JPH058398B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a fuel assembly, and more particularly to a fuel assembly comprising plutonium-enriched fuel rods.

[Technical Background of the Invention] FIG. 1 is a perspective view showing a conventional fuel assembly. This fuel assembly includes a plurality of fuel rods 1a filled with a large number of fuel pellets (not shown), a rectangular channel box 2a in which the fuel rods 1a are arranged, and a handle 3a on the top of the channel box 2a. upper tie plate 3b having
and a lower tie plate 4a provided on the core support in the channel box lower part 2a.
It is composed of Spacers 5a are provided at several locations in the axial direction of the regularly arranged bundle of fuel rods 1a to maintain gaps between each fuel rod and the channel box.

FIG. 2 is a cross-sectional view showing the arrangement of fuel rods in a conventional fuel assembly constructed as described above, and this fuel assembly is constructed of fuel rods made only of enriched uranium.

That is, in the figure, numeral 1 is the highest enrichment fuel rod, numeral 2 is the high enrichment fuel rod, numerals 3 to 5 are the intermediate enrichment fuel rods, numeral 6 is the low enrichment fuel rod, and numeral 7 is the high enrichment fuel rod.
is the lowest enrichment fuel rod, code 8 is the water rod,
Code 9 indicates that the concentration of gadolinia, a burnable poison, is 1.
For fuel rods with ~8% gadolinia, these total
64 bottles are arranged as shown. In addition, in the figure, the reference numeral 10a indicates a control rod.

FIG. 3 is a cross-sectional view showing the arrangement of fuel rods in a conventional fuel assembly consisting of plutonium-enriched fuel rods. In the figure, reference numeral 11 indicates the highest plutonium-enriched fuel rod, and reference numeral 12 indicates the plutonium-rich fuel rod. 13 and 14 are plutonium intermediate enriched fuel rods, 15 is a plutonium low enrichment fuel rod, and 16 is a plutonium minimum enriched fuel rod, 17
shows a plutonium-enriched gadolinia fuel rod.

As is clear from FIG. 3, in general, plutonium-enriched fuel rods have a lower fuel assembly than the fuel rods made of enriched uranium, which is not plutonium-enriched, as shown in FIG. The number of gadolinia fuel rods indicated by reference numeral 17 is increasing.

That is, generally with plutonium-enriched fuel,
Due to its hard neutron spectrum compared to _UO2 fuel,
The value of gadolinia is quite different from that of UO ₂ fuel, and the neutron absorption cross section of gadolinia is large for thermal group neutron energy and small for extrathermal energy, so when the neutron spectrum becomes hard, the reactivity value of gadolinia decreases. At the same time, the burning rate of gadolinia slows down. Therefore, in order to perform reactivity control using gadolinia in the same way as UO ₂ fuel, it is necessary to reduce the gadolinia concentration and increase the number of fuel rods containing gadolinia.

Therefore, for example, while the gadolinia of the UO ₂ fuel shown in Fig. 2 is 3w/o x 8, the plutonium-enriched fuel rod shown in Fig. 3 is 1.5w/o.
It is said that there are 11 pieces.

Figure 4 shows the relationship between the burnup and infinite multiplication factor of the fuel assembly made of enriched uranium fuel shown in the second map. In the figure, the horizontal axis represents the burnup and the vertical axis represents the infinite multiplication factor. The curve a shown by the broken line in the figure represents the infinite multiplication factor when gadolinia, which is a burnable poison, is not loaded, and the curve b shown by the solid line
shows the infinite multiplication factor of the fuel assembly constructed as shown in FIG.

Then, place 1/4 of the fuel assembly shown in Figure 2 in the core.
The average infinite multiplication factor of the core at the end of the cycle in the equilibrium core when the core is loaded one by one is at points A, B, and B shown in Figure 4.
It can be determined as the average value of the infinite multiplication factors of C and D, and here it is approximately 1.05.

Figure 5 shows the relationship between the infinite multiplication factor and burnup change during operation of the fuel assembly made of plutonium-enriched fuel rods shown in Figure 3. In the figure, the horizontal axis represents the burnup, and the vertical axis represents the burnup. An infinite multiplication factor is taken for , and the curve c shown by a broken line in the figure shows the change in the infinite multiplication factor when gadolinia is not loaded, and the curve d shown by a solid line shows the change in the infinite multiplication factor when no gadolinia is loaded. It shows the change in the infinite multiplication factor of the aggregate. Here, the core average infinite multiplication factor at the end of the cycle of an equilibrium reactor with 1/4 of the fuel assemblies loaded in the core when gadolinia is not loaded is shown by the broken line. It can be determined as the average value of the multiplication factors, and this value is 1.05, which is the same as the value of the fuel assembly shown in FIG. 2 mentioned above.

