JP2009222617A - Bleedable nuclear fuel assembly using non-plutonium-based nuclear fuel, and core of light water-cooled bwr - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a reactor of low Pu generation by improving the core of a BWR under operation. <P>SOLUTION: Pellets having higher degree of U233 enrichment is filled into the upper part of a TMOX obtained by easy reprocessing, and pellets where enriched uranium is added to Th are deposited and filled in the bottom part, and a thorium-based nuclear fuel assembly 130, where many thorium-based nuclear fuel rods 131 are arranged in a square form and a boronized titanium control rod 101 are loaded in the core of the BWR currently in operation. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a nuclear fuel assembly that can be loaded into the core of a BWR (Boiling Water Reactor).

FIG. 1 is a structural diagram of the core of a boiling water reactor (Non-Patent Document 1). The lower end of the nuclear fuel assembly (30) containing the nuclear fuel material is supported by a detachable nuclear fuel support fitting (2) mounted on the core support plate (1), and the upper end via a channel box (35). It is made to lean also on the upper lattice plate (3). In the center of the four nuclear fuel assemblies (30) between the lattices of the upper lattice plate (3), there is a control rod (100) that controls the nuclear reactor by moving up and down. Most control rods (100) are drawn to the bottom of the core during operation. Although it is assumed that the nuclear fuel assembly (30) and the control rod (100) are exchanged once every several years, it is not easy to exchange the core support plate (1) and the upper lattice plate (3). Major changes are difficult.
FIG. 2 is a schematic perspective view of the nuclear fuel assembly (30) (Patent Document 1). Cylindrical nuclear fuel rods (31) enclosing nuclear fuel materials arranged in a large number of square lattices, and upper and lower coupling plates (32) and (33) supporting the upper and lower ends thereof, respectively. ), Spacers (34) that are located in the middle of the height of the nuclear fuel rods (31) to regulate the spacing between the nuclear fuel rods (31), and a channel box (35) that covers these on four sides. Is done. Water as a coolant enters the channel box (35) from the bottom of the core and receives heat from the nuclear fuel rod (31) to generate steam. Vapor is called a void, and the (ratio of vapor) / (ratio of vapor + percentage of liquid water) at a certain height in the channel box (35) increases as it goes upward.
FIG. 3 is a longitudinal sectional view of a conventional nuclear fuel rod (31). Zircaloy cladding tube (41), upper end plug (42) and lower end plug (43) hermetically closing the upper and lower opening ends of the cladding tube (41), spring (45), upper plenum (48), And a large number of nuclear fuel pellets (44) formed by sintering oxide of enriched uranium, which is a nuclear fuel, into a cylindrical shape in a cladding tube (41).
FIG. 4 is a partial core plan view in which a conventional nuclear fuel assembly (30) and a control rod (100) are arranged at a height where the spacer (34) is not located. In the core of the nuclear reactor, the nuclear fuel assemblies (30) are arranged in a grid with a leakage material passage (51) on the control rod side and a leakage material passage (52) on the opposite side of the control rod. A coolant passage (49) is formed between the nuclear fuel rods (31). A water rod (70) may be arranged in place of several nuclear fuel rods (31) at the center. The distance L between adjacent control rods (100) is determined at the time of reactor manufacture and can hardly be changed if there is a need for some modification of the reactor.
: Sho 61-37591, "Nuclear Fuel Assembly" : Nuclear Safety Research Association (ed.), 1998 “Light Water Reactor Fuel Behavior”.

The core of the nuclear reactor uses actinide as nuclear fuel. Actinide is a general term for elements of actinoids excluding actinium. Actinoid is a general term for 15 elements from actinium of atomic number 89 to lorencium of 103. In the nuclear fuel pellet (44) of the conventional nuclear fuel rod (31), uranium 235 (U235), which is easy to fission out of uranium with atomic number 92, which is a member of the actinide, is concentrated to about 5%, and the remaining 95% is thermal neutron On the other hand, it was filled with an oxide of enriched uranium composed of uranium 238 (U238) which does not fission.
In recent years, nuclear power generation without greenhouse gas emissions has been reviewed due to environmental problems, and soaring uranium ore prices have become a problem.
Nuclear reactors that efficiently burn uranium via plutonium (Pu) produced by conversion from uranium may be subject to international restrictions on future development as Pu may be used for nuclear weapons , Development must be careful. In addition, as a result of power generation by nuclear power, the accumulated number of spent nuclear fuel assemblies (30) containing a large amount of Pu is enormous. In particular, problems have arisen in the treatment of plutonium (Pu).

