JP2009145363A - Fuel assembly - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve critical power of a fuel assembly by averaging power of fuel rods and preventing rising of boiling transition of a specific fuel rod. <P>SOLUTION: The fuel assembly 1 for a boiling water reactor includes many fuel rods, including fuel rods in which pellets containing burnable poison are filled, arranged in a square lattice shape, and two water rods 6 in which water flows. The many fuel rods include long fuel rods N1-N5 in which the burnable poison containing fuel pellets are not filled in their active length, a short fuel rod V, and long fuel rods G1, G2 in which the pellets containing the burnable poison are filled at least in a part of a clad axially. The long fuel rods N1-N5 in which the fuel pellets containing the burnable poison are not filled are arranged on an outermost part of the fuel assembly 1 and a position adjacent to both of the two water rods 6. The long fuel rods G1, G2 in which the pellets containing the burnable poison are filled are arranged in a position except for the outermost part and the position adjacent to both of the two water rods 6. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a fuel assembly with improved limit power characteristics used in a boiling water reactor (referred to as BWR).

  In general, a fuel assembly used in a BWR has a structure in which a large number of fuel rods are bundled in a square lattice and surrounded by a channel box. An example of a conventional BWR fuel assembly will be described with reference to FIGS. In FIG. 6, the fuel assembly denoted by reference numeral 1 includes an upper tie plate 4 and a lower tie plate in which long fuel rods 2, short fuel rods 3, and water rods 6 are bundled by a spacer 8 into a 9 × 9 square lattice. The fuel rod bundle is fixed to 5 to be surrounded by a channel box 7. 6B is a cross-sectional view taken along the line B-B in FIG. 6A, and FIG. 6C is a cross-sectional view taken along the line C-C in FIG.

  The coolant / neutron moderator water flows through the space surrounded by the channel box 7 and is heated to generate voids. Non-boiling water exists between the channel box of the other fuel assembly adjacent to the outside of the channel box 7, and thermal neutrons from here are in the outer portion of the other fuel assembly 1 close to the channel box 7. As a result, the thermal neutron flux distribution is nonuniform in one fuel assembly 1.

  Non-uniform thermal neutron flux distribution leads to non-uniform fuel rod output. In order to correct the non-uniformity of the thermal neutron flux distribution to some extent and to optimize the moderator-to-nuclear fuel material ratio, a water rod 6 through which water flows is arranged in the approximate center of the fuel assembly 1. The water rod 6 shown in FIG. 6 has a circular cross section, but does not necessarily have a circular cross section.

  Since the short fuel rods 3 of the fuel assembly 1 exist relatively below, the short fuel rods 3 are not shown in the cross-sectional view of FIG. It has become. Since the void ratio is high at the upper part of the fuel assembly 1, the pressure loss increases and the amount of the moderator with respect to the nuclear fuel material is reduced. However, the correction is made by the absence of the short fuel rod 3 at the upper part.

  Conventionally, not all fuel assemblies that have been used have two types of long fuel rods 2 and short fuel rods 3 having different lengths, but only one type of fuel rod is used. There are also many. FIG. 7A shows the configuration of the long fuel rod 2, and FIG. 7B shows the configuration of the short fuel rod 3.

  As shown in FIG. 7, both the long fuel rod 2 and the short fuel rod 3 are loaded with a plurality of fuel pellets 10 in a cladding tube 11, and both ends of the cladding tube 11 are sealed with an upper end plug 12 and a lower end plug 13. The spring 15 is provided in the upper plenum 14 in the cladding tube 11 to press the fuel pellets 10. The short fuel rod 3 is also provided with a plenum 14 at the bottom. Hereinafter, fuel pellets are simply referred to as pellets.

The material of the pellet 10 is almost always uranium dioxide. Recently, use of a mixed oxide (MOX) of uranium and plutonium has begun. Some pellets contain flammable poisons that absorb thermal neutrons. Gadolinium is commonly used as a flammable poison, and is mixed into the pellet in the form of gadolinia (Gd ₂ O ₃ ), which is an oxide.

  The number of pellets loaded in one fuel rod is not necessarily one, and several types of pellets having different fissile substance concentrations and combustible poison concentrations are often used in combination. Further, a fuel assembly is configured by combining several types of fuel rods with different pellets to be loaded inside the cladding tube.

