JPH0450795A - Fuel assembly - Google Patents

Abstract

PURPOSE:To reduce the cost of production and to increase the Pu charge quantity per fuel assembly by disposing one or three pieces of uranium U fuel rods without contg. plutonium Pu in the corner parts facing control rods in the fuel assembly. CONSTITUTION:One or three pieces of the fuel rods U loaded with the pellets contg. UO2 and without contg. PuO2 are disposed in the corner parts facing the control rods 11 in the fresh fuel assembly 12 of 0Gwd/t burnup. The fuel rods (the degree of Pu enrichment is higher as the number is smaller) contg. the MOX (uranium/plutonium mixed oxide) loaded with the pellets formed by mixing the UO2 and the PuO2 are usable for the fuel rods 1 to 4 exclusive of the fuel rods G contg. the UO2 and Gd2O3 in this way and, therefore, the charge quantity of the MOX fuel is increased. Since the kinds of the degree of the Pu enrichment in the MOX fuel assembly are decreased, the cost of producing the fuel assemblies is reduced.

Description

Detailed Description of the Invention [Field of Industrial Application] The present invention relates to a fuel assembly used in a boiling water nuclear reactor, particularly a uranium-plutonium mixed oxide fuel assembly (hereinafter referred to as M
(referred to as OX fuel assembly).

[Conventional technology]

The structure of the fuel assembly used in boiling water reactors is described in the 13th
As shown in the figure. In this figure, 4 is an upper tie plate, 5 is a channel fastener, 5 is a channel box, 8 is a spacer, 9 is a lower tie plate, and 10 is a fuel rod.

Among the fuel assemblies used in boiling water reactors, those with a shape called D lattice have different gap distances between adjacent fuel assemblies, as shown in the cross-sectional view of the fuel assembly in Figure 14. Gap distance on the rod side (Dl in Fig. 14,
The gap interval (hereinafter referred to as wide gap) is wider than the gap interval on the side without the control rod (hereinafter referred to as narrow gap from Dz in FIG. 12). Therefore, on the wide gap side, the area of the moderator flow path outside the channel box 13 is large, and the effect of moderating neutrons is large.

As a result, the output of each fuel rod 14 in the fuel assembly 12 is
It tends to be higher on the wide gap side and lower on the narrower gap side.

Examples of plutonium and uranium enrichment distributions of uranium-plutonium mixed oxide fuel assemblies (MOX fuel assemblies) for conventional boiling water reactors are shown in FIGS. 11 and 12.

In both of the plutonium and uranium enrichment distribution examples shown here, the enrichment is determined so that the heat distribution of the fuel rods 14 in the fuel assembly becomes flat when the fuel assembly 12 is loaded into the D-lattice reactor core. It has a distribution.

To determine the enrichment distribution of plutonium and uranium, gadolinia (
All fuel rods other than fuel rods containing gadolinia (GdzOs) contain plutonium, and fuel rods other than fuel rods containing gadolinia (GdzOs), especially those located around the new fuel assembly, do not use plutonium and contain only uranium. There is a square method of adopting fissile material as fissile material.

The former is called a discrete distribution, and the latter is called an island distribution. In the discrete type distribution, the amount of plutonium loaded per new fuel assembly can be increased, but on the other hand, many types of plutonium enrichment are required. Also, the island type allows for fewer types of plutonium enrichment than the discrete type, but at the cost of this, the amount of plutonium loaded per new fuel assembly is reduced.

FIG. 11 shows an example of plutonium and uranium enrichment distribution in a discrete MOX fuel assembly.

In FIG. 11, 11 indicates a control rod, and 12 indicates a fuel assembly. The fuel assembly 12 is a channel box 1
3. It consists of a fuel rod 14 and a water rod 15. Among the fuel rods 14, those marked P1 to P6 are fuel rods in which uranium contains imaged plutonium (
(hereinafter referred to as plutonium fuel rods), and the smaller the subscript number, the more plutonium it contains. Similarly, those marked with G indicate fuel rods containing gadolinia (Gd208) in uranium fuel rods.

FIG. 12 shows an example of plutonium and uranium enrichment distribution in an island-type MOX fuel assembly. 1st
In the fuel rods 14 in Figure 0, those with numbers 1 to 4 indicate uranium fuel rods, and the smaller the number, the higher the enrichment of uranium. Similarly, Pl
, Pl indicate plutonium fuel rods, and Pl contains more plutonium than Pl.

Moreover, those marked with G indicate fuel rods made of uranium fuel rods containing gadolinia.

In order to solve the problems of discrete and island type MOX fuel assemblies, Japanese Patent Application Laid-Open No. 62-24183 discloses that at least one uranium fuel rod is attached to each corner of the fuel assembly of a pressurized wooden reactor. A fuel assembly has been devised in which low-enrichment plutonium fuel rods are arranged in the outermost row excluding the uranium fuel rods, and high-enrichment plutonium fuel rods are arranged in other locations.

