JPH1090460A - Fuel assembly - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the fuel design flexibility and fuel economy of a MOX (mixed oxide) fuel assembly by eliminating the cinder of a burnable poison in the last stage of an operation cycle by reducing the kinds of degrees of Pu(plutonium) enrichment in the fuel assembly and increasing the charging amount of Pu and, at the same time, flattening the output distribution of a reactor core in the height direction. SOLUTION: Fuel rods Gi which contain a burnable poison in their axial centers which are surrounded by a material containing no burnable poison are arranged in the outermost peripheral area of a fuel assembly. The diameters of the fuel rods Gi containing the burnable poison are made larger in the order of G1, G2, and G4 and the diameter of the upper half sections of the fuel rods G3 are made equal to that of the rods G2 that of the lower half sections of the rods G3 are made to that of the rods G4. The rods G3 are also arranged to the positions facing water rods. In the other area of the fuel assembly, fuel rods M containing no burnable poison are arranged.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel assembly used in a nuclear reactor, and more particularly to a boiling water reactor loaded with a large number of fuel rods made of a mixed oxide of uranium dioxide and plutonium dioxide. Fuel assemblies.

[0002]

2. Description of the Related Art A nuclear fuel assembly used in a boiling water reactor has basically used uranium as a nuclear fuel material. That is, uranium oxide (UO ₂ ) is molded into a cylindrical shape, and pellets obtained by sintering are produced in a zirconium alloy cladding tube to produce uranium fuel rods. It is an aggregate. In the fuel assembly, a coolant flow path is provided outside the fuel rod. FIG. 12A is a longitudinal sectional view of a fuel assembly of a conventional boiling water reactor, and FIG. 12B is a sectional view taken along line AA of FIG. 12A. In the fuel assembly 9, the fuel rods 4 and the water rods 5 through which the coolant flows are bundled by a spacer 6 in a square grid of, for example, 9 rows and 9 columns, and fixed by an upper tie plate 7 and a lower tie plate 8. The fuel rod bundle is surrounded by a channel box 3 made of Zircaloy. This fuel assembly 9 has 74
It has two fuel rods 4 and two cylindrical large-diameter water rods 7.

In the boiling water reactor, a flow path of boiling water is provided between the fuel rods 4 of the fuel assembly 9. Further, a water gap through which water as a moderator flows is provided between the fuel assemblies 9, but the moderator distribution in the horizontal direction of the fuel assembly in the core is not uniform because the distribution of the moderator is not uniform. The output distribution is distorted. Therefore, by appropriately arranging several types of fuel rods 4 having different uranium enrichment or plutonium enrichment, the local power distribution is flattened.

Further, in order to suppress the excess fission chain reaction in the early stage of combustion and appropriately control the excess reactivity, some fuel rods include gadolinia (Gd ₂₎ as a burnable poison.
A neutron absorber such as O ₃ ) is added over almost the entire length. The neutron absorption effect of the burnable poisoned fuel rod decreases almost linearly as combustion proceeds. The amount of the burnable poison is set such that the amount of the burnable poison remaining at the end of the operation cycle is as small as possible from the viewpoint of fuel economy.

In some fuel rods, the burnable poison is uniformly distributed in the height direction, and the fuel rod is divided into several regions having different concentrations of the burnable poison in the height direction of the fuel assembly. The setting of several types of burnable poisons in the fuel rods will be described below.

In a boiling water reactor, during power operation, the void ratio of boiling water increases above the core, so that the moderator density is high below the core and the power distribution in the height direction of the core has a peak below the core. For this reason, Japanese Patent Publication No. 61-3759
In the invention disclosed in Japanese Patent Publication No. 1 (1993), the burnable poison is added to the entire length of the fuel rod and the burnable poison concentration in the lower half of the fuel rod is increased, or the burnable poison is added only to the lower half of the fuel rod. In addition, the distortion of the power distribution below the core is improved.

