DE1764478B2 - REACTOR CORE FOR A NUCLEAR REACTOR - Google Patents

Description

The invention relates to a reactor core for an atomic nuclear reactor, which by a coolant is cooled with moderator properties and a number of fuel rods freely surrounded by the coolant contains, which are arranged parallel to one another at a certain distance from one another, wherein in the cross section through the reactor core, the fuel rods in a single grid formation in rows Grid lines are arranged, and with fuel rods missing at regular intervals.

Such a reactor core is known from "Directory of Nuclear Reactors", Vol. IV, 1962, p. 204. On pages 3 to 8 of the same publication, a 6s reactor core is described which is constructed from fuel elements arranged in a grid-like manner, the fuel rods in each fuel element being arranged in a sub- bitter formation. From p. 228 of the same publication, a reactor core for an atomic nuclear reactor can also be found, which is cooled by a coolant with moderator properties and contains a number of fuel rods which are freely surrounded by coolant and which are arranged parallel to one another at a certain distance from one another Cross-section through the reactor core, the fuel rods are arranged in a single grid formation in rows on grid lines. Some of the grid positions in this reactor core are not occupied by fuel rods. At these grid locations there are tubes that have a larger outer diameter than the fuel rods.

These known reactor cores have the disadvantage that either the fuel moderator ratio in the cross section through the core is not constant , which locally ·; This has the consequence of neutron flux peaks and thus local power peaks, or that the fuel moderator ratio is kept constant by a complicated structure. It was common so far. To prevent power peaks from changing the degree of enrichment of the fuel and the amount of absorber material over the cross section of the reactor core in a specific, previously calculated way. Such a structure de, reactor core increases the manufacturing costs of the atomic nuclear reactor considerably and makes a complex operational organization for the reactor necessary.

Fs is therefore the object on which the invention is based, a reactor core of the type mentioned at the beginning To develop a type which is simple in its structure and a neutron flux distribution which is uniform in cross-section having.

This is achieved according to the invention in that in a manner known per se at all or at some of the lattice positions not occupied by fuel rods are tubes that these tubes are the same Outside diameter, as the fuel rods have, and that at least some of these tubes with the Coolant are filled, which flows through at least one inlet opening in these tubes and through at least one outlet opening flows out of these tubes, with obstacles in these tubes to the Limitation of the amount of coolant flowing through the tubes are provided.

This extremely simple structure has the advantage that the fuel moderator ratio is for everyone Fuel rods in cross section through the reactor core is the same and therefore for a balanced neutron flux distribution is taken care of. To that which generally occurs at high moderator fuel ratios Avoid the disadvantage that the circulation of the coolant must be maintained by pumping, it is ensured that the coolant is continuous mainly around the outside of the im Reactor core arranged tubes flows. For this purpose, there are barriers in the pipes to limit the situation the amount of coolant flowing through the tubes is provided so that the coolant is within of these tubes only takes part in the overall circulation of the coolant to a limited extent.

The fuel rods are preferably, as also from "Directory of Nuclear Reactors", Vol. IV, 1962, P. 66 and 67, known, divided into groups, each of which, inserted in a prism-shaped box, forms a lattice component, the walls of which

run on or in the vicinity of not completely occupied grid lines, the volume ratio of fissile material to moderator material for the central fuel rods is just as large or larger than for the Edge fuel rods of the grid components.

This not only achieves that the insertion of the prism-shaped boxes for relocating only a few;. Split bars leads, which contributes to an improvement in the achievable power density, but also that the edge fuel rods of the grid components show no undesirable power peaks.

The walls of the adjacent grid components can be between two fully occupied, outer grid lines of the components can be arranged by increasing the distance between them. Through this greater freedom is obtained in designing the reactor core structure without the aforesaid Advantages are lost.

By feeding a suitable filler into the coolant in the free grid; ! etch located Pipes or through different openings in the> Vand of the pipes, it is possible at the same time to to influence the moderator fuel ratio also in the vertical direction so that also in axial direction a flux course without peaks is obtained. Preferably at least part of the tubes filled with coolant formed as guide tubes, each of which contains a rod that is arranged displaceably in the longitudinal direction and consists of a material that the local neutron flux influenced. In thermal reactors, a neutron absorbing substance is generally used used as the material for the rods, while in the case of fast reactors fissile material or breeding material is used. Ls Lt also possible that the rods partly or entirely from Moderatormaierial exist.

The structure of the reactor core according to the invention can be independent of numerous types of nuclear reactor on the type of coolant used. It can be used in pressurized water reactors just like in steam-cooled, rapid reactions be related.

In the following an example, preferred embodiment of the invention with reference to the drawing explained in more detail: rt.

F i g. 1 shows the scheme of an open grid used in the reactor core, in which the position of the walls a grid structure is indicated;

F i g. 2 shows a cross section through the in FIG. 1 indicated lattice component;

F i g. 3 is a plan view of a reactor core according to the invention;

F i g. Figure 4 is a cross-section through another embodiment of a grid component;

Fig. 5 shows a vertical section through two pipes filled with coolant and through a guide pipe for a pressurized water reactor;

F i g. 6 shows a modification of the one in FIG. 3 shown reactor core.

In Fig. 1, the fuel rods 1 are arranged in a lattice formation at points at which the lines 2 and 3 intersect with lines 4,5,6 and 7. The grid lines 2,5 and 7 are on the one Fuel rod following :; Unoccupied grid places. This grid becomes fuel rod groups within combined by walls 8 to form a grid component 9. The walls run on grid lines that were originally incompletely filled with fuel rods. The lattice component has a hexagonal Cross-section with the corner points 10 to IS. At points 16 to 26 the racing sticks have been removed. The reactor core is made up of these grid components.