On the other hand, the spacing between fuel assemblies loaded in a D-lattice shape in a boiling water reactor is wide on the side facing the control rods and narrow on the side not facing the control rods. On the wide gap side, the neutron spectrum is softer than on the narrow gap side, so the power peaking of the fuel rod tends to be higher.

JP-A No. 62-24183 aims to suppress power peaking within the fuel assembly by using fewer kinds of enriched fuel rods, but in a boiling water reactor, the fuel assembly Due to the uneven spacing between
It tends to distort the power distribution.

[Problem to be solved by the invention]

The present invention provides a fuel assembly that overcomes the problems of conventional plutonium and uranium mixed oxide fuels, ie, discrete type fuels and island type fuels, as described above.

Conventional plutonium-uranium mixed oxide fuels have a large variety of plutonium enrichments in discrete fuels, making production costs significantly higher. This is because in the production of MOX fuel assemblies, equipment is required to prevent internal exposure of the human body to alpha rays emitted by plutonium, and to suppress gamma rays and neutron rays released due to decay, etc. It is. Plutonium-containing fuel rods manufactured using such equipment need to be internally cleaned for each different enrichment level before being moved to production for a different enrichment level, but the more steps like this, the more difficult it is to manufacture the fuel rods. This is because it increases costs. The present invention is directed to such M
The object of the present invention is to provide an MOX fuel assembly that can reduce the manufacturing cost of the OX fuel assembly and utilize more Pu.

[Means to solve the problem]

In order to solve the above-mentioned problems, the present invention has developed an MOX fuel assembly in which the neutron spectrum is noticeably softer than in other fuel assemblies, and in order to suppress local power peaking, the plutonium enrichment must be extremely reduced. This method loads enriched uranium without enriching plutonium with respect to one or three corner fuel rods facing the control rods in the fuel assembly. In this way, by making only one fuel rod at the corner facing the control rod a uranium rod, the number of plutonium enrichment types is reduced, which reduces the complexity in manufacturing the MOX fuel assembly mentioned above, and significantly reduces manufacturing costs. On the other hand, by reducing the number of uranium rods to one or three, excluding the gadolinia-containing fuel rods among the fuel rods in the fuel assembly, the amount of plutonium loaded per fuel assembly can be maintained at approximately the maximum. From the viewpoint of plutonium utilization, it is desirable for MOX fuel assemblies to have a large amount of plutonium loaded per fuel assembly, but as in the present invention, only one or three uranium fuel rods containing no gadolinia are used per fuel assembly. This allows for maximum plutonium per fuel assembly to be maintained while reducing manufacturing costs. In order to improve the softening of the neutron spectrum caused by plutonium, the water rods in the MOX fuel assembly should be placed farther away from the uranium rods loaded in the corners facing the control rods. This is because the corners of the fuel assembly facing the control rods are loaded with uranium rods, softening the neutron spectrum, so the water rods that cause the softening of the neutron spectrum should be moved away from this corner.
It is desirable to make the distribution of the neutron spectrum within the fuel assembly more uniform.

[Effect]

Uranium has a smaller nuclear fission cross section and thermal neutron absorption cross section than plutonium, so power peaking does not occur in uranium fuel rods loaded into a fuel assembly mainly composed of plutonium fuel rods. In addition, the neutron spectrum is softened near the uranium fuel rod.

〔Example〕 Examples of the present invention will be explained below.

FIG. 1 shows a first embodiment of the invention. In Figure 1, 1
1 represents a control rod, and 12 represents a fuel assembly. The fuel assembly 12 includes a channel box 13, fuel rods 14. It is composed of a water rod 15. The fuel assembly 12 is a new fuel assembly (burnup OG w d / t),
The fuel rods 14 are loaded with pellets of any one of the following: pellets made of plutonium and uranium oxide, pellets made of uranium oxide mixed with gadolinia, or pellets of uranium oxide (UOz) not mixed with plutonium and gadolinia. be done. In the fuel assembly shown in FIG. 1, among the fuel rods arranged in a square grid of 8 rows and 8 columns, control rods 1
One fuel rod located at the corner facing the channel fastener, that is, the corner where the channel fastener is attached, is filled with pellets containing uranium but not plutonium and gadolinia.

One of the four corners of the upper end of the channel box of the fuel assembly of a boiling water reactor has a first
As shown in FIG. 1, a channel fastener 15 is provided. The channel fastener is attached to the corner portion facing the control rod at the upper end of the channel box, that is, the first
It is provided at the corner part A of the fuel assembly in Figure 2. The four fuel assemblies surrounding the control rods loaded in a boiling water reactor maintain the necessary spacing between the fuel assemblies for control rod insertion by having their channel fasteners contact each other at the upper end of the channel box. . Therefore, a channel fastener is provided at the upper end of the corner portion facing the control rod of the fuel assembly of the boiling water reactor.