One of the actinides is uranium 233 (U233), a fissile material. U233 is produced by conversion from thorium (Th) of atomic number 90 which is one of actinides. Th has low ore cost and large quantity. Th and U233 also generate actinides (plutactinium (Pa), uranium 232 (U232), miscellaneous actinides such as U235 (actinides other than Th and U233).
Fig. 5 shows the kinetic energy of neutron velocity (hereinafter simply referred to as η, the number of fission neutrons released per neutron absorbed by the nuclear material), which is a measure of the fission efficiency of U233, a fissile material. It is the figure which showed the dependence (it is called neutron energy) (nonpatent literature 2). Η of U233 shows a high value regardless of neutron energy and efficiently fissions. Reactor with U233 and Th as nuclear fuel is a breeding reactor or a high conversion ratio with a conversion ratio that is the ratio of the number of fissile material that does not multiply but is consumed every time one fissile material is consumed. It can be considered as a nuclear reactor.
Reduced-speed spectrum reactor (shortened reduced-speed reactor) aimed at breeding reactors or high-conversion-reactor reactors that are equipped with Pu as nuclear fuel by improving the core of the current BWR without a long development period and cost. Patent Document 3) is drawing attention. If U233 and Th are used as nuclear fuel for a nuclear reactor with a densely built-in nuclear fuel, such as a low-speed reactor, if it can be made into a breeding reactor or a high conversion ratio nuclear reactor, nuclear power generation with low regulations on nuclear weapons and low fuel costs can be implemented.
Since U233 is not found in nature, it is produced by adding highly enriched uranium to Th. Gas fission products and liquid fission products that are easy to process in the spent nuclear fuel are separated and discarded, and the remaining Th, U233, miscellaneous actinides, and solid fission products are reused as nuclear fuel without separation. A mixed oxide containing U233 oxide converted from Th with Th oxide as the main component will be called TMOX in the future.
In order to reduce the effect of solid fission products that reduce thermal reactivity by absorbing thermal neutrons, the core of a nuclear reactor with dense nuclear fuel will be used. The nuclear fuel assembly (30) is improved and loaded into the core of the current BWR in order to realize a nuclear reactor core with densely built-in nuclear fuel without significantly changing the core structure of the current BWR. Although the reprocessing cost is high, it is possible to extract only U233 from the spent nuclear fuel in which highly enriched uranium is added to Th and to make it a U233-containing nuclear fuel mainly composed of Th.
Thorium-based nuclear fuel pellets (132) with a diameter of 1 cm to 1.3 cm where U233 enrichment is the main component of TMOX and contains miscellaneous actinide oxides as well as solid fission products. The cladding tube (1041) is deposited and filled. At that time, the enrichment level of the upper thorium-based nuclear fuel pellet (132) is increased, and the bottom is deposited with a highly enriched uranium-added thorium-based fuel pellet (133) obtained by adding a highly enriched uranium oxide to the oxide of Th. A thorium-based nuclear fuel assembly (130) in which a large number of thorium-based nuclear fuel rods (131) are densely arranged in a square with a gap of 1 mm to 1.3 mm is loaded into a BWR core for light water cooling.
FIG. 6 shows the dependence of neutron energy on the fission cross section of U233. Since the capture cross section is smaller than the fission cross section, the output behavior is almost determined by the fission cross section behavior. The fission cross section monotonously decreases as neutron energy increases at a few eV.
Since the neutron flux in the core of a nuclear reactor with dense nuclear fuel is larger in the range of 1 eV to 10 eV than in a conventional thermal neutron reactor, the fission rate proportional to the product of the fission cross section and neutron flux is 1 eV to 10 eV. The contribution from the range is large.
When a void is generated in a reactor core containing U233 as a nuclear fuel densely due to a coolant loss accident, etc., the neutron flux decreases near 10 eV and increases at an energy higher than 10 eV, so the fission reaction decreases. Therefore, the void reactivity coefficient is greatly negative.
In order to secure the reactor shutdown margin, it is effective to attach gadolinium, which is a flammable poison with a large capture cross section at neutron energy of 10 eV or less, to the nuclear fuel rod or the channel box (35).
The coolant in the BWR core has a two-phase flow in which the void is zero at the lower end and the void is 60% or more at the upper end. When the nuclear fuel pellet diameter is around 1.2 cm and the enrichment of U233 is around 3%, the kinf is high and the conversion ratio is high, but the kinf is too large in the lower part where there are few voids and many liquids. , And increase the U233 enrichment because kinf becomes too small at the upper part with many voids and little liquid. Highly enriched uranium-added thorium-based nuclear fuel in which the oxide of Th is added to the oxide of Th at the bottom of thorium-based nuclear fuel rod (131) in consideration of the case where U233 is insufficient to maintain combustion for a long period of time Pellet (133) is deposited and filled.
In summary, the diameter of the actinide oxide based on TMOX, a mixed oxide enriched with 2 to 5% of U233 in Th, containing less than 10% solid fission product is 1.1cm to 1.3cm. Thorium-based nuclear fuel pellets (132) of cm are thickly packed into the large-diameter cladding tube (1041) by increasing the U233 enrichment, and at the bottom is highly enriched by adding highly enriched uranium oxide to Th oxide. Thorium-based nuclear fuel rods (131) characterized by being deposited and filled with uranium-added thorium-based nuclear fuel pellets (133) and numerous thorium-based nuclear fuel rods (131) arranged in a square with a gap of 1 mm to 1.3 mm A thorium-based nuclear fuel assembly (130) characterized by the above is introduced into the core of the BWR to make a reactor with little Pu production.
A titanium boride control rod (101) in which a titanium boride core (113) at the center is coated with an outer sheath (112) of titanium or nickel base alloy is introduced into the core of the BWR, while maintaining the control performance of the nuclear reactor. Reactor with low generation
A control rod center side pad (141) and an upper grid plate side pad (142) are attached to one side of the control rod side channel box of the thorium-based nuclear fuel assembly (130) around the titanium boride control rod (101). The thorium-based nuclear fuel assembly (130) is arranged in a rotationally symmetrical manner to maintain a light-water cooled BWR core while maintaining the seismic resistance of the reactor so that Pu is not generated.
Split control rod blades with four split control rod blades (202) containing a neutron absorber having a length slightly shorter than the shortest distance between the control rod center pad (141) and the upper grid plate side pad (142) at the lower end A quadrant control rod (201), which is connected by the bottom connecting plate (202) and can move upward beyond the upper end of the channel box (35), is introduced into the BWR core to maintain the control performance of the reactor However, the reactor will produce less Pu.
Thorium-based nuclear fuel in which thorium-based nuclear fuel rods (131) each having a diameter of 1.1 cm to 1.3 cm and filled with thorium-based nuclear fuel pellets (132) deposited to a length of 260 cm or less are arranged in a square with a gap of 1 mm to 1.3 mm When the positions of the spacers (34) in the assembly (130) are positioned at two locations, that is, the height of the central portion of the thorium-based nuclear fuel pellet (132) to be deposited and filled and the top right of the thorium-based nuclear fuel pellet (132) to be deposited and filled. Reactor with less burden on cooling water circulation pump and less generation of Pu with good U233 conversion efficiency.
The thorium-based nuclear fuel pellet (132) may be a nuclear fuel pellet made of highly enriched uranium oxide or a mixed oxide of Pu and uranium, and the thorium-based nuclear fuel rod (131) is a mixture of highly enriched uranium oxide or Pu and uranium. Nuclear fuel rods filled with nuclear fuel pellets made of oxide may be used, and thorium-based nuclear fuel assemblies (130) have a large number of nuclear fuel rods filled with highly enriched uranium oxide and nuclear fuel pellets made of mixed oxide of Pu and uranium. It may be a nuclear fuel assembly arranged in the form of
Therefore, a spacer (34) in which a large number of nuclear fuel rods, in which nuclear fuel pellets made of nuclear fuel having a diameter of 1.1 cm to 1.3 cm are deposited and filled in a cladding tube to a length of 260 cm or less, are arranged in a square with a gap of 1 mm to 1.3 mm. The core of a light water cooled BWR loaded with a nuclear fuel assembly is located in two locations: the central height of the nuclear fuel pellet to be deposited and placed directly above the top of the nuclear fuel pellet to be deposited and filled. The reactor will be less loaded with pumps and less wasted neutron absorption.
: 1964, CONSULTANTS BUREAU, Abagyan, “Group Constants For Nuclear Reactor Calculations” : JAERI-Conf2002-012, "5th Study Group Report on Reduced-Speed Spectrum Reactor".