On the other hand, when the reactor is stopped, the moderator distribution is uniform in the vertical direction, so that the reactivity is high above the reactor core, contrary to the power operation. this is,
During power operation, the upper part of the core has a low output, so that the combustion is difficult to progress due to low power, and the fissile material tends to remain unburned. Further, the neutron flux spectrum is high due to the high void fraction, and the production ratio of plutonium is large. For this reason, Japanese Unexamined Patent Publication No.
In the invention disclosed in Japanese Patent No. 238784, the burnable poison is located at the position where the neutron flux distribution in the core height direction at the time of shutting down the cold and hot furnaces is the highest, specifically, in the range from the height position 19/24 to 21/24. By increasing the concentration, the reactivity of the core is suppressed and the reactor shutdown margin is improved. In addition,
Below height position k / 24 (k is a natural number from 1 to 24)
Means the position of the k-th node counted from the bottom when the fuel pellet filling region of the fuel rod is divided into 24 nodes.

In recent years, in order to improve fuel economy, uranium fuel assemblies have been promoted to have high burnup, that is, high enrichment. In parallel with this, Plutonium thermal utilization, in which plutonium obtained by reprocessing spent uranium fuel is reused in light water reactors
ization) plan is underway. This is to produce and use mixed-oxide fuel (MOX fuel) by mixing uranium dioxide (UO ₂ ) with plutonium dioxide (PuO ₂ ) recovered by reprocessing. It is.

[0009]

From the viewpoint of pull thermal utilization as described above, some recent fuel assemblies include MOX.
An MOX fuel assembly has been developed in which most of the fuel rods in the fuel assembly are MOX fuel rods to increase the loading of plutonium in the MOX fuel assembly.

In order to increase the burnup of these fuel assemblies, it is necessary to increase the uranium enrichment and plutonium enrichment of each fuel rod, and further increase the number of burnable poison-containing fuel rods to increase the surplus. It is necessary to suppress the reactivity. As a result, the degree of freedom in fuel rod arrangement is significantly restricted.

On the other hand, regarding the MOX fuel assembly,
It is also necessary to simplify the manufacturing process of the MOX fuel rod from the viewpoint of reducing the manufacturing cost. For this reason, Japanese Unexamined Patent Publication No.
In the invention disclosed in Japanese Patent Publication No. 82, the burnable poison is added only to the uranium fuel rod and not to the MOX fuel rod.

In general, since the resonance neutron absorption cross section of the plutonium 240 is particularly large in the MOX fuel assembly, the neutron flux spectrum is hard and the thermal neutron absorption ratio of gadolinia is small as compared with the uranium fuel assembly. Therefore, in the MOX fuel assembly, it is necessary to arrange more burnable poison-containing fuel rods than in the case of the uranium fuel assembly in order to suppress the excess reactivity. However, Japanese Patent Laid-Open No.
In the invention disclosed in Japanese Patent No. 8482, if the number of burnable poison-containing fuel rods is increased, the number of MOX fuel rods is reduced. Therefore, it is difficult to increase the plutonium loading.

FIG. 13 is a horizontal sectional view showing an example of a fuel rod arrangement of a conventional MOX fuel assembly 10 by a method disclosed in Japanese Patent Application Laid-Open No. 4-244994 in which gadolinia is added to uranium fuel rods. . Here, gadolinia is employed as the burnable poison. In the figure, the symbol GU represents a uranium fuel rod containing gadolinia, and the symbols M1, M2, M3.
, M4 have different plutonium enrichment MOX
The fuel rods are shown, and the lower the subscript number of the MOX fuel rod, the greater the plutonium enrichment. In this MOX fuel assembly 10, 22 gadolinia-containing uranium fuel rods GU are almost evenly arranged in a region excluding the outer peripheral portion among the 74 fuel rods 4, but this arrangement makes it difficult for gadolinia to remain. Thus, the adjacent arrangement is avoided. A fuel rod M4 is provided at the corner of the fuel assembly 10, and the fuel rod M4
The fuel rod M3 is arranged at a position adjacent to the fuel rod M3. Further, the fuel rod M2 is disposed at a position where the fuel rods M3 and M4 are not disposed at the outermost peripheral portion of the fuel assembly 10. At a position other than the outermost peripheral portion of the fuel assembly 10, a fuel rod M1 is arranged adjacent to the gadolinia-containing fuel rod GU.