  FIG. 8 shows an example of the arrangement of the fuel rods in the fuel assembly 1 and the axial distribution of the pellets in the fuel rods. FIG. 8A is a cross-sectional view showing the arrangement of fuel rods in the fuel assembly, and FIG. 8B is a diagram showing the axial distribution of pellets in the fuel rods. In the figure, N1 to N5 are long fuel rods without gadolinia, G is a long fuel rod with gadolinia, V is a short fuel rod, WR is a water rod, and long fuel rods are six types indicated by N1 to N5 and G, There is one kind of short fuel rod V. The short fuel rods V are provided at the (2, 2), (2, 5) positions on the second layer from the outermost periphery and at symmetrical positions thereof.

  The material of the pellets is uranium dioxide, and some pellets are mixed with gadolinia as a flammable poison. Except for natural uranium, there are five types of uranium 235 enrichment in pellets, a to e, and a> b> c> d> e. The concentration of gadolinia is X. It is shown in the form of XG (wt%).

  Natural uranium pellets are loaded in the hatched portions of the long fuel rods N1 to N5 and G. There are 16 fuel rods G loaded with gadolinia-containing pellets, excluding natural uranium pellets at the upper and lower ends, and loaded with pellets with a gadolinia concentration of 4.0 wt% and uranium 235 enrichment c.

  The concentration of the flammable poison in the pellet containing the flammable poison and the number of the pellets containing the flammable poison are determined from the following conditions. FIG. 9 schematically shows changes associated with combustion at infinite multiplication factors in the regions I and II of the fuel assembly shown in FIG. It is assumed that this fuel assembly is used for about 4 cycles. The infinite multiplication factor when no flammable poison is present is indicated by a dotted line in the figure.

  In this case, the infinite multiplication factor of the fuel in the first, second, third, and fourth cycles all decreases with combustion, so it is necessary to insert a very large number of control rods at the beginning of the cycle, and control is performed one after another during operation. It becomes necessary to pull out the stick. When the flammable poison is mixed in the pellet, the infinite multiplication factor can be lowered because the flammable poison absorbs thermal neutrons.

  Combustible poisons are lost by absorbing thermal neutrons, and the effect of decreasing the infinite multiplication factor decreases. By changing the concentration of the flammable poison, it is possible to adjust the time at which the flammable poison is almost completely lost (burned out). The amount of decrease in the initial infinite multiplication factor depends on the number of pellets containing flammable poisons. Normally, the period when the flammable poison is burned out is the end of the first cycle.

  By appropriately setting the initial reduction amount of the infinite multiplication factor, the reduction associated with the infinite multiplication factor combustion of the second, third, and fourth cycle fuels can be increased by the infinite multiplication factor combustion of the first cycle fuel. It is possible to compensate and keep the reactivity of the core substantially constant, and it is possible to operate with the number of control rods used and the insertion depth thereof being substantially constant.

  There are no flammable poisons at the upper and lower ends of the fuel assembly shown in Fig. 8, but this part uses natural uranium with large neutron leakage and low uranium 235 content. Has little effect on the characteristics of The reason why the flammable poison is not put into the upper and lower end portions is because it is not necessary to suppress the output of this portion.

  Note that the above description of the flammable poison is for replacement fuel used in the core that has reached an equilibrium state. Even in the initial loading fuel used for the initial loading core, flammable poisons are used to appropriately control the reactivity of the entire core. However, there is a difference that the flammable poisons are not always burned out at the end of the first cycle. is there.

  In boiling water reactors, one of the thermal limiting conditions for fuel to be observed during reactor operation is the minimum critical power ratio. The limit output is the fuel assembly output that reaches the boiling transition, that is, the state exceeding the nucleate boiling, and the limit output ratio is defined by the following equation.

(Limit output ratio) = (Limit output) / (Fuel assembly generation output)
Of the limit power ratios for each fuel assembly loaded in the core, the minimum one is called the minimum limit power ratio, and is used as a measure of the thermal margin for burnout of the fuel rods.

  The fuel assembly output that causes the boiling transition is the limit output, but not all fuel rods cause the boiling transition even if the limit output is reached. If there is a single fuel rod that is likely to undergo boiling transition, the limit output of the fuel assembly will be small.

  Even if some of the fuel rods are very difficult to cause a boiling transition, there is no point in terms of the limit output of the fuel assembly. In a fuel assembly in which some fuel rods are loaded with flammable poison pellets, fuel rods loaded with flammable poison pellets are less prone to boiling transitions, while other fuel rods are more prone to boiling transitions. There are challenges.