By changing the nuclear fuel assembly (30) and control rod (100) without significantly changing the structure of the core of the current BWR, Pu will be used as the core of a nuclear reactor loaded with a nuclear fuel assembly containing TMOX as a nuclear fuel. Since it can be made into a nuclear reactor that is difficult to generate, it can be backfitted to the core of the current BWR and at the same time exported as a nuclear reactor that is difficult to generate Pu.
Like U238, Th, the parent substance of U233, has a strong neutron absorption action and a negative void reactivity coefficient. Th that has absorbed neutrons is converted to U233. The fission cross section of U233 has a strong property of making the void reactivity coefficient negative because it decreases as neutron energy increases at a few eV. Therefore, the core of a nuclear reactor that uses U233 and Th as nuclear fuel has a negative void reactivity coefficient, so it is highly safe even if the number of voids increases due to a loss of coolant accidents. Since η of U233 is 2.0 or more over almost the entire energy, extra neutrons are generated by Th and absorbed into Th to convert to U233, even if burning accompanied by fission is generated by neutron absorption. Can be a breeder reactor.
Conventional breeder reactors using U233 and Th as nuclear fuels used thermal neutrons as a coolant with heavy water having a small neutron absorption effect and a large neutron moderation effect. However, since heavy water generates tritium, which is a radioactive substance, environmental considerations are necessary, and handling is necessary because heavy water is a hydrogen bomb-related substance or Pu production-related substance. It is difficult.
The thorium-based nuclear fuel assembly (130) of the present invention has reduced the coolant passage (49) through which light water passes by narrowing the arrangement gap of the thorium-based nuclear fuel rods (131) adopting nuclear fuel pellets having a large diameter. The proportion of light water with relatively large neutron absorption decreased and the proportion of neutrons absorbed by Th and converted to U233 increased. Furthermore, the decrease in the proportion of light water, which is also a moderator, increases the rate of fast neutrons, so the rate of absorption of thermal neutrons absorbed by fission products decreases and the proportion of neutrons absorbed by Th and converted to U233. Increased. The ratio of neutron absorption by reducing the proportion of light water by expanding the channel box (35) to the leakage material passage (52) on the side opposite to the control rod. Increased.
If the U233 enrichment is close to 3%, the kinf is high and the conversion ratio is also high. Therefore, if the U233 enrichment lower limit is 2%, the upper limit is 5%, and the U233 enrichment is higher at the top, the kinf The distribution in the height direction is flattened and the output distribution is flattened. In view of the soundness of nuclear fuel rods, there is an upper limit for the line power density. If the line power density is locally increased, a predetermined reactor power may not be obtained. If the power distribution is flattened, the linear power density is also flattened, and power can be generated uniformly in the length direction of the nuclear fuel rods, making it easy to obtain a predetermined reactor power.
In the reactor core, there are many fast neutrons and few thermal neutrons, so even if solid fission products are contained in the nuclear fuel, it does not become a big problem. Since the thorium-based nuclear fuel pellet (132) used as the nuclear fuel without separating the actinide oxide and the solid fission product can be used as the nuclear fuel, the reprocessing of the spent nuclear fuel is simplified and the cost can be reduced.
In order to compensate for the decrease in TMOX due to combustion, high-concentration uranium-added thorium-based nuclear fuel pellets (133), in which high-concentration uranium oxide is added to Th oxide, are additionally deposited and filled at the bottom of thorium-based nuclear fuel rod (131) As a result, a new reprocessing step for separating and extracting U233 is not required, and even a core using TMOX as a nuclear fuel does not increase the cost significantly.
When the four-part control rod (201) is introduced into the core of the BWR, the length of the nuclear fuel portion of the thorium-based nuclear fuel assembly (130) in which the weight of one fuel assembly is equivalent to the conventional one is about 260 cm. Even if it is introduced into the BWR core, it can be pulled out. Insertion allows dropping by its own weight, and even if power is lost, the control rod is inserted into the core of the reactor and it becomes easier to stop the reactor more reliably.
Thorium-based nuclear fuel rods (131) that are thick and short with a thorium-based nuclear fuel pellet (132) having a diameter of 1.1 cm to 1.3 cm deposited and filled to a length of 260 cm or less are difficult to vibrate and difficult to bend. A large number of thorium-based nuclear fuel rods (131) are located at two locations, a central spacer (136) positioned at the height of the center of the nuclear fuel pellet (132) and an upper spacer (137) positioned immediately above the upper end. ) Is a thorium-based nuclear fuel assembly (130) arranged in a square of 1 mm to 1.3 mm.
Even though the thorium-based nuclear fuel rods (131) were made thicker, the gaps were narrowly arranged at 1mm to 1.3mm, so the distance between adjacent control rods (100) fixed by the core of the conventional BWR was set to L. 2 = The number of thorium-based nuclear fuel rods (131) that can fit in 15.5cm can be increased, and if the weight of nuclear fuel is maintained at a conventional level, the number of thorium-based nuclear fuel pellets (132) will be reduced and filled, resulting in a shorter overall length. The number of spacers (34) can be reduced. As a result, the pressure loss of the cooling water proportional to the number of spacers (34) can be reduced and the burden on the circulation pump can be reduced, and the neutron absorption ratio proportional to the number of spacers (34) can be reduced to reduce the U233 enrichment. Can be reduced. Since the number of the substantial spacers (34) is one in the place where the nuclear fuel pellet is present, the neutron absorption ratio is extremely reduced.