When the number of gadolinia-containing fuel rods GU is further increased in this MOX fuel assembly, M
The number of OX fuel rods is reduced and the plutonium loading per fuel assembly is reduced. In this case, the gadolinia-containing fuel rods GU are arranged adjacent to each other, so that the neutron absorption effect per fuel rod is reduced, and the gadolinia residue after combustion increases. Therefore, it is difficult at present to arrange more gadolinia-containing fuel rods GU than the case shown in FIG. 13 with respect to the design of a high burn-up fuel assembly with an increased plutonium enrichment.

The present invention has been made in view of the above problems, and provides a fuel assembly having excellent flexibility in fuel design and excellent fuel economy while reducing manufacturing costs by appropriately controlling the reactivity of a reactor core. In addition to eliminating burnable poisons remaining at the end of the operation cycle, it is used for boiling water reactors with a large thermal margin and a sufficiently large amount of plutonium per fuel assembly, with flattened power distribution distortion. It is an object to provide a fuel assembly that can be used.

[0016]

In order to achieve the above object, the present invention provides a first fuel rod containing a fissile material and a burnable poison, and a second fuel rod containing a fissile material and containing no burnable poison. In a fuel assembly configured by bundling a fuel rod and a water rod through which a coolant flows inside in a lattice shape,
A first fuel rod is disposed in at least a part of a position facing a water rod of the fuel assembly or an outermost peripheral region of the fuel assembly, and an axial center portion of the first fuel rod contains a burnable poison. And a region excluding the axial portion of the first fuel rod, the fissionable material not containing a burnable poison.

With this configuration, the position where the thermal neutron flux is high,
That is, by arranging a large number of the first fuel rods in the outermost peripheral region of the fuel assembly or at a position facing the water rod, the neutron absorption effect of the burnable poison of the first fuel rods is enhanced. Further, the first fuel rod disposed at a position facing the water rod suppresses an increase in neutron flux due to an increase in the moderator density around the water rod when the cooling / heating furnace is stopped, thereby ensuring a sufficient furnace stop margin.

Further, the burnable poison contained in the first fuel rod is gadolinia. Further, the fissile material contained in the first fuel rod and the second fuel rod is a mixed oxide (MOX) of uranium dioxide and plutonium dioxide.

Thus, the use of the pull thermal described above is promoted by applying the present invention to the MOX fuel assembly. Further, the base material of the burnable poison located at the axial center portion of the first fuel rod is uranium dioxide or a porous ceramic having a small neutron absorption cross-sectional area. Thereby, by first molding the region excluding the axial portion of the fuel pellets, manufacturing the hollow pellets, and then molding the axial portion containing the burnable poison, the fuel rod containing the burnable poison is not directly manufactured, The manufacturing cost can be reduced, and contamination of the manufacturing equipment due to the burnable poison can be eliminated as much as possible.

Further, the first fuel rod is divided into an upper region and a lower region except for upper and lower ends, and a third fuel rod having a uniform concentration of burnable poison in the upper region and the lower region; The fourth fuel rod is configured so as to be composed of a fourth fuel rod having a lower concentration of the poison in the lower region than in the upper region, and the first fuel rod disposed at a position facing the water rod is the fourth fuel rod. Specifically, the diameter of the shaft center portion containing the burnable poison of the fourth fuel rod is set to be larger in the lower region than in the upper region, or the shaft containing the burnable poison of the fourth fuel rod is set. The burnable poison concentration in the heart portion is set to be higher in the lower region than in the upper region. With this configuration, the neutron absorption by the burnable poison is increased particularly in the lower region of the fuel assembly, so that the power distribution in the height direction of the core is flattened.

Further, at least some of the fourth fuel rods are located at fuel rod height positions 19/24 to 21/24.
The diameter of the shaft portion in the range of 24 is substantially the same as the diameter of the shaft portion at the lower part of the fuel. Accordingly, by arranging a large amount of burnable poisons at the position where the neutron flux is highest when the cold and hot furnaces are stopped in the reactor core height direction, the reactivity in the region is suppressed, and the furnace stop margin is sufficiently secured.

Further, the fourth fuel rod has a fifth fuel rod in which the diameter of the axis portion containing the burnable poison is larger in the lower region than in the upper region, and a fourth fuel rod in which the diameter of the axis portion is in the upper region than in the lower region. And a fourth fuel rod disposed at a position facing the water rod is a fifth fuel rod, and a fourth fuel rod disposed at the outermost periphery of the fuel assembly. The first fuel rod is set to be the sixth fuel rod.