  There are many factors affecting the ease of boiling transition on the surface of the fuel rod, such as the output of the fuel rod and the shape of the member that affects the coolant flow, such as the spacer, and it is strictly evaluated at this time. There is no choice but to rely on experiments.

  However, the output of the fuel rod is used here for general discussion that is not confined to the fine structure of the fuel member. Boiling transitions can occur in the upper part of fuel assemblies with a high void fraction, but using the power of the entire fuel rod is the quality of the coolant (gas phase) that greatly affects the likelihood of boiling transitions. This is because the output on the upstream side, that is, the downward direction of the fuel rod becomes a problem in the ratio of the liquid phase to the liquid phase.

  FIG. 10 shows the relative output of each fuel rod when the output of the fuel rod of the fuel assembly of FIG. FIG. 10 (a) shows the burn-up with 0 (point A in FIG. 9), and FIG. 10 (b) shows the burn-up with the burned-out gadolinia (point B in FIG. 9). The value of the fuel rod loaded with pellets containing gadolinia is marked with a circle. The axial power distribution of the fuel assembly is assumed to be low at the top and bottom and high at the center. FIG. 9 shows the influence of the fuel rod in FIG. 8 on the infinite multiplication factor of the flammable poison in relation to the burnup.

  First, in FIG. 10 (a), it is noticeable that the output of the fuel rods on the outermost periphery of the fuel assembly is high, because there is much supply of thermal neutrons from non-boiling water outside the channel box 7. . However, there is a low-quality (a lot of liquid phase) coolant flow along the inner surface of the non-heat-generating channel box 7, and a part of this coolant flow is supplied to the fuel rod surface on the outermost periphery of the fuel assembly. Therefore, the boiling transition hardly occurs for the output. The same is true for the fuel rods adjacent to the water rods to a lesser extent.

  It can also be confirmed that the output of the short fuel rod is low. This is because the length of the heat generating part of the fuel rod is short. Short fuel rods may be located in the lower part of the void ratio, and the possibility of boiling transitions on the surface is extremely low.

  In FIG. 10A, the fuel rod loaded with gadolinia-containing pellets has an extremely low output compared to other fuel rods because gadolinia absorbs thermal neutrons. In FIG. 10 (b), the output of the fuel rod loaded with pellets containing gadolinia is low because the enrichment of uranium 235 is lowered.

  The low concentration of uranium 235 in gadolinia-containing pellets has been adopted in many designs, but the purpose is to reduce the thermal conductivity and the melting point when gadolinia is mixed with the pellets. Since the mechanical characteristics deteriorate, the output is kept low even after gadolinia burns out, and a sufficient margin of thermomechanical characteristics is secured.

  In this way, the output of fuel rods loaded with flammable poison pellets is low, so the output of other fuel rods is relatively high, boiling transitions are likely to occur on the surface, and the limit output of the fuel assembly is low. To do. Fuel rods loaded with flammable poison pellets have a low power output and the possibility of boiling transitions on their surfaces is very low, but this does not contribute to the fuel assembly's critical power.

  The present invention has been made to solve the above-mentioned problems. Since the output of some of the fuel rods is excessively low, the output of other fuel rods is relatively increased, and the boiling transition on the surface thereof is caused. An object of the present invention is to provide a fuel assembly capable of preventing the limit output from being lowered due to a tendency to occur, and thereby improving the limit output characteristics of a large number of fuel rods.

  In order to solve the above problems, a fuel assembly according to the present invention has two water rods in which a plurality of fuel rods including fuel rods loaded with pellets containing flammable poisons are arranged in a square lattice and water flows inside. In a fuel assembly for a boiling water reactor having rods, the multiple fuel rods are at least shafts of a long fuel rod, a short fuel rod, and a cladding tube in which an effective length is not loaded with a fuel pellet containing a combustible poison. It is composed of long fuel rods loaded with combustible poison-containing pellets in a part of the direction, and the long fuel rods not loaded with the combustible poison-containing fuel pellets are the outermost peripheral portion of the fuel assembly, and Located at a position adjacent to both of the two water rods, the long fuel rod loaded with the pellet containing the flammable poison is positioned adjacent to both the outermost peripheral portion and the two water rods. Characterized in that it is arranged at a position except.