  A BWR core that is currently in operation can be expected to have a high conversion ratio with low reprocessing costs, without any structural changes other than replaceable nuclear fuel assemblies and control rods. The core could be provided.

FIG. 7 is a longitudinal sectional view of the thorium-based nuclear fuel rod (131) of the present invention. Thorium-based nuclear fuel rods (131) contain less than 10% solid fission products in the oxides of actinides based on TMOX, a mixed oxide enriched with 2 to 5% U233 in Th. Thorium-based nuclear fuel pellets (132) having a diameter of 1.1 cm to 1.3 cm are deposited and filled in a large diameter cladding tube (1041). U233 high enrichment thorium-based nuclear fuel pellets (134) with high U233 enrichment are deposited and filled in the upper part, and thorium-based nuclear fuel pellets (132) with a moderate U233 enrichment in the middle. The bottom is formed by depositing and filling highly enriched uranium-added thorium-based nuclear fuel pellets (133) obtained by adding highly enriched uranium oxide to Th oxide.
In order to obtain U233 that does not exist in nature, a nuclear fuel in which U235 is added to Th is burned, and a part of Th is converted to U233. It immediately comes to mind that U233 is extracted by reprocessing the spent nuclear fuel, but the reprocessing cost is considered high. Therefore, simple reprocessing that removes gaseous fission products and liquid fission products from the spent nuclear fuel (non-actinide solid fission production in addition to oxides of actinides containing TMOX as a main component and miscellaneous actinides) 10% or less may be contained, ferromagnetic materials such as iron can be easily separated with magnets, light elements are floated, and low-melting elements can be easily removed at elevated temperatures, so less than 5% Can be reused as nuclear fuel with TMOX as the main component. In particular, Pa is not wasteful because it naturally collapses to U233. It can be operated for many cycles by adding a small amount of highly enriched uranium.
The life of nuclear fuel rods in the BWR core is about 40,000 MWd / t. When the burnup becomes 40,000 MWd / t, the TMOX weight of nuclear fuel decreases by about 4% of the TMOX weight of the initially loaded nuclear fuel, so the TMOX weight in the spent nuclear fuel is about 96% of the TMOX weight of the initially loaded nuclear fuel, The nuclear fuel itself is as good as new. A solid containing a non-actinide solid fission product in the oxide of TMOX-based actinide is processed into a thorium-based nuclear fuel pellet (132). The total weight of thorium-based nuclear fuel pellets (132) (TMOX-based actinide oxides + non-existing) even if there is removal of solid fission products of non-actinides that have become excessive due to repeated simple reprocessing or loss during processing The actinide solid fission product) is about 90% of the total weight of the initially loaded nuclear fuel. If the non-actinide solid fission product is 10% or less, it can be reused as nuclear fuel.
The shortage of the total weight of the first loaded nuclear fuel is compensated by adding highly enriched uranium oxide to Th oxide. That is, a highly enriched uranium-added thorium-based nuclear fuel pellet (132) is deposited and filled at the bottom of the thorium-based nuclear fuel rod (131). For example, when 10% of 20% enriched uranium is added to Th, about 2% of the fissile material U235 is added.
When the weight of the thorium-based nuclear fuel assembly (130) is equivalent to the weight of one conventional fuel assembly, the length of the nuclear fuel part is about 260 cm, and the extraction burnup is 40,000 MWd / t. Will be 96%, which is a 4% decrease in the TMOX weight of the first loaded nuclear fuel. This decrease can be compensated by depositing and filling highly enriched uranium-added thorium-based nuclear fuel pellets (132) at 260 cm × 0.04 = 10.4 cm.
FIG. 8 is a plan view of a thorium-based nuclear fuel assembly (130) according to the present invention in which a large number of thorium-based nuclear fuel rods (131) are arranged in a square with a gap of 1 mm to 1.3 mm. The conventional water rod (70) was removed and a thorium-based nuclear fuel rod (131) was placed instead. The area of the coolant passage (49) occupying the gap of the cladding tube by densely arranging the thorium-based nuclear fuel rods (131) formed by filling the large diameter cladding tube (1041) with thick pellets having a diameter of 1.1 cm or more Decreased. The proportion of light water with relatively large neutron absorption decreased and the proportion of neutrons absorbed by Th and converted to U233 increased. Furthermore, the decrease in the proportion of light water, which is also a moderator, increases the rate of fast neutrons, so the rate of absorption of thermal neutrons absorbed by fission products decreases and the proportion of neutrons absorbed by Th and converted to U233. Increased.
FIG. 9 is a partial core plan view in which the thorium-based nuclear fuel assembly (130) of the present invention and the titanium boride control rod (101) of the present invention are arranged at a height where the spacer (34) is not located. . A titanium boride control rod (101) characterized in that an outer surface is coated with an outer sheath (112) of titanium or nickel alloy around a titanium boride core (113) made of titanium boride (TiB ₂ ). The four thorium-based nuclear fuel assemblies (130) were arranged around. In the figure, A, B, C, D, E, and F are for associating the positional relationship with the nuclear fuel assembly in the figure to be shown later.
The channel box (35) has been expanded within the range in which the length L between the control rod centers can be maintained at the core length of the conventional BWR, so that the leakage material passage (51) area on the control rod side and the opposite side of the control rod Leakage material passage (52) area was reduced. The proportion of water, which is also the moderator, is reduced accordingly, so the rate of fast neutrons increases and the conversion ratio increases.
On the other hand, since it is necessary to reduce the thickness of the control rod without reducing the neutron absorption ability, the titanium boride control rod (101) was used. Since the boron, which is a neutron absorber, can be arranged with high density by the plate-like titanium boride, even if the thickness of the control rod is reduced, it is possible to prevent a decrease in neutron absorption ability. Hydrogen in light water, which is a coolant, has the highest neutron decelerating property among materials, so fast neutrons generated from nuclear fuel immediately become thermal neutrons. Thermal neutrons are absorbed by boron.
Titanium or nickel constituting the outer sheath (112) of the outer surface has a higher neutron absorption action than iron, and therefore the neutron absorption capability is further enhanced. Since both boron and titanium constituting the titanium boride control rod (101) are light, the number of driving devices for operating the control rod up and down can be reduced.