That is, in the sixth fuel rod, the surface area of the substance containing the burnable poison is larger in the upper region than in the lower region,
The concentration of the burnable poison is higher in the lower region than in the upper region.

With this configuration, the amount of plutonium and gadolinia above the core is slightly reduced to harden the neutron spectrum above the core, thereby increasing the reactor shutdown margin without causing distortion in the power distribution in the height direction of the core. it can.

Further, the fuel pellets sealed at the upper and lower ends of the first fuel rod are set to be made of a substance containing no burnable poison. By employing uranium dioxide pellets made of natural uranium or depleted uranium as the upper and lower end pellets, the amount of extra fissile material is reduced in a region where combustion does not easily proceed. When hollow pellets are used at the upper and lower ends, the volume of the gas plenum can be increased in addition to the reduction in the amount of fissile material. Further, the hollow pellet is sealed with a porous ceramic having a small neutron absorption cross-sectional area, thereby preventing the hollow pellet from falling off.

[0026]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described below. FIG. 1 is a horizontal cross-sectional view showing a fuel rod arrangement of a fuel assembly 1 according to the present embodiment, and FIG. 2 is an axial cross-sectional view showing a gadoniria distribution in a height direction of each fuel rod constituting the fuel assembly 1. It is.

The symbol M in the figure is MOX containing no burnable poison.
Fuel rods G1, G2, G3, G4 are MOX fuel rods containing gadolinia as a burnable poison. Each gadolinia-containing MOX fuel rod Gi has a structure in which a substance containing gadolinia is disposed on an axis portion, and a material containing no gadolinia is disposed on the outer periphery of the axis portion. In FIG. 2, the gadolinia-containing substance in the axial center portion is indicated by oblique lines.
Here, uranium dioxide is used as a gadolinia base material. In addition, ceramics of Tako Udezu having a small neutron cross-sectional area may be used as a book material. The region excluding the hatched portion is occupied by MOX fuel containing no gadolinia.

Further, the plutonium enrichment of MOX in the portion excluding the axial center portion of each fuel rod Gi and in the fuel rod M is uniform. That is, FIG.
In the fuel assembly 10 of No. 2, the plutonium enrichment of the fuel
While it was necessary to produce different types of fuel pellets,
In this embodiment, since the plutonium enrichment can be set to be uniform, the fuel production cost can be significantly reduced.

The outer diameter of the fuel pellets used for these fuel rods is about 9.6 mm, while the diameter of the axial portion containing gadolinia is 5 mm, 4 mm and 3 mm for the fuel rods G1, G2 and G4, respectively. It is uniform in the vertical direction. The axial center of the fuel rod G3 is 4 m in height from 1/24 to 12/24 of the fuel rod denoted by reference numeral 11 in FIG.
m and other portions are 3 mm. Uranium dioxide, in particular, depleted uranium, is used as the base material of these axial portions, and the gadolinia concentration of the axial portions is uniformly 5%.

Although the values of the diameter and gadolinia concentration of the axial center portion are not limited to these values, with this configuration, the fuel rods G1, G2, and G4 in the region excluding the upper and lower nodes of the fuel rods, Although the gadolinia concentration is uniform in the upper region and the lower region, the gadolinia concentration of the fuel rod G3 is higher in the lower region than in the upper region.

The arrangement of the fuel rods in the fuel assembly 1 will be described with reference to FIG. Regarding the outermost peripheral region of the fuel assembly 1, the fuel rod G1 is located at the corner of the fuel assembly 1, the fuel rod G2 is located at a position adjacent to the fuel rod G1, and the fuel rod G2 is located at a position adjacent to the fuel rod G2. G3 is further moved to a position where these fuel rods G1, G2 and G3 are not disposed.
Are arranged respectively. A fuel rod G3 is disposed at a position adjacent to the water rod 5 in two directions.
3 and the fuel rod G3 also at a position adjacent to the water rod 5.
Place. The fuel rods M are arranged at other positions.

Since the neutron shielding effect of the MOX loaded on the outer periphery of the axial center portion of the MOX fuel rod Gi cannot be ignored, it faces the water gap where the thermal neutron flux is high or the water rod 5 as described above. By arranging the fuel rods Gi at the positions, the neutron absorption effect of gadolinia can be enhanced.