  Further, the fuel assembly according to the present invention is a boiling water nuclear reactor fuel assembly having a water rod in which a large number of fuel rods including fuel rods containing combustible poisons are arranged in a square lattice and water flows inside. The fuel rods adjacent to the outermost fuel rods and the water rods of the fuel assembly are not loaded with flammable poison pellets in the cladding tube, and the fuel rods adjacent to the outermost fuel rods are not loaded. A fuel assembly comprising a rod and a fuel rod adjacent to the fuel rod adjacent to the water rod, wherein a pellet containing a combustible poison is loaded in at least a part of the cladding tube in the axial direction.

  The fuel assembly according to the present invention is a boiling water type having two water rods in which a large number of fuel rods including fuel rods loaded with pellets containing flammable poisons are arranged in a square lattice and water flows inside. In the fuel assembly for a nuclear reactor, the fuel rods at the outermost peripheral portion of the fuel assembly are not loaded with flammable poison pellets in the cladding tube, and all the fuel rods at positions other than the outermost peripheral portion are in the cladding tube. At least part of the axial direction is filled with flammable poison pellets, and the fuel rods adjacent to both of the two water rods are loaded with flammable poison pellets almost in the axial direction in the cladding tube. The fuel rods loaded with flammable poison pellets other than the fuel rods adjacent to both of the two water rods are loaded with the flammable poison pellets below or above the axial center in the cladding tube. And wherein the are.

  According to the present invention, the output of a large number of fuel rods is averaged to prevent a decrease in the limit output caused by an increase in the boiling transition of a specific fuel rod, and a fuel assembly having a high limit output characteristic is provided. can do.

(A) is the fuel rod arrangement | positioning figure of 1st Embodiment of the fuel assembly which concerns on this invention, (b) is the axial direction distribution map of the fuel pellet in the fuel rod in (a). (A) is a relative output diagram in the case where the burnup of the fuel rod in the fuel assembly of FIG. 1 is 0, and (b) is a relative output diagram in the case of the burnup with which the gadolinia is burned out. (A) is the fuel rod arrangement | positioning figure of 2nd Embodiment of the fuel assembly which concerns on this invention, (b) is an axial direction distribution map of the fuel pellet in the fuel rod in (a). (A) is the fuel rod arrangement | positioning figure of 3rd Embodiment of the fuel assembly which concerns on this invention, (b) is an axial direction distribution map of the fuel pellet in the fuel rod in (a). (A) is the fuel rod arrangement | positioning figure of 4th Embodiment of the fuel assembly which concerns on this invention, (b) is an axial direction distribution map of the fuel pellet in the fuel rod in (a). (A) is a longitudinal cross-sectional view showing an example of a conventional boiling water reactor fuel assembly, partly cut away, (b) is a cross-sectional view taken along line BB in (a), and (c) is (a) CC sectional view taken on the line in FIG. (A) is a three-dimensional view showing the long fuel rod of the fuel assembly in FIG. 6 in a partial cross section, and (b) is a three-dimensional view showing the short fuel rod in a partial cross section. (A) is the fuel rod arrangement | positioning figure of the conventional fuel assembly, (b) is an axial distribution map of the fuel pellet in the fuel rod in (a). The characteristic view which shows the influence on the infinite multiplication factor of the combustible poison of the fuel rod in FIG. (A) is a relative output figure in the case of the burnup 0 of the fuel rod of the conventional fuel assembly, (b) is a relative output figure which shows the case of the burnup at which gadolinia burned out.

(First embodiment)
A first embodiment of a fuel assembly according to the present invention will be described with reference to FIGS. The structure of the fuel assembly according to the present embodiment is essentially the same as that shown in FIGS. 6A to 6C and the structure of the fuel rods is not shown in FIGS. 7A and 7B. These descriptions are omitted.

  FIGS. 1A and 1B are views for explaining a first embodiment of a fuel assembly according to the present invention. FIG. 1A is an arrangement of fuel rods and water rods in a channel box 7. 1 (b) is an axial distribution diagram of pellets in the fuel rod, FIG. 1 (a) corresponds to FIG. 8 (a), and FIG. 1 (b) is FIG. 8 (b). In FIG. 1, the same parts as those in FIG.