Since the thorium-based nuclear fuel assembly (130) of the present invention has few thermal neutrons and the conversion ratio to U233 is around 1.0, the U233 enrichment in the spent nuclear fuel is almost the same as the U233 enrichment in the initially loaded nuclear fuel. It is. Even if the U233 enrichment in the spent nuclear fuel is lower than the U233 enrichment in the initially loaded nuclear fuel, combustion of about 40,000 MDd / t can be achieved by adjusting the amount of highly enriched uranium added at the bottom. Can do.
Fig. 10 shows the cooling of a thorium-based nuclear fuel rod (131) filled with a zirconium alloy cladding tube with a diameter of 1.2 cm and a TMOX nuclear fuel pellet with a U233 enrichment of 3% arranged infinitely with a gap of 1 mm. It is the figure which showed the burnup dependence of the kinf and U233 enrichment at the time of changing the void ratio of a material from 0% to 60%. If the void increases, the kinf decreases, but the burning of U233 decreases. At 60% voids, U233 increases with combustion and proliferates, but kinf quickly drops below 1.0. Due to the high voids, there is less neutron moderation and the large fission reaction at low energy is reduced, and due to neutron absorption due to the generation of Pa. If the void is reduced, the opposite of what is described for the 60% void occurs.
If thorium-based nuclear fuel rods (131) filled with U-rich TMOX nuclear fuel pellets with a diameter of 1.2cm and filled in a zirconium alloy cladding tube are arranged with a gap of 1mm, combustion will be about 40,000 MDd / t Can be achieved. However, the difference in kinf between the lower part of the core where the void ratio of the coolant is 0% and the upper part of the core where the void ratio is 60% is too large. Therefore, if the U233 enrichment is increased in the upper part with more voids, the output is flattened.
FIG. 11 is a diagram showing the burnup dependence of kinf and U233 enrichment when the U233 enrichment is 5% and 2%. If it becomes 5%, even if it becomes a high void, kinf will exceed 1.0, and the burnout accompanying the combustion of U233 will be insignificant. If it is 2%, the kinf will exceed 1.0 if the void is low, and the U233 enrichment is low, so the burning caused by the combustion of U233 will be negligible.
10 and 11, if the U233 enrichment is lowered at the lower part of the void and the U233 enrichment is raised at the upper part of the void, the degree of burnup is high and the burning caused by the combustion of U233 is kept low. be able to. The lower limit of U233 enrichment is 2%, where kinf exceeds criticality 1.0. The upper limit of U233 enrichment is 5% because it is sufficient if the kinf is critical 1.0 at 60% voids and 40,000 MDd / t, which is equivalent to the burnup of conventional U235 fuel.
The upper figure of Fig. 12 shows a case where the U233 enrichment is 3%, the void is 40%, the thorium nuclear fuel rod (131) gap is fixed at 1mm, and the thorium nuclear fuel pellet (132) diameter is 1.1cm and 1.3cm. Shows the burnup behavior of kinf and U233 enrichment. Although there is no big difference in kinf, if the diameter is reduced to 1.1 cm, the proportion of water as the moderator is relatively increased, so that the burning out of U233 is increased.
If the pellet diameter is 1.1 cm or less, it will be necessary to increase the amount of highly enriched uranium in order to produce the next nuclear fuel by simple reprocessing.
If the pellet diameter is 1.3cm or more, it will not be possible to load more than 8X8 nuclear fuel rods within the range of L / 2 = 15.5cm. The larger the number of nuclear fuel rods, the better from the viewpoint of ensuring the linear power density within the conventional limits.
When the U233 enrichment is 3%, the void is 40% and the thorium nuclear fuel pellet (132) is fixed at 1.2 cm in diameter, and the thorium nuclear fuel rod (131) gap is 1 mm and 1.3 mm, the kinf and U233 enrichment The figure below shows the burnup behavior. When the gap between the thorium-based nuclear fuel rods (131) is increased to 1.3 mm, the proportion of water as a moderator increases relatively, so kinf is large in the early stage of combustion, but there is no difference in the late stage of combustion. Burnout increases. When the gap between the thorium-based nuclear fuel rods (131) is 1.3 mm or more, the amount of highly enriched uranium must be increased in order to prepare the next nuclear fuel by simple reprocessing. Thorium-based nuclear fuel rod (131) gaps of 1 mm or less are expected to cause heat removal problems.
TMOX decreases when burning 40,000 MWD / t. The amount is supplemented with a highly enriched uranium-added thorium-based nuclear fuel pellet (133) obtained by adding a highly enriched uranium oxide to a Th oxide. Since the lower part has low voids, the conversion ratio is low and U233 burns out severely. Therefore, highly enriched uranium is introduced from the outside to compensate for the lack of fissile material.
A thorium-based nuclear fuel assembly (130) containing TMOX with a U233 enrichment of around 3% has a burnup of 40,000 MWD / t and a high conversion ratio. In a 4-batch exchange BWR core, the U233 enrichment can be lowered by reducing the coolant flow rate and operating at high voids and lowering the burnup degree to about 30,000 MWD / t. The growth of U233 is considered possible.
The dense arrangement of nuclear fuel rods filled with thick pellets increases the weight of the nuclear fuel per unit volume, so the denominator of the burnup MWd / t increases and the burnup itself tends to decrease. MWd, which is the cumulative calorific value directly connected to, is equivalent to or increased in the current BWR core.
In order to suppress a large kinf in the early stage of combustion, a flammable poison is added to the thorium-based nuclear fuel pellet (132) of several thorium-based nuclear fuel rods (131), as was done in the core of a conventional BWR. What is necessary is just to add the gadolinia (Gd2O3) which is.
If reprocessing with an organic solvent is not performed or simple reprocessing is performed as much as possible, reprocessing costs are reduced. Actinides other than Th and U233 are also reprocessed into fuel and burned, so they are not turned into waste, and waste disposal costs are reduced. Since there is almost no generation of Pu, no problems related to nuclear non-proliferation occur.
Highly enriched uranium oxide is added to the core of the newly constructed nuclear reactor at the top in the highly enriched uranium-added thorium-based nuclear fuel pellet (133) in which highly enriched uranium oxide is added to Th oxide. If the thorium-based nuclear fuel rod (131) is used, there is no need to newly establish a reprocessing facility for U233 extraction.
Nuclear fuel or nuclear fuel made from thorium-based nuclear fuel assembly (130), burned in Japan with Th oxide added with Pu oxide and processed into TMOX consisting of U233 and Th from the spent nuclear fuel Exporting aggregates will reduce proliferation problems.