In general, the larger the outer diameter of the axial center portion including gadolinia, the larger the surface area and the greater the neutron absorption effect of gadolinia. In the present embodiment, the fuel rods G1 and G2 having a large outer diameter of the axial center portion are arranged particularly at the corners of the fuel assembly where the thermal neutron flux is high and in the vicinity thereof.

Further, by disposing the fuel rods G3 at six positions facing the water rod 5, it is possible to prevent the moderator density from increasing at the center of the fuel assembly 1 at the time of shutting down the cooling and heating furnace, thereby increasing the thermal neutron flux. In addition, the furnace shutdown margin can be improved.

FIG. 3 shows the transition of combustion at infinite multiplication factor in the fuel assembly 1 according to the present embodiment when the average vertical void ratio of the fuel assembly is 40%. It is a graph shown in comparison with the aggregate 10.
In the figure, a solid line denoted by reference numeral 21 indicates the present embodiment, and reference numeral 2
A dashed line with 2 indicates a conventional case. In each case, the case where there is no burnable poison, that is, the case where the infinite multiplication factor linearly decreases as the combustion proceeds, is shown by a broken line.

In this embodiment, the gadolinia-burning burnout is shortened by arranging many gadolinia-containing fuel rods at a position where the thermal neutron flux is high. That is, according to FIG. 3, the combustion transition of the infinite multiplication factor exhibits almost the same behavior as that without gadolinia after about 14 GWd / t in the conventional case, whereas it is about 10 GWd in the present embodiment. / T or later. Therefore, in the present embodiment, the unburned gadolinia at the end of the driving cycle is reduced, and as a result, the reactivity gain is improved.

FIG. 4 is a graph showing the combustion transition of the local output peaking coefficient for the fuel assembly 1 according to the present embodiment in comparison with the case of the fuel assembly 10 shown in FIG. . In the figure, a solid line denoted by reference numeral 23 indicates the present embodiment, and a broken line denoted by reference numeral 24 indicates a conventional case. As described above, the distortion of the local output distribution is greatly improved even though the number of types of enrichment is reduced from four to one in the related art.

FIG. 5 is a power distribution in the average core height direction in the equilibrium cycle core loaded with the fuel assembly 1 according to the present embodiment. Here, (a), (b), and (c) show the initial stage (BOC), the middle stage (MOC), and the last stage (EOC) of the operation cycle, respectively. At the end of the operation cycle, the control rods are completely withdrawn. The vertical axis of the graph indicates the position in the core height direction as 24 nodes as a whole, and the horizontal axis indicates the relative output, that is, the output obtained by standardizing the output as an average output of 1. Further, in the figure, a circle with a reference numeral 25 indicates the output distribution of the present embodiment, and a cross with a reference numeral 26 indicates the output distribution in the case of the prior art.

As can be seen from this figure, the output in the lower half of the fuel assembly is kept small and the output in the upper half is slightly increased over the entire operation cycle as compared with the conventional fuel assembly 10. In the fuel assembly 1, the distortion of the power distribution in the height direction as a whole is flattened. Further, in the present embodiment, the relative output particularly at the BOC is almost constant except for several nodes at the upper and lower ends, and it can be seen that the distortion of the output distribution is greatly improved.

Here, the base material of each fuel rod Gi containing gadolinia is not limited to depleted uranium, but may be natural uranium or low-enriched uranium. Further, it may be made of a non-fissionable substance typified by zirconium oxide (ZrO ₂ ) or alumina (Al ₂ O ₃ ).

In the fuel rod manufacturing process according to this embodiment,
There is no direct production of burnable poisoned fuel rods. That is, in manufacturing this fuel rod, for example, first, a region excluding the axial portion of the fuel pellet is molded to produce a hollow pellet, and then the fuel pellet is produced by molding the axial portion containing a burnable poison. It is conceivable to stack and enclose this in a fuel cladding tube. In this manufacturing process, especially in the MOX fuel assembly, M
By using a substance other than OX, the production cost can be reduced and the contamination of the production equipment due to the burnable poison can be removed as much as possible.