Figure 1 shows a new fuel assembly (burnup oa
This is an example in which one fuel rod loaded with pellets containing uranium oxide (UOz) but not plutonium oxide (PuOz) is placed in the corner part where the channel fastener is provided in the fuel cell (wd/l).

Among the fuel rods 14, those marked with numbers 1 to 4 indicate plutonium-enriched fuel rods (fuel rods containing pellets formed of uranium-plutonium mixed oxide),
The lower the number, the higher the plutonium enrichment. Also, items marked with a U indicate uranium fuel rods that are not mixed with plutonium or gadolinia.
Items marked with indicate fuel rods containing gadolinia in uranium fuel rods. FIG. 2 shows another embodiment, in which two fuel rods adjacent to the fuel rod U located at the corner where the channel fastener is provided in FIG. 1 are also fuel rods U. The fuel assembly shown in FIGS. 3 and 4 has the fuel rod arrangement of the fuel assembly shown in FIGS. 1 and 2 arranged in 9 rows and 9 columns.

In all of these embodiments, only one or three of the corner portions where channel fasteners are provided are fuel rods U, and fuel rods 1 to 4 other than fuel rod G are all MOX-containing fuel rods, so the amount of MOX fuel loaded can be reduced. Can be many.

Furthermore, the types of plutonium enrichment within the MOX fuel assembly can be reduced from six types in the conventional discrete distribution to four types.

Other embodiments of the present invention are shown in FIGS. 5 to 10.

In Figures 5 to 10, one or three rods located at the corner where the channel fastener is provided are fuel rods U, but the others are MOX-containing fuel rods or uranium dioxide (UOZ) and gadolinia (GdzOa). ) is a fuel rod containing The arrangement of the water rods 15 differs from the previous case. That is, FIGS. 5 to 10 are characterized in that the water rods are arranged away from the corner portion where the channel fastener is provided. This is because the fuel rods U are arranged near the corner where the channel fastener is provided, so the neutron spectrum is softer than near the other fuel rods. As a result,
The water rod has the role of softening the neutron spectrum, but it is more desirable to place it near the corner where the channel fastener is provided rather than near the corner.

Figures 5 and 6 show examples of an 8x8 arrangement in which uranium fuel rods and water rods are arranged based on this idea, and Figures 7 to 10 show examples of a 9x9 arrangement.

In the embodiments shown in FIGS. 5, 7 and 8, M
There are three types of plutonium enrichment in the OX fuel assembly, and furthermore, Fig. 6, Fig. 9, and Fig. 10 a
In the example shown in b), by arranging eight uranium fuel rods made only of uranium dioxide (UOZ), the types of plutonium enrichment in the MOX fuel assembly are reduced to two types.b) Ru. The types of plutonium enrichment are more reduced than in the embodiments shown in FIGS. 1 to 4.

〔Effect of the invention〕

Since the fuel assembly of the present invention can reduce the type of plutonium enrichment in the MOX fuel assembly, the manufacturing cost of the fuel assembly can be reduced, and the amount of plutonium loaded per fuel assembly can be increased. , it is possible to save uranium resources.

[Brief explanation of the drawing]

Figures 1 to 10 are cross-sectional views of a MOX fuel assembly according to an embodiment of the present invention, Figures 11 and 12 are cross-sectional views of a conventional MOX fuel assembly, and Figure 13 is a cross-sectional view of a fuel assembly. FIG. 14 is a partially cutaway perspective view of the fuel assembly, and FIG. 14 is a cross-sectional view of the fuel assembly. 4... Upper tie plate, 5... Channel fastener, 8... Spacer, 9... Lower tie plate,
11...Control rod, 12...Fuel assembly, 13...Channel Chestnut I Diagram 20 One Waetsuro/To rate 6 Diagram 14 Diagram D Runmo X, 1. Pu 11 sunogi 艷buyayama pλ cooking ~ ~ 1. ~' Yap Satoru on the Bu side

Claims (1)

[Claims] 1. A fuel rod enriched with plutonium in a fuel assembly in which fuel rods are arranged in a square lattice in a substantially square channel box and a channel fastener is provided at one corner of the upper end of the channel box. A fuel assembly comprising: a plutonium-free gadolinia fuel rod; one or three plutonium-free uranium fuel rods disposed at a corner portion where the fastener is provided; and a water rod. 2. The fuel assembly according to claim 1, wherein the water rod is arranged away from the corner portion of the channel box and close to a corner portion diagonal to the corner portion.