JPS6383689A - Fuel aggregate - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a fuel assembly, and particularly to a fuel assembly suitable for use in a light water nuclear reactor.

[Conventional technology]

As the proportion of nuclear power generation increases, the amount of recovered uranium generated through reprocessing of spent fuel is becoming increasingly important.

The difference between natural uranium and enriched uranium is that
Recovered uranium contains artificial isotopes formed during irradiation in nuclear reactors. Among these, particularly important nuclides are U-236 and U-232. That is, U-
236 has a large neutron absorption cross section, and reactivity loss must be taken into consideration. In addition, since U-232's daughter nuclides B1-212 and TΩ-208 emit high-energy γ-rays, consideration must be given to handling precautions.

As an example of how to use recovered uranium, see JP-A-60
-146183 publication etc. are mentioned.

[Problem that the invention seeks to solve]

As mentioned above, there are two problems in using recovered uranium: loss of reactivity and increase in dose rate. Although these effects are small when recovered uranium is used experimentally in a small number of fuel assemblies, if the amount of recovered uranium to be generated increases in the future and a large amount of recovered uranium is to be used, it will be necessary to sufficiently address the two problems mentioned above. It is necessary to take appropriate measures.

In view of the above circumstances, an object of the present invention is to provide a fuel assembly that can effectively utilize recovered uranium and can be used in large quantities.

[Means for solving problems]

The above object is achieved by using recovered uranium obtained by reprocessing spent fuel for the nuclear fuel pellets containing gadolinia in a fuel assembly consisting of a plurality of fuel rods loaded with nuclear fuel pellets.

[Effect]

Fuel rods loaded with nuclear fuel pellets containing gadolinia have a large neutron absorption cross section, but due to the effect of gadolinia,
The output is lower than that of other fuel rods loaded with uranium-only nuclear fuel pellets. Therefore, even if recovered uranium is used in nuclear fuel pellet fuel rods containing gadolinia,
The effect of reactivity loss specific to recovered uranium is smaller than when recovered uranium is used in other uranium-only nuclear fuel pellet fuel rods.Furthermore, the effect of reactivity loss can be further reduced by adjusting the gadolinia concentration. is also possible.

Furthermore, in the forming process, the gadolinia-containing nuclear fuel pellet production line has conventionally been separated from the normal uranium-only nuclear fuel pellet production line. Therefore, there is an advantage that it is easy to take measures to prevent an increase in the dose rate or to prevent mixing of recovered uranium and ordinary uranium.

〔Example〕

The present invention will be explained in detail below with reference to the embodiment shown in FIG.

FIG. 1 is a cross-sectional view showing one embodiment of the fuel assembly of the present invention, which is used in a boiling water nuclear reactor. In Figure 1, 1 is a fuel rod, 1a is a uranium nuclear fuel pellet fuel rod, 1b is a (gadolinia + recovered uranium) nuclear fuel pellet fuel rod, 2 is a water rod, 3 is a control rod, and 4 is a channel box. .

Usually, about 5 to 10 gadolinia-containing nuclear fuel pellet fuel rods are used in a fuel assembly for a boiling water reactor. In the embodiment shown in FIG. 1, seven nuclear fuel pellet fuel rods containing gadolinia are arranged, and the pellets of these fuel rods are mixed nuclear fuel pellets of gadolinia and recovered uranium.

Nuclear fuel pellet fuel rods containing gadolinia are used for reactivity compensation and flattening of power distribution during the operation cycle, and due to the large neutron absorption cross section of gadolinia, the output is lower than that of uranium nuclear fuel pellet fuel rods. It can be suppressed. Therefore, even with respect to recovered uranium, which has the problem of reactivity loss due to U-236, the effect of reactivity loss is reduced when used in gadolinia-filled nuclear fuel pellet fuel rods than when used in uranium nuclear fuel pellet fuel rods. Can be done. In addition, if the number of fuel assemblies using recovered uranium is small, the effect of reactivity loss due to U-236 mentioned above can be ignored, but if the majority of the core is occupied by fuel assemblies using recovered uranium, or If the amount of U-236 in the recovered uranium is particularly large due to the characteristics of the spent fuel, etc., compensation for reactivity loss may be required. In this case, it is generally considered to increase the concentration of U-235 more than usual, but this method requires adjustment during the concentration process, so it is not a very preferable method from the viewpoint of work efficiency and economy. .

On the other hand, when recovered uranium is used in gadolinia-containing nuclear fuel pellet fuel rods as in the embodiments of the present invention, reactivity compensation can be achieved by lowering the gadolinia concentration from normal. This method can be easily implemented in the molding process.

This method is superior in terms of work efficiency and economy compared to the U-235 enrichment adjustment method described above.

Furthermore, this embodiment has an advantage in dealing with the problem of increased dose rate due to recovered uranium. As aforementioned.

The recovered uranium contains a trace amount of U-232.

Daughter nuclides B1-212 and 'I' produced by its decay
m-208 emits high-energy gamma rays.

Therefore, in the forming process, it is considered necessary to take measures such as applying shielding to control exposure and preventing mixing with ordinary uranium.

In this embodiment, since recovered uranium is used in the gadolinia-filled nuclear fuel pellet fuel rod, these measures are extremely easy to implement. In other words, 1.Normally, the production line for nuclear fuel pellet fuel rods containing gadolinia is separated from the production line for uranium nuclear fuel pellet fuel rods, so there are already countermeasures for mixing recovered uranium and regular uranium, and there are also countermeasures. It is possible to implement it intensively and efficiently.

Also, nuclear fuel pellet fuel rods containing gadolinia.

Because they are usually located inside the fuel assembly, the blocking effect of the outer uranium nuclear fuel pellet fuel rods
There is also the advantage that the dose rate after fM material assembly assembly can be kept low.

〔Effect of the invention〕

As explained above, according to the present invention, problems inherent to recovered uranium, such as U-236 reactivity loss and U-232
The effect of increasing the dose rate due to the daughter nuclides of the uranium can be reduced, the uranium recovered can be used effectively, and the uranium can be used in large quantities.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view showing one embodiment of the fuel assembly of the present invention. DESCRIPTION OF SYMBOLS 1...Fuel rod, 1a...Uranium nuclear fuel pellet fuel rod, 1b...(Gadolinia ten recovered uranium) nuclear fuel pellet fuel rod, 2...Water rod, 4...Channel box.

Claims (1)

[Claims] 1. A fuel assembly consisting of a plurality of fuel rods loaded with nuclear fuel pellets, characterized in that the nuclear fuel pellets containing gadolinia are made of recovered uranium obtained by reprocessing spent fuel. body.