Hereinafter, a second embodiment of the present invention will be described. FIG. 6 is an axial cross-sectional view showing a gadonia distribution in the height direction of each fuel rod constituting the fuel assembly according to the present embodiment. In the present embodiment, the arrangement of the fuel rods M, G1, G2, G3, G4 in the fuel assembly 1 in the first embodiment is the same, but the gadolinia concentration of G3, G4 among the fuel rods is partially changed. It was done. That is, in FIG.
In the axial center portion of the fuel rod G3, a portion at a height position 1/24 to 12/24 denoted by reference numeral 11 in the figure, that is, the lowermost 1
The gadolinia concentration in the lower half excluding the nodes is set lower than the gadolinia concentration in the axial center of the upper half of the fuel rod G3. Further, the gadolinium concentration at the height position 1/24 to 12/24 indicated by reference numeral 12 in the axial center portion of the fuel rod G4 is set higher than the gadolinia concentration at the axial center portion of the upper half of the fuel rod G4. I do. Further, the fuel assembly composed of these fuel rods is set so that the gadolinia concentration is higher in the lower half than in the upper half as a whole.

The present embodiment has a configuration in which the gadolinia concentration is increased in a portion where the neutron absorption effect by gadolinia is particularly large and combustion progresses rapidly. As a result, substantially the same operation and effect as in the first embodiment can be obtained, and at the same time, the neutron absorption effect in the lower half of the fuel assembly is particularly increased. The output distribution can be flattened.

Hereinafter, a third embodiment of the present invention will be described. FIG. 7 is an axial cross-sectional view showing the gadonia distribution in the height direction of each fuel rod constituting the fuel assembly according to the present embodiment. In the present embodiment, the arrangement of the fuel rods M, G1, G2, G3, G4 in the fuel assembly in the first embodiment is the same, but the structure of the upper and lower ends of each fuel rod and the gadolinia of the fuel rod G4 are changed. The outer diameter of the contained shaft center is partially changed. That is, in FIG. 7, natural uranium or depleted uranium is disposed at the upper and lower ends of each fuel rod denoted by reference numeral 14 in the figure. The reference numeral 13 in the figure indicates the axial portion of the fuel rod G4.
, The diameter of the portion from the height position 2/24 to 8/24, that is, the lower 1/3 portion excluding the lowermost 1 node,
The diameter is set to be larger than the diameter of the upper axis portion.

As a result, substantially the same operation and effect as those of the first embodiment can be obtained, and at the same time, the fissile material at the upper and lower end portions 14 of the fuel rod, in which combustion does not easily proceed, can be eliminated. Further, in order to prevent the power peaking at the lower part of the core from increasing due to the decrease in the power at the end caused by this deletion, the diameter of the lower part of the axial part of the fuel rod G4 is increased to increase the core height. An increase in directional output peaking can be suppressed.

Hereinafter, a fourth embodiment of the present invention will be described. FIG. 8 is an axial cross-sectional view showing the gadonia distribution in the height direction of each fuel rod constituting the fuel assembly of the present embodiment. In this embodiment, the arrangement of the fuel rods M, G1, G2, G3, and G4 in the fuel assembly in the first embodiment is the same, but the diameter of the axial center of the fuel rod G3 containing gadolinia is one. The part has been changed. That is, in FIG.
The diameter of the part of the fuel rod G4 at the height positions 19/24 to 21/24 denoted by reference numeral 15 in the figure is set to be larger than the diameter of the shaft part above it.

As a result, substantially the same functions and effects as those of the first embodiment can be obtained. Furthermore, since the diameter of the shaft center portion in the range of the height position 19/24 to 21/24 in the first embodiment was 3 mm, when the diameter of the portion was set to, for example, 5 mm, the temperature of the cold / hot furnace was thus stopped. By locally increasing the gadolinia content in the region where the neutron flux is high, the reactivity of the core can be suppressed and the reactor shutdown margin can be increased by about 0.5% Δk.