  This embodiment differs from the conventional example in that the number of fuel rods N1 loaded with the highest enriched pellets is reduced by 16 compared with the conventional fuel assembly shown in FIG. The fuel rods G loaded with gadolinia-containing pellets are removed, and instead, 16 fuel rods G1 and G2 each partially loaded with gadolinia-containing pellets are provided by combining the pellets loaded in the fuel rods. That is.

  The other fuel rods N2 to N5 and V are not changed. The fuel assembly according to the present embodiment and the conventional fuel assembly have exactly the same uranium 235 enrichment in the fuel assembly and the amount of gadolinia used.

  When the fuel assemblies in FIG. 1 are divided into regions in the axial direction with reference to the horizontal position of the long fuel rods G1 and G2 with gadolinia, they are divided into four regions. The arrangement of gadolinia-containing pellets in regions I and II is completely different, and the concentration of uranium 235 in gadolinia-containing pellets is not the highest in regions I and II.

  The fuel assembly as a whole has 32 fuel rods partially loaded with gadolinia-containing pellets, and all long fuel rods other than the outermost periphery and the portion adjacent to the water rod are fuel rods loaded with gadolinia-containing pellets. Yes.

  FIG. 2 shows the output of the fuel rod of the fuel assembly of FIG. FIG. 2A shows a burnup with a burnup of 0, and FIG. 2B shows a burnup with gadolinia burned out. 2 (a) and 2 (b), the portions surrounded by circles are gadolinia-containing fuel rods loaded with gadolinia-containing pellets. Comparing FIG. 2 with FIG. 10, the decrease in the output of 32 fuel rods loaded with pellets containing gadolinia is moderate, and the phenomenon that the output decreases extremely compared to the fuel rods not containing gadolinia is avoided. I understand.

  The fuel rod adjacent to the outermost fuel rod and the two water rods is in a position where there is a large supply of thermal neutrons and is not loaded with gadolinia-containing pellets, so the output is high, but from the inner surface of the channel box or the outer surface of the water rod Boiling transitions are unlikely to occur due to the supply of low quality coolant. When the maximum value of the output of the other fuel rods is compared between FIG. 2 and FIG. 10, it is lower in FIG. The effect is particularly great when the burnup is zero. According to the present embodiment, it is possible to suppress the maximum value of the output of the fuel rod at a position where the boiling transition is likely to occur, and the limit output of the fuel assembly is improved.

(Second Embodiment)
Next, a second embodiment of the fuel assembly according to the present invention will be described with reference to FIGS. FIG. 3A is a cross-sectional view showing the arrangement of fuel rods in the fuel assembly, and FIG. 3B is a diagram showing the axial distribution of fuel pellets in the fuel rods.

  The fuel assembly according to this embodiment differs from the fuel assembly shown in FIGS. 1 and 8 in that the length and position of the short fuel rods V arranged in the channel box 7 are different. That is, the short fuel rods V are provided at the center (1, 5) position of the outermost periphery, the (3, 3) position of the third layer from the outermost periphery and the symmetrical positions thereof, and the short fuel rod V is shorter than the conventional example. It has become.

  3 with reference to the horizontal position of the fuel rods G2 and G3, excluding the fuel rod G1 disposed at the corner position of the second layer from the outer circumference among the long fuel rods G1 to G3 with gadolinia. When the area is divided in the axial direction, it is divided into four areas. The arrangement of long gadolinia fuel rods in region I and region II is different except for the corner position of the second layer from the outer periphery, and the uranium enrichment of gadolinia long fuel rods is not the highest in region I and region II. .

  Gadolinia-containing long fuel rods G1 to G3 loaded with gadolinia-containing pellets are a total of 28, and all long fuel rods at positions excluding the outermost periphery and the portion adjacent to the water rod 6 are loaded with gadolinia-containing pellets. It has become a fuel rod. The fuel rod G1 loaded with gadolinia-containing pellets over almost the entire axial direction is disposed at the corner position of the second layer from the outer periphery.

  At the corner position of the second layer from the outer periphery, the influence of thermal neutrons from the non-boiling water outside the channel box 7 is the second largest after the outermost periphery of the fuel assembly, and the output of the fuel rod tends to increase. However, since it is not adjacent to the channel box 7, there is no supply of a low-quality (high liquid phase) coolant flowing on the inner surface of the channel box 7. For this reason, the boiling transition is most likely to occur at this position.