In Fig. Figure 2 is a cross section through lattice components with the walls 8, 28 and 29 shown. The majority of the free grid sites in FIG. 1 is in this cm Case of tubes 30 occupied. The remaining free grid places take guide tubes 31, which the have the same outer diameter as the tubes 30 and the fuel rods. In these guide tubes are Rods 57 are arranged which absorb trending from a neutron Substance exist and can be moved in the longitudinal direction. It is possible another than that in Fig. 2 between the number of tubes 30 and the number of guide tubes 31 to be used. For example, in special cases all free Giuer places in a grid component be occupied by tubes 30. It is also possible that all or some of the free Lattice places are occupied by guide tubes 31.

3 shows a plan view of a reactor core 97, which shows the distribution of the lattice components 9 over the core. In this scheme are with 91 denotes those lattice components that have no control rods. The designated 9 Lattice components are, as shown in Fig. 2, provided with control rods. This is indicated schematically by circles in the grid components. In the lattice components 91, all lattice locations where there are no fuel rods are preferably occupied by pipes filled with coolant.

F i g. FIG. 4 shows, in cross section, a change in a lattice component as used in connection with FIG F i g. 2 has been described. Inside the wall 8 of a lattice component 9 are fuel rods 1 and Rods 57 arranged from a neutron absorbing material. These bars 57 are longitudinal movable and thus serve as control rods. The lattice exists within the lattice component from see intersecting lines (not shown). The wall doesn't necessarily have to be on an incomplete basis occupied grid line be arranged, it can rather be between two fully occupied grid lines of adjacent lattice components, with the distance between the two increasing is. This way, there is more coolant near the wall, which means a low power peak can result. However, it is possible to choose the dimensions so that these power peaks the additional cooling capacity of the edge bars is not exceeded. It is also possible to use the power peaks by introducing a flammable poison into the edge bars, with the result that the power increase factor in such a grid component is lower than in another Lattice component with poison in the edge bars.

At or near the corner points 58, some control bars are omitted in order to distribute the power with too high a power factor at these points.

F i g. 5 shows, in a vertical section, two tubes 30, between which a guide tube 31 is located is located. With 64 and 65 end grilles are designated, which not only as a carrier for the tubes 30, but

also serve for the guide tubes 31. Each of these grids has through openings 66 and 67 to allow the coolant to flow through the reactor core. As from the above As can be seen, the majority of the coolant moves up through the passages 68 which are between the pipes are left free.

However, some of the coolant can enter the interior 70 of the tubes 30 through inlet openings 69. If the tubes are provided with further openings 71, the lower openings 69 can be omitted as long as the lowermost opening of the openings 71 is sufficiently close to the lower one Edge of the tubes 30 is. The heated coolant can be returned to the upper part through the outlet opening 72 flow out of the pipe.

Apart from the fact that a tube 30 is filled with a moderating coolant during operation It is also possible to use pipes that are inside with a solid moderator composition are filled. Tubes of this type, which are designated by 63, have a inside Moderator composition 73, which - although not shown - consists of absorbing neutrons Sticks or tablets, e.g. of a flammable poison, may be made, the moderator composition is coordinated by alternately stacking these rods or tablets that the greatest possible neutron flux smoothing is achieved in the vertical direction. The same result will be obtained when, as shown in the case of the tube 30, two groups of openings 71 and 74 in the side wall are provided in such a way that the material concentration of the pipe wall in two places reached a minimum along the pipe.

The distribution of the material density of the pipe wall can in turn be influenced by the fact that the openings are made larger or smaller, or

ίο that they are closer to each other or further apart lie. Such measures can also be taken with the guide tubes. The guide tube 57 has guide parts 93, 94 at two points, which fit smoothly in the guide tube.

are slidable. They can be provided with narrow slots 95, 96 through which the coolant flows can. For example, in the case of a pressurized water reactor, these slots can cause the accumulation prevent steam bubbles under the guide parts

otherwise what would otherwise lead to local overheating.

F i g. FIG. 6 shows a plan view of a modification to that shown in FIG. 3 shown reactor core. With this representation is each grid component 9 with control rods

provided, as shown in FIG. 2 are shown. Only half the grid components 91 of the reactor core 140 have no control rods. By circles it is again indicated that in the respective Giiierverbindungen Control rods are located.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Reactor core for a nuclear reactor, which is cooled by a coolant with Moderatoreigen- S property and contains a number of fuel rods freely surrounded by coolant, which are arranged parallel to one another at a certain distance from one another, the fuel rods in a cross section through the reactor core single grid formation are arranged in rows on grid lines and with fuel rods missing at regular intervals, characterized in that tubes (30) are located in a manner known per se at all or at some of the grid positions not occupied by fuel rods , that these tubes (30) have the same diameter as the pulp rods, and that at least some of these tubes (30) are filled with the coolant that flows into these tubes through at least one inlet opening (69, 71) and through at least one outlet opening ( 72) flows out of these pipes, with obstacles in these pipes to limit the flow through the pipes en amount of coolant are provided. 2. Reactor core according to claim 1, characterized in that the fuel rods are divided into groups (9), each of which, in a prism-shaped box (8) e ^; ngeset- forms a grid component, the walls (8, 29) of which run on or in the vicinity of not completely occupied grid lines (14-15, 15-10, 10-11, 12-13, 13-14) , with the volume ratio is from gap material to moderator material for the central fuel rods is just as large or larger than for the edge fuel rods of the grid components. 3. reactor core according to claim 1 or 2, characterized in that at least one part of the tubes filled with coolant are designed as guide tubes (31), each of which a rod (57) which is arranged displaceably in the longitudinal direction and made of a material exists, which affects the local neutron flux. 4. reactor core according to claim 2, characterized in that each corner point of the lattice components (8) is occupied by a fuel rod (1). 50