved in that the edge elements Have bracing devices and are provided with sealing surfaces. That the core interior close to the outside and that inside the core by means of throttling devices the pressure in the fuel assembly cases counteracting the pressure is built up.

According to a development of the invention, the sealing spacer strips preferably in the area of the lower and upper end of the cleavage zone, as well as at the head end the fuel assemblies arranged.

An embodiment of the invention is shown in the drawing and is described below. Fig. 1 rye through a horizontal section a reactor core according to the invention Fig. 2 shows the fuel elements in the invention Execution - As can be seen in Fig. 1, the reactor core is in this embodiment formed from fuel assemblies 1, which have the shape of regular hexagon. Between The fuel assemblies 1 are rule eXenents at various positions in a known manner 2 arranged. The fuel assemblies of the outer row 3 are provided with devices by which they are tightly braced.

Fig. 2 shows two grid plates 4 and 5, in whose openings the Fuel assemblies 1 sit.

The fuel assemblies 1 each have a foot part 6 with holes 7 through which the coolant - in this case liquid sodium - from the through the two Grid plates 4 and 5 formed space in the fuel assemblies upwards along the the fuel rods forming the fuel assemblies flows. The individual fuel rods are in the one fuel assembly shown in section by vertical lines indicated.

Seen from bottom to top, the fuel rods are first of all a breeding zone then a crevice zone and then again a breeding zone is formed. A gap gas space is provided in a known manner at the upper end of the fuel rods.

To the fuel assemblies on a uniform low mutual To keep a distance, they are on the outside in the usual way with sealing spacer strips 8, 8 ', 8' 'provided. The elements of the outer row 3 (see Fig. 1) - have taken place the sealing spacer strips sealing surfaces 9 or 10. Are on each fuel assembly three sealing spacer strips 8, 8 ', 8 "are arranged, so you can use the sealing surfaces either only provide between two sealing spacer strips, as shown on the right The image side is shown in FIG. 2, in which the sealing surface has been designated by 9 or in the entire area from the bottom to the top sealing spacer strip, as can be seen in the lines of the picture side of FIG. 2, the sealing surface here with 10 denotes nirde.

In the first case, one obtains one that is closed off from the outside in the core Space 11, the up and down through the sealing spacer strips 8 and 8 'and after Is bounded on the outside by the fuel elements of the outer row 3. In the second case one obtains a corresponding one at a height above the first space 11 the upper sealing spacer strips 8 ″ delimited space 120 In which The reactor to which this exemplary embodiment relates is located in both the fuel elements as well as in the space around them liquid sodium as a coolant.

The highest fluid pressure prevails in that through the grid plates 4 and 5 formed space. The liquid pressure then increases over the height of the fuel elements evenly. Now the walls of the fuel assemblies do not cope with the pressure inside the fuel assembly to be claimed is through a fuel assembly or also through several, a connecting line from its foot part to the space 11 between the two lower sealing spacer strips and if the fuel assemblies of the outer fuel assembly row are shown on the left in FIG. 2, are formed, also made to the space 12 above. In the or A throttle device is provided in the connecting lines so that the via the connecting line or

the connecting lines in the room 11 and possibly 12 adjusting The pressure can either be predetermined or set for different operating states. As a result, builds up around the fuel assemblies in spaces 11 and 12 while the reactor is in operation around a pressure counteracting the internal pressure of the fuel elements, so that the Walls of the fuel assembly boxes are only stressed with a slight pressure difference and therefore only need to be of low wall thickness.

The edge elements must absorb the radial forces caused by the Pressure in the spaces 11 and possibly 12 arise. You are therefore with appropriate To provide bracing devices so that they are fixed to the grid plates 4 and 5 can be braced.

For the purpose of pressure equalization and mass distribution of the coolant The box walls can be perforated over the entire core cross-section in the upper area be provided. At the same time, this poses the problem of box bending as a result of the temperature imbalance, i.e. the uneven temperature distribution solved over the Rernquersc1rnitt.

The advantages of the embodiment according to the invention are that due to the relief of the fuel assembly box walls when the coolant flows outwards in the reactor core these need to be of only small wall thickness and their bulging by the built-up via the connecting lines and the throttle devices Back pressure is effectively prevented. One arranges sealing spacer strips at the bottom and the upper end of the gap zone as well as at the head end of the fuel assemblies, so it is possible via throttle devices in the upper chamber 12 of the reactor core Build up lower pressure than in the lower chamber 11. This allows for the upper A lower back pressure can be selected than for the lower part of the fuel assemblies, where there is a higher liquid pressure inside the fuel assembly. Because the back pressure acts between sealing spacer strips arranged above and below axial forces on the fuel assemblies do not occur.

Claims (5)

P a t e n t a n s p r ü c h e Reactor core structure with fuel elements in which rods are placed in a box with fuel and / or breeding material are included and the sealing spacer strips for bear mutual distancing that the pulp elements of the outer row (3) have splitting devices and with Sealing surfaces (9, 10) are provided which close off the inside of the core towards the outside and that in the interior of the core by means of throttle parts a pressure in the fuel boxes counteracting pressure is built up. 2. reactor core structure according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the arrangement of the sealing spacer strips (8, 8 ', 811) is preferred in the area of the lower and upper ends of the fission zone and at the top of the fuel assemblies are provided. 3. Reaktor3cern structure according to claims 1 and 2, d a d u r c h g It is not noted that the sealing surfaces (9) are only in the area of the gap zone available. 4. reactor core structure according to claim 1 or one of the following, d a it is indicated that the sealing surfaces over the area of the Fissure zone also up to the head end of the fuel assemblies are present. 5. reactor core structure according to claim 1 or one of the following, d a It is noted that the box walls have perforations in the upper area own.