  In the present embodiment, the output is particularly low by loading gadolinia-containing pellets into the long fuel rods at the position where the boiling transition is most likely to occur in almost all axial directions. In addition, a long fuel rod at a position where the boiling transition is likely to occur next is loaded with gadolinia-containing pellets in a part of the axial direction to reduce the output to some extent. In this way, a fuel rod output distribution desirable from the viewpoint of the limit output is created.

(Third embodiment)
Next, a third embodiment of the fuel assembly according to the present invention will be described with reference to FIGS. 4A is a cross-sectional view showing the arrangement of fuel rods in the channel box 7, and FIG. 4B is a diagram showing the axial distribution of fuel pellets in the fuel rods. There is one water rod 6 in the shape of a square tube, and there are 72 fuel rods with the same effective length.

  This fuel assembly is axially moved with reference to the horizontal position of the fuel rods G2 and G3, excluding the fuel rod G1 arranged at the corner position of the second layer from the outer periphery of the long fuel rods G1 to G3 with gadolinia. If the area is divided into four areas, it is divided into four areas.

  The arrangement of gadolinia-containing long fuel rods G1 to G3 in region I and region II is different except for the corner position of the second layer from the outer periphery, and the uranium 235 enrichment of gadolinia-containing long fuel rods G1 to G3 is region I, Not the best in Region II.

  There is a fuel rod not loaded with gadolinia-containing pellets other than the outermost peripheral portion and the portion adjacent to the water rod 6. For these fuel rods, not the fuel rod N1 with the highest uranium 235 enrichment but the fuel rod N2 with a slightly lower enrichment is used, and the output is lowered to some extent.

  According to the present embodiment, gadolinia-containing long fuel rod G1 over almost all of the axial direction, gadolinia-containing long fuel rods G2 and G3, and gadolinia-containing pellets are not loaded in a part of the axial direction, but the degree of enrichment is somewhat The low gadolinia-free fuel rod N2 can be appropriately disposed at a position other than the outermost peripheral portion and the portion adjacent to the water rod to create a fuel rod output distribution that is desirable from the viewpoint of limit output.

(Fourth embodiment)
Next, a fourth embodiment of the fuel assembly according to the present invention will be described with reference to FIGS.

  5A is a cross-sectional view showing the arrangement of fuel rods and water rods 6 in the channel box 7, and FIG. 5B is a diagram showing the axial distribution of fuel pellets in the fuel rods. 5A and 5B, N is a long fuel rod without gadolinia, G1 to G3 are long fuel rods with gadolinia, and VG is a short fuel rod with gadolinia. Uranium and plutonium are loaded as pellets of mixed oxide (hereinafter referred to as MOX fuel) as nuclear fuel materials for the fuel rod pellets. The flammable poison is gadolinia. Since plutonium enrichment and uranium 235 enrichment are not necessary for the description of this embodiment, pellets and fuel rods are not distinguished by plutonium enrichment and uranium 235 enrichment in FIG.

  MOX fuel has the characteristics that the neutron spectrum becomes hard, the amount of neutron absorption of gadolinium is reduced, and the effect of reducing the infinite multiplication factor is reduced. For this reason, it is necessary to increase the number of gadolinia-containing pellets in the MOX fuel. Since the neutron absorption amount of gadolinium decreases, the gadolinia concentration in the pellet containing gadolinia is lowered.

  When the fuel assemblies in FIG. 5 are divided into regions in the axial direction with reference to the horizontal position of the long fuel rods G1 to G3 containing gadolinia, the fuel assemblies are divided into three regions. 22 of the 66 fuel rods in the horizontal cross section in Region I, 22 of the 74 fuel rods in the horizontal cross section in Region II, and 66 of the fuel rods in the horizontal cross section in Region III 14 pieces are loaded with gadolinia-containing pellets.

  There are 42 fuel rods loaded with gadolinia-containing pellets in at least a part of the axial direction, but when converted to long fuel rods loaded with gadolinia-containing pellets in almost the entire axial direction, it is about 22 rods. You can see more.

  According to this embodiment, by loading gadolinia-containing pellets on at least a part of the axial direction of all fuel rods other than the outermost peripheral portion, even if the MOX fuel having a large number of required gadolinia-containing fuel rods is used, an appropriate fuel The limit output can be improved by the rod output distribution.