In other words, this shows that if we assume conventional plutonium-enriched fuel rods that are not loaded with gadolinia, we can obtain the same incremental cycle burnup as the fuel assembly shown in Figure 2. .

[Problems with the Background Art] However, in general, in a fuel assembly as shown in Fig. 3, the combustion of gadolinia is actually slow, so that the curve d shown by the solid line in Fig. 5 changes, and the point line changes. The cycle incremental burn-up of the plutonium-enriched fuel rod shown in Figure 3 is smaller than that of the fuel assembly shown in Figure 2 by the difference in the infinite multiplication factors between points N, E, and H. This results in a negative fuel economy.

In other words, with the conventional plutonium-enriched fuel assembly shown in Figure 3, it is not possible to completely recover from the gadolinia combustion delay, as shown in Figure 5, and the fuel assembly consisting of UO ₂ fuel cannot be used. It is difficult to avoid being at a financial disadvantage compared to the body.

In addition, in such a fuel assembly, the local power distribution within the bundle is distorted by increasing the number of gadolinia. It is necessary to flatten the local power distribution by using six types of plutonium fuel rods with different enrichments.

Curve e shown in Figure 6 shows the relationship between the local power peaking and burnup of a fuel assembly consisting of fuel rods with six different plutonium enrichment levels shown in Figure 3, and the horizontal axis shows the burnup. The vertical axis shows the local output peaking coefficient. As is clear from the figure, in such a fuel assembly, the initial stage of combustion (0
~5Gwd/st), the local power peaking decreases monotonically, but after the middle stage of combustion, the power of the highly enriched plutonium fuel rods in the center of the bundle increases, and the local power peaking tends to increase. It's not a healthy idea.

In other words, since the number of gadolinia fuel rods is increased, it is necessary to reduce the plutonium enrichment of the fuel rods on the outer periphery of the bundle in order to reduce the distortion of the initial local power distribution, and at the stage where gadolinia combustion has progressed, the heat This is because neutrons easily enter the center of the bundle, and the specific output of the highly enriched plutonium fuel rods at the center of the bundle relative to the outer fuel rods increases.

[Object of the Invention] The present invention has been made in response to such conventional squaring problem, and can eliminate the combustion delay of gadolinia, improve fuel economy, and reduce local power peaking within the bundle throughout the entire combustion period. The purpose is to provide a fuel assembly that improves the soundness of the fuel by suppressing the amount of fuel.

[Summary of the Invention] That is, the present invention provides a fuel assembly in which a plurality of fuel rods enriched with plutonium are arranged in a rectangular shape, and the fuel rods located at the corners of the fuel assembly contain plutonium. This is a fuel assembly characterized in that fuel rods made of natural uranium, depleted uranium, or low enriched uranium and enriched with plutonium are arranged up to the outer periphery of the fuel assembly.

[Embodiment of the Invention] The details of the present invention will be described below with reference to an embodiment shown in the drawings.

FIG. 7 shows a cross section of a fuel assembly according to an embodiment of the present invention, in which reference numeral 18 indicates a high plutonium enrichment fuel rod, 19 indicates a plutonium low enrichment fuel rod,
Code 20 is the plutonium least enriched fuel rod, code 2
1 shows a fuel rod that contains 3w/o gadolinia in natural uranium and does not contain plutonium.

That is, in this fuel assembly, the types of plutonium fuel rods are reduced from six types in the conventional fuel assembly shown in FIG. 3 to three types. Further, the total amount of plutonium used in this fuel assembly is the same as the total amount of plutonium in the fuel assembly shown in FIG.

The curve f shown in Figure 8 shows the relationship between the infinite multiplication factor and burnup during operation of a fuel assembly configured in this way, with the horizontal axis representing the burnup and the vertical axis representing the infinite multiplication factor. is taken. As is clear from the 8th map, in the fuel assembly configured as shown in Fig. 7, the value of gadolinia is reduced compared to the conventional one by arranging the gadolinia fuel rods at the corners of the fuel assembly in the early stage of combustion. The value can be the same as the value of the 11 gadolinia-containing fuel rods shown in Figure 3.

In addition, at the stage where the combustion of gadolinia has progressed, placing gadolinia at the corners of the fuel assembly facilitates the penetration of thermal neutrons into the center of the bundle. It can be larger than the fuel assembly.

Therefore, in the fuel assembly configured in this manner, the cycle incremental burnup can be significantly increased compared to the conventional fuel assembly shown in FIG. 3, and fuel economy can be improved.