FIG. 13 is a view at the upper end of the partial core plan view in which the thorium-based nuclear fuel assembly (130) and the titanium boride control rod (101) shown in FIG. 9 are arranged. Four thorium-based nuclear fuel assemblies (130) were arranged around the titanium boride control rod (101) in rotational symmetry. There are two channel boxes (35) facing the control rod side of the thorium-based nuclear fuel assembly (130), but the control rod center side pad (141) and the upper grid plate side pad (142) are attached to only one side. It was. In the figure, A, B, C, D, E, and F are for associating the positional relationship with the nuclear fuel assemblies in the figures that appear in the front and rear. A gap is secured between the upper grid plate side pad (142) and the control rod center side pad (141) between adjacent nuclear fuel assemblies. The pad thickness is greater than the control rod thickness. The reason why the tip of the control rod center side pad (141) protrudes beyond the channel box (35) is to secure a gap with the nuclear fuel assemblies adjacent in the diagonal direction. If four thorium-based nuclear fuel assemblies (130) each having a control rod center pad (141) and an upper grid plate side pad (142) are arranged rotationally symmetrically, a function of securing a gap with the nuclear fuel assembly can be obtained. It is done.
FIG. 14 is a longitudinal sectional view of the thorium-based nuclear fuel assembly (130) with the control rod center side pad (141) and the upper grid plate side pad (142) attached, as viewed from the control rod side. B and C in the figure are for associating the positional relationship with the nuclear fuel assembly in FIG. If the length of the thorium-based nuclear fuel rod (131), whose weight per unit length is about twice that of the conventional one, is about half that of the conventional nuclear fuel rod because the nuclear fuel is densely arranged, the fuel assembly Problems related to replacement cranes and core support are unlikely to occur. Since the length of the control rod can be halved, no problem occurs even if the control rod central pad (141) is positioned on the control rod. The vertical movement of the titanium boride control rod (101) is performed by a driving device connected to the lower end of the extension rod (111).
In addition, the spacer (34) for ensuring the gap | interval of a thorium type nuclear fuel rod (130) is the upper end spacer (137) arrange | positioned in the upper end height of U233 highly enriched thorium type nuclear fuel pellet (134), and thorium type nuclear fuel pellet. The central spacer (136) disposed at the central height of the entire length of (132) deposited and filled is two places. Since the thorium-based nuclear fuel rod (130) is thicker and shorter, vibration caused by coolant flow or the like is small, and it is considered that bending caused by thermal expansion or the like is considered to be small. The smaller the number of spacers (34) that provide flow resistance and absorb neutrons, the better.