Hereinafter, a fifth embodiment of the present invention will be described. FIG. 9 is an axial cross-sectional view showing the gadoniria distribution in the height direction of each fuel rod constituting the fuel assembly of the present embodiment. In this embodiment, the arrangement of the fuel rods M, G1, G2, G3 and G4 in the fuel assembly in the first embodiment is the same, but the axial center portion of the fuel rod G4 containing gadolinia is partially changed. It was done. That is, each of 16
The diameter of the shaft portion of the upper half of the fuel rod G4, which is indicated by, is set to be larger than the diameter of the lower half. Further, the gadolinia content of the axial center portion of the upper half of these fuel rods G4 is set smaller than that of the lower half.

As a result, substantially the same functions and effects as those of the first embodiment can be obtained. Furthermore, by hardening the neutron flux spectrum above the core by slightly reducing the plutonium enrichment and gadolinia amount above the core, plutonium can be burned more efficiently, so that the distortion of the power distribution in the height direction of the core is reduced. It is possible to further reduce and increase the margin for stopping the furnace.

Hereinafter, a sixth embodiment of the present invention will be described. FIG. 10 is an axial cross-sectional view showing the gadonia distribution in the height direction of each fuel rod constituting the fuel assembly of the present embodiment. In the present embodiment, the arrangement of the fuel rods M, G1, G2, G3, G4 in the fuel assembly in the first embodiment is the same, but the upper and lower ends of each fuel rod are changed to hollow pellets. is there. That is, the portion indicated by reference numeral 17 in the drawing is hollow.

As a result, substantially the same functions and effects as those of the first embodiment can be obtained. Further, the amount of fissile material can be reduced and the volume of the gas plenum can be increased in a region where combustion does not easily proceed.

The same function and effect as described above can be obtained by enclosing porous ceramics having a small neutron absorption cross-sectional area such as zirconium oxide or alumina in the hollow portion.

Hereinafter, a seventh embodiment of the present invention will be described. FIG. 11 is a horizontal sectional view showing the fuel rod arrangement of the fuel assembly 2 according to the present embodiment. In the present embodiment, the first
In this embodiment, a square water rod 18 is provided at the center of the fuel assembly 1 instead of the water rod 5 of the fuel assembly 1 in the embodiment. The number of fuel rods per fuel assembly is 72, which is two less than in the first embodiment, but the basic fuel rod arrangement is the same as in the first embodiment. Thereby, the same operation and effect as in the first embodiment can be obtained.

Also, instead of the fuel rods of the fuel assembly according to the first embodiment, the fuel rods of the fuel assemblies according to the second to sixth embodiments may be arranged. Thereby, the operation and effect corresponding to each embodiment can be obtained. Although several embodiments have been described above, each of the embodiments
The present invention is not limited to the X fuel assembly, and can be similarly applied to a conventional uranium fuel assembly.

[0055]

As described above, according to the present invention, plutonium enrichment is achieved by arranging burnable poisons on the fuel rods at the appropriate positions as described above. By greatly reducing the number of types, the manufacturing cost can be significantly reduced, and at the same time, the power distribution in the height direction of the core is flattened, the thermal margin is improved, and the burnable poison remains at the end of the operation cycle. By eliminating the plutonium loading per fuel assembly and by sufficiently increasing the amount of plutonium, a nuclear reactor having excellent fuel design flexibility and fuel economy can be realized.

[Brief description of the drawings]

FIG. 1 is a horizontal sectional view showing a fuel rod arrangement of a fuel assembly according to a first embodiment of the present invention.

FIG. 2 is an axial sectional view showing a gadolinia distribution of each fuel rod included in the fuel assembly according to the first embodiment of the present invention.

FIG. 3 is a graph showing a combustion transition at an infinite multiplication factor of the fuel assembly according to the first embodiment of the present invention.

FIG. 4 is a graph showing a combustion transition of a local output peaking coefficient of the fuel assembly according to the first embodiment of the present invention.

FIG. 5 is a graph showing a core height direction power distribution in an equilibrium cycle core loaded with a fuel assembly according to the first embodiment of the present invention, wherein (a) shows an initial operation cycle;
(B) is at the middle of the operation cycle, and (c) is at the end of the operation cycle.

FIG. 6 is an axial sectional view showing a gadolinia distribution of each fuel rod constituting a fuel assembly according to a second embodiment of the present invention.

FIG. 7 is an axial sectional view showing a gadolinia distribution of each fuel rod constituting a fuel assembly according to a third embodiment of the present invention.