  DESCRIPTION OF SYMBOLS 1 ... Fuel assembly, 2 ... Long fuel rod, 3 ... Short fuel rod, 4 ... Upper tie plate, 5 ... Lower tie plate, 6 ... Water rod, 7 ... Channel box, 8 ... Spacer, 9 ... External spring, 10 ... fuel pellets, 11 ... cladding tube, 12 ... upper end plug, 13 ... lower end plug, 14 ... plenum, 15 ... spring.

Claims (9)

In a fuel assembly for a boiling water reactor having two water rods, in which a plurality of fuel rods including fuel rods loaded with pellets containing flammable poisons are arranged in a square lattice and water flows inside,
The multiple fuel rods are loaded with flammable poison pellets at least in the axial direction in the long and short fuel rods and the cladding tube, which are not loaded with flammable poison fuel pellets in their effective length. A long fuel rod composed of long fuel rods and not loaded with the fuel pellets containing flammable poisons is disposed at a position adjacent to both the outermost periphery of the fuel assembly and the two water rods, The fuel assembly, wherein the long fuel rod loaded with the flammable poison-containing pellet is disposed at a position excluding a position adjacent to both the outermost peripheral portion and the two water rods.   When the fuel rod loaded with the flammable poison pellets is divided into two regions in the axial direction, the fuel rod loaded with the flammable poison pellets in the first region is the flammable poison in the second region. The fuel rods that are not loaded with pellets and vice versa are loaded with flammable poison pellets in the second region, and are not loaded with flammable poison pellets in the first region. The fuel assembly according to claim 1. In a fuel assembly for a boiling water reactor having a water rod in which a large number of fuel rods including fuel rods containing flammable poisons are arranged in a square lattice and water flows inside,
The fuel rods adjacent to the outermost fuel rods and the water rods of the fuel assembly are not loaded with flammable poison pellets in the cladding tube, and the fuel rods are adjacent to the outermost fuel rods. The fuel rods adjacent to the fuel rods adjacent to the water rods are filled with flammable poison-containing pellets in at least a part of the cladding tube in the axial direction.   A fuel rod loaded with pellets containing flammable poisons excluding fuel rods loaded with pellets containing flammable poisons at the corner position of the second layer from the outer periphery of the fuel assembly is a flammable poison in a horizontal cross section of the fuel assembly. When divided into two regions in the axial direction with reference to the position where the fuel rod is present, among the regions where the fuel rod containing the combustible poison is present, the pellet containing the combustible poison is loaded in the first region. Fuel rods are not loaded with flammable poison pellets in the second region, and vice versa, fuel rods loaded with flammable poison pellets in the second region are flammable poisons in the first region. The fuel assembly according to claim 3, wherein the pellets are not loaded.   The flammable toxic fuel rod pellets of the first region and the second region are the largest in the fuel rod pellets of the fuel assemblies of the first region and the second region, respectively, with respect to the concentration of fissile material. The fuel assembly according to claim 2 or 4, wherein the fuel assembly is not. In a fuel assembly for a boiling water reactor having two water rods, in which a plurality of fuel rods including fuel rods loaded with pellets containing flammable poisons are arranged in a square lattice and water flows inside,
The fuel rods at the outermost peripheral portion of the fuel assembly do not have pellets containing flammable poisons in the cladding tube, and all the fuel rods at positions other than the outermost peripheral portion are at least partially in the axial direction in the cladding tube. Combustion poison-filled pellets are loaded, and fuel rods adjacent to both of the two water rods are loaded with combustible poison-filled pellets almost axially in the cladding tube, and both of the two water rods are loaded. A fuel assembly in which a fuel rod loaded with a combustible poison-containing pellet other than an adjacent fuel rod is loaded with a combustible poison-containing pellet below or above the center in the axial direction in the cladding tube.   Except for fuel rods loaded with flammable poison pellets adjacent to both of the two water rods, fuel rods loaded with flammable poison pellets are present in the fuel assembly horizontal cross section. When divided into two regions in the axial direction with respect to the position, the fuel rods loaded with flammable poison pellets in the first region are not loaded with flammable poison pellets in the second region, 7. The fuel assembly according to claim 6, wherein, conversely, fuel rods loaded with combustible poison pellets in the second region are not loaded with combustible poison pellets in the first region. .   8. A part of fuel rods loaded with combustible poison-containing pellets in the second region are short fuel rods having an effective fuel length only in the second region. Fuel assembly.   The first region is located above the second region, and the upper end of the second region is located above the axial center of the fuel assembly. 8. The fuel assembly according to any one of 8.

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