Curve g shown in Figure 9 shows the relationship between local power peaking and burnup during operation of the fuel assembly configured as shown in Figure 7, where the horizontal axis represents the burnup and the vertical axis represents the burnup. is the local output peaking coefficient.

That is, at the initial stage of combustion, the fuel assembly is almost the same as the conventional fuel assembly using six types of fuel rods shown in FIG. 3, but as combustion progresses, the local power peaking tends to monotonically decrease. This means that the local power can be kept low at high burnup points when the strength of the fuel cladding decreases, and in such a fuel assembly, fuel integrity can be significantly improved.

FIG. 10 shows another embodiment of the present invention, in which a corner 11a adjacent to the control rod 10 and a corner 12a in a diagonal direction are provided with reference numerals 21 on both sides of the fuel rod 13a.
A fuel rod containing 3 w/o gadolinia in natural uranium and containing no plutonium 14
The fuel assembly has the same structure as the fuel assembly shown in Fig. 7, except that the fuel rods a and 15a are arranged and the plutonium enrichment in the other fuel rods arranged at the outermost periphery is partially different. ing.

The fuel assembly configured in this way is, for example,
It is used when the surplus reactivity at the beginning of the cycle becomes abnormally large due to changes in the operation plan, etc.

That is, in the conventional fuel assembly shown in FIG. 3, it is necessary to add 6 to 7 gadolinia fuel rods to reduce the infinite multiplication factor of about 5% Δk at the initial stage of combustion, but according to the present invention, it is necessary to add 6 to 7 gadolinia fuel rods. As shown in FIG. 10, two gadolinia fuel rods 14a, 15a
This can be achieved by adding .

The relationship between the infinite multiplication factor and the burnup of the fuel assembly shown in Figure 10 is the same for the initial stage of combustion (0 to 7 Gwd/st).
This fuel assembly is the same as the fuel assembly shown in FIG. 7 except for the following, and it is possible to obtain substantially the same fuel economy as the fuel assembly shown in FIG. In addition, the relationship between the local power peaking of the bundle and burnup is approximately 5% worse at the early stage of combustion compared to the fuel assembly shown in Figure 7, but this difference decreases as combustion progresses, and at the end of combustion, It is almost equivalent to that of the fuel assembly shown in FIG.

[Effects of the Invention] As described above, according to the fuel assembly of the present invention, the value of each gadolinia can be increased,
It is now possible to make a fuel assembly made of UO ₂ fuel have the same combustion characteristics as a gadolinia fuel rod.
Further, it is possible to eliminate the decrease in cycle incremental burnup due to the combustion delay of gadolinia, and it is possible to provide an economically efficient fuel assembly.

Furthermore, the number of types of fuel rods with different plutonium enrichment levels can be reduced, making it easier to manufacture fuel assemblies and reducing manufacturing costs.

[Brief explanation of the drawing]

Figure 1 is an external view of a conventional fuel assembly;
The figure is a cross-sectional view of a conventional fuel assembly made only of enriched uranium. Figure 3 is a cross-sectional view of a conventional fuel assembly made of plutonium-enriched fuel rods.
Figure 5 is a graph showing the relationship between the infinite multiplication factor and burnup during operation of the fuel assembly shown in Figure 5, and Figure 5 shows the relationship between the infinite multiplication rate and burnup during operation of the fuel assembly shown in Figure 3. Graph, FIG. 6 is a graph showing the relationship between local power peaking and burnup during operation of the fuel assembly shown in FIG. 3, and FIG. 7 is a cross-sectional view showing the fuel assembly of one embodiment of the present invention. , FIG. 8 is a graph showing the infinite multiplication factor during operation of the fuel assembly shown in FIG. 7, and FIG. 9 is a graph showing the relationship between local power peaking and burnup of the fuel assembly shown in FIG. 7. , 1st
FIG. 0 is a cross-sectional view showing a fuel assembly according to another embodiment of the present invention. 1a... fuel rod, 2a... channel box, 10a... control rod.

Claims (1)

[Scope of Claims] 1. In a fuel assembly in which a plurality of fuel rods enriched with plutonium are arranged in a square shape, the fuel rods located at the corners of the fuel assembly do not contain plutonium and are made of natural uranium. Or, a fuel assembly characterized in that fuel rods made of depleted uranium or low enriched uranium and enriched with plutonium are arranged up to the outer periphery of the fuel assembly. 2. The fuel assembly according to claim 1, wherein a burnable poison for reactivity control is added to the fuel rods located at the corners of the fuel assembly.