When inserting the control rod into its own weight to increase the failsafe, it is necessary to pull up the control rod during normal operation. If the length of the thorium-based nuclear fuel assembly (130) is about half or less of the length of the conventional nuclear fuel rod, there is no problem even if the control rod central pad (141) is positioned on the control rod. However, some control is necessary because the control rod cannot be operated with a length of more than half.
FIG. 15 is an overview of the 4-split control rod (201). The split control rod blade (202) containing the neutron absorber is coupled at the lower end by the split control rod blade bottom coupling plate (203). There is a gap between the four split control rod blades (202). Split control rod blades with four split control rod blades (202) containing a neutron absorber having a length slightly shorter than the shortest distance between the control rod center pad (141) and the upper grid plate side pad (142) at the lower end It can be joined by the bottom joining plate (203) and moved up beyond the upper end of the channel box (35).
An extension rod (111) is connected under the split control rod blade bottom coupling plate (203) and can be moved up and down by a driving device. If one part is a zirconium alloy follower instead of the extension rod (111) extended under the split control rod blade bottom coupling plate (203), the water in the leakage passage (51) on the control rod side is eliminated. The introduction control rod center side pad (1411) shown in FIG. 17 is also unnecessary.
FIG. 16 is a diagram at the upper end of the partial core plan view in which the thorium-based nuclear fuel assembly (130) and the four-divided control rod (201) are arranged when the control rod is pulled up during normal operation. In the figure, A, B, C, D, E, and F are for associating the positional relationship with the nuclear fuel assembly in FIG.
The four-divided control rod (201) is divided into four with the control rod center side pad (141) as the center. Therefore, the quadruple control rod (201) can move upward beyond the upper end of the core plan view, that is, the upper end of the channel box (35), even if the control rod central side pad (141) is present. When the bundle restraining metal fitting (300) is attached to the place where the upper lattice plates (3) where the four thorium-based nuclear fuel assemblies (130) are adjacent to each other, the four thorium-based nuclear fuel assemblies (130) are mounted. Is restricted from shifting horizontally. Even if there is a large earthquake, the thorium-based nuclear fuel assembly (130) does not move laterally.
FIG. 17 is a longitudinal sectional view of the thorium-based nuclear fuel assembly (130) viewed from the four-divided control rod (201) side. B and C in the figure correspond to the positional relationship with the nuclear fuel assembly in FIG. One blade of the four-divided control rod (201) can be seen in the back of the control rod central pad (141).
An introduction control rod center pad (1411) is provided at the height of the upper plenum (48) under the control rod center pad (141). When the reactor is shut down, the control rod is lowered, and the upper end of the control rod protrudes above the introduction control rod central pad (1411).
FIG. 18 is a longitudinal sectional view of the thorium-based nuclear fuel assembly (130) viewed from the upper lattice plate (3) side. In the figure, D, E and F are for associating the positional relationship with the nuclear fuel assembly in FIG. One wing of the four-divided control rod (201) is visible behind the upper grid plate side pad (142).
The bundle restraint metal fitting (300) is provided with a bundle restraint metal claws (301) extending along the inside of the channel box (35) to restrain the thorium-based nuclear fuel assembly (130) from being laterally displaced.

Exporting BWRs that generate a relatively large amount of Pu to countries with atomic bombs is difficult due to proliferation problems. In the present invention, since the generation of Pu is relatively small, it is easy to export BWR. Furthermore, since Pu is unlikely to occur, Pu stock can be reduced rapidly and fissile material can be stored in U233, which is difficult to use as an atomic bomb.
Pu and Th mixed nuclear fuel may be misused by extracting Pu, but in the case of nuclear fuel with U235 added to U233 and Th mixed nuclear fuel, there is a problem of proliferation due to the small amount of Pu generated. hard.
Note that the U233 extraction step by reprocessing is unnecessary.