FIG. 8 is an axial sectional view showing a gadolinia distribution of each fuel rod constituting a fuel assembly according to a fourth embodiment of the present invention.

FIG. 9 is an axial sectional view showing a gadolinia distribution of each fuel rod constituting a fuel assembly according to a fifth embodiment of the present invention.

FIG. 10 is an axial sectional view showing a gadolinia distribution of each fuel rod constituting a fuel assembly according to a sixth embodiment of the present invention.

FIG. 11 is a horizontal sectional view showing a fuel rod arrangement of a fuel assembly according to a seventh embodiment of the present invention.

12A is a longitudinal sectional view of a fuel assembly of a conventional boiling water reactor, and FIG. 12B is a sectional view taken along line AA of FIG. 12A.

FIG. 13 is a horizontal sectional view showing an example of a fuel rod arrangement of a conventional MOX fuel assembly.

[Explanation of symbols]

 1, 2, 9 Fuel assembly 3 Channel box 4 Fuel rod 5, 18 Water rod 6 Spacer 7 Upper tie plate 8 Lower tie plate

Claims (13)

[Claims] 1. A first method comprising fissile material and burnable poison.
A fuel rod, a second fuel rod containing a fissile substance and no burnable poison, and a water rod in which a coolant flows inside are bundled in a grid, wherein the fuel assembly comprises: At least a part of a position facing the water rod and an outermost periphery of the fuel assembly.
And a shaft portion of the first fuel rod is made of a substance containing a burnable poison, and a region excluding the shaft portion of the first fuel rod contains a burnable poison. A fuel assembly comprising non-fissile material. 2. The fuel assembly according to claim 1, wherein the burnable poison contained in the first fuel rod is gadolinia. 3. The fuel assembly according to claim 1, wherein the fissile material contained in the first fuel rod and the second fuel rod is a mixed oxide of uranium dioxide and plutonium dioxide. body. 4. The fuel assembly according to claim 1, wherein the base material of the burnable poison located at the axial center of the first fuel rod is uranium dioxide. 5. The fuel assembly according to claim 1, wherein the base material of the burnable poison located at the axial center of the first fuel rod is a porous ceramic having a small neutron absorption cross-sectional area. . 6. The third fuel rod, wherein the first fuel rod is divided into an upper region and a lower region excluding upper and lower ends, and the concentration of the burnable poison is uniform in the upper region and the lower region. And a fourth fuel rod having a lower concentration of the burnable poison in the lower region than in the upper region, and the first fuel rod disposed at a position facing the water rod is the fourth fuel rod. 2. The fuel assembly according to claim 1, wherein said fuel rod is a fuel rod. 7. The fuel assembly according to claim 6, wherein in the fourth fuel rod, a diameter of an axis portion including the burnable poison is larger in the lower region than in the upper region. 8. The fuel according to claim 6, wherein in the fourth fuel rod, the concentration of the burnable poison in the axial center portion containing the burnable poison is higher in the lower region than in the upper region. Aggregation. 9. The fuel rod according to claim 4, wherein the diameter of the axial portion of the fuel rod in the range of height positions 19/24 to 21/24 is higher than the height position of 21/24. The fuel assembly according to claim 6, wherein the fuel assembly is larger than a diameter. 10. The fifth fuel rod, wherein the fourth fuel rod has a fifth fuel rod in which a diameter of an axis portion including the burnable poison is larger in the lower region than in the upper region, and in a diameter of the axis portion. A fourth fuel rod, comprising a sixth fuel rod in which the upper region is larger than the lower region, and which is disposed at a position facing the water rod, is the fifth fuel rod, and further comprises the fifth fuel rod. 7. The fuel assembly according to claim 6, wherein at least a part of the first fuel rods arranged on the outermost periphery of the assembly is the sixth fuel rod. 11. The fuel assembly according to claim 1, wherein the fuel pellets sealed at the upper and lower ends of the first fuel rod are made of a substance containing no burnable poison. 12. The fuel assembly according to claim 11, wherein the fuel pellets sealed at the upper and lower ends of the first fuel rod are made of natural uranium or depleted uranium. 13. The fuel assembly according to claim 11, wherein the fuel pellets sealed in the upper and lower ends of the first fuel rods are hollow pellets.