Overview of the core structure of a conventional boiling water reactor. The schematic perspective view of the conventional nuclear fuel assembly (30). The longitudinal cross-sectional view of the conventional nuclear fuel rod (31). FIG. 3 is a partial core plan view in which a conventional nuclear fuel assembly (30) and a control rod (100) are arranged at a height at which a spacer (34) is not located. Η value of fissile material. Kinetic energy dependence of neutron velocity of fission cross section. The longitudinal cross-sectional view of the thorium-type nuclear fuel rod (131) of this invention. The top view of the thorium type nuclear fuel assembly (130) of this invention. The partial core top view which arrange | positions the thorium-type nuclear fuel assembly (130) of this invention and the titanium boride control rod (101) of this invention in the height where the spacer (34) is not located. The figure which showed the burnup dependence of the kinf and U233 enrichment which used the void ratio as a parameter when the U233 enrichment is 3%. The figure which showed the burnup dependence of the kinf and U233 enrichment in case U233 enrichment is 5% and 2%. The figure above shows the burn-up behavior of kinf and U233 enrichment when the U233 enrichment is 3%, the void is 40%, and the thorium-based nuclear fuel pellet (132) diameter is 1.1cm and 1.3cm. The figure below shows the burnup behavior of kinf and U233 enrichment when the thorium-based nuclear fuel rod (131) gap is 1 mm and 1.3 mm. The top view of a partial core plane in which the thorium-based nuclear fuel assembly (130) and the titanium boride control rod (101) are arranged. The longitudinal cross-sectional view at the time of seeing from the control rod side the thorium system nuclear fuel assembly (130) which attached the control rod center side pad (141) and the upper lattice board side pad (142). An overview of the four-divided control rod (201). The top view of a partial core plane in which the thorium-based nuclear fuel assembly (130) and the four-part control rod (201) are arranged when the control rod is pulled up during normal operation. The longitudinal cross-sectional view at the time of seeing a thorium type nuclear fuel assembly (130) from the 4-part dividing control rod (201) side. The longitudinal cross-sectional view at the time of seeing a thorium type nuclear fuel assembly (130) from the upper lattice board (3) side.

Explanation of symbols

1 is a core support plate.
2 is a nuclear fuel support bracket.
3 is the upper grid plate.
30 is a conventional nuclear fuel assembly.
31 is a nuclear fuel rod.
32 is an upper coupling plate.
33 is a lower coupling plate.
34 is a spacer.
35 is a channel box.
41 is a cladding tube.
42 is an upper end plug.
43 is the bottom end plug.
44 is a nuclear fuel pellet.
45 is a spring.
48 is the upper plenum.
49 is a coolant passage.
51 is a leakage material passage on the control rod side.
52 is a leakage material passage opposite to the control rod.
70 is a water rod.
100 is a control rod.
101 is a titanium boride control rod of the present invention.
111 is an extension bar.
112 is an outer sheath.
113 is a titanium boride core.
130 is a thorium-based nuclear fuel assembly of the present invention.
131 is a thorium-based nuclear fuel rod of the present invention.
132 is a thorium-based nuclear fuel pellet.
133 is a highly enriched uranium-added thorium-based nuclear fuel pellet.
134 is a U233 highly enriched thorium-based nuclear fuel pellet.
136 is a center spacer.
137 is a top spacer.
141 is a pad on the center side of the control rod.
142 is an upper grid plate side pad.
201 is a 4-split control rod.
202 is a split control rod wing.
203 is a split control rod blade bottom coupling plate.
300 is a bundle restraint bracket.
301 is a bundle restraint bracket claw.
1041 is a large-diameter cladding tube.
1411 is a pad on the center side of the control rod for introduction.

Claims (4)

  Thorium with a diameter of 1.1 cm to 1.3 cm where the actinide oxide based on TMOX, a mixed oxide enriched with 2 to 5% U233 in U, contains less than 10% solid fission products The high-concentration uranium-added thorium is obtained by adding the U233 enrichment to the large-diameter cladding tube (1041) and depositing and enriching the nuclear fuel pellet (132) at the top, and adding the oxide of highly enriched uranium to the oxide of Th at the bottom. Characterized in that thorium-based nuclear fuel rods (131) and a large number of thorium-based nuclear fuel rods (131) are arranged in a square with a gap of 1 mm to 1.3 mm. Thorium-based nuclear fuel assembly (130).   Around the titanium boride control rod (101) and the titanium boride control rod (101) characterized in that the titanium boride core (113) in the center is coated with an outer sheath (112) of titanium or nickel base alloy 4 thorium-based nuclear fuel assemblies (100) comprising a control rod center side pad (141) and an upper grid plate side pad (142) attached to one side of the control rod side channel box of the thorium-based nuclear fuel assembly (130) of claim 1. 130) A light water cooled BWR core characterized in that it is arranged in rotational symmetry and maintains earthquake resistance.   Split control rod blades with four split control rod blades (202) containing a neutron absorber having a length slightly shorter than the shortest distance between the control rod center pad (141) and the upper grid plate side pad (142) at the lower end A quadrant control rod (201) characterized in that it can be joined by a bottom joining plate (203) and can move up beyond the upper end of the channel box (35).   The position of the spacers, in which a large number of nuclear fuel rods made of nuclear fuel with a diameter of 1.1 cm to 1.3 cm are deposited in a cladding tube with a length of 260 cm or less in a cladding tube and arranged in a square with a gap of 1 mm to 1.3 mm, are deposited. A nuclear fuel assembly characterized in that it is positioned at two locations, the height of the center of the nuclear fuel pellet to be filled and the top of the nuclear fuel pellet to be deposited and filled, and a light water cooled BWR characterized by loading the nuclear fuel assembly. Core.

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