JP2003344588A - Disposal container of radioactive waste, hanging tool of disposal container and containing method for radioactive waste in the disposal container - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disposal container for radioactive waste which can efficiently accommodate radioactive waste, can be efficiently contained in a disposal field and can exhibit functions for stably confining nuclides for a long period. <P>SOLUTION: The disposal container 1 for radioactive waste accommodating inside radioactive waste is constituted of a container body 2 formed in a rectangular shape and sealed at the upper opening by welding a sealing lid 3, and a plurality of rectangular shield plates to assemble into a rectangular shield body 5 of which each 4 corner has step shape assembling parts which are assembled to be right angles with each other in the container body 2. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radioactive waste disposal container for accommodating radioactive waste to be disposed, a suspender for the disposal container used for storing the disposal container at a disposal site, and a radioactive material for the disposal container. It belongs to the technical field of waste storage methods.

[0002]

2. Description of the Related Art As is well known, radioactive waste is stored in a disposal container and then carried into an appropriate disposal site for disposal. Conventionally, such a disposal container has a cylindrical shape,
Since there is a lot of dead space when storing in a disposal site and storage efficiency is poor, a rectangular type has been recently used. In such a disposal container, a shielding layer is formed inside a steel plate container consisting of a container body and a container lid with a shield such as concrete with a certain thickness, and the container lid is bolted to the upper opening of the container body. It is generally configured to be sealed.

Further, the disposal container is provided with a lifting means for suspending it with a special lifting tool when it is stored in the disposal site. The following means are generally used for lifting the disposal container. The side plate of the container body is formed with a bulging portion projecting outward. Attach the handle to the side plate of the container body. Install the trunnion on the side plate of the container body. Install the lifting bolt on the top of the side plate of the container body.

By the way, in order to stably contain the nuclides for a long period of time, various methods have been devised for the method of accommodating the radioactive waste in the disposal container. This is one in which a mortar is filled in a disposal container and solidified. Further, for example, in Japanese Unexamined Patent Publication No. 4-110799, after the radioactive waste charged in a metal container is filled with a powdery or granular adsorbent, the metal container is compression-molded into a waste compact. A device having a confining property is disclosed.

[0005]

In the radioactive waste disposal container according to the above-mentioned conventional example, the thickness of the shielding plate constituting the shielding layer for shielding radiation is preset. by the way,
From the viewpoint of safety, it is necessary to keep the surface dose value of the disposal container within a certain value. Therefore, it is necessary to control the amount of the radioactive waste stored in the disposal container according to the radiation level of the radioactive waste, and there is a drawback that the storage efficiency of the radioactive waste decreases.

In order to solve such a drawback, a method of forming the shielding layer in multiple layers has been proposed. That is, in order to keep the surface dose value of the disposal container within a certain value according to the radiation level of the radioactive waste, the steel plate-integrated tubular shield body has a multiple structure. On the other hand, as mentioned above,
In order to efficiently store the disposal container in the disposal site, it has been proposed to make the disposal container rectangular. However, when the multiple configuration of the shield is applied to the rectangular disposal container,
The manufacturing process of the steel plate integrated rectangular shield is more complicated than that of the cylindrical shield, and an increase in manufacturing cost is unavoidable, which is economically disadvantageous.

It has also been proposed to use radioactive metal waste as a material for the shield. From the viewpoint of utilizing the excellent shielding ability of metal and reusing radioactive metal waste, the molten metal of radioactive metal waste was poured into the container instead of concrete, and the shielding layer was cast. It is a thing. However, when casting the shielding layer, the material of the disposal container may be altered due to the heat effect during casting, and it is necessary to apply it as it is to a disposal container that needs to keep the nuclide trapped and stable for a long period of time. Inappropriate.

In the method of bolting the container lid to the upper opening of the container body of the disposal container, it is necessary to provide a threaded portion inside or outside the upper end of the side plate of the container body. Therefore, there is a restriction on the shape of the radioactive waste, so that the storage efficiency is lowered, and it is inevitable that the storage efficiency of the disposal container is lowered at the disposal site. Further, it is preferable to reduce the burden on other artificial barriers and reduce the total disposal cost including the disposal site by ensuring the long-term nuclide confinement property in the disposal container. However, there is an unavoidable risk of deterioration of durability due to deterioration of the sealing material inserted between the container body and the container lid to maintain airtightness, corrosion of dissimilar metal batteries and crevice corrosion of contact surfaces, It is not a preferable sealing method for a disposal container that is expected to have a long life.

For example, a bulge is formed on the side plate of the container body of the disposal container, a handle is attached to the side plate of the container body, a trunnion is attached to the side plate of the container body, and a lifting bolt is attached to the upper part of the side plate of the container body. In the conventional lifting means, the occupied area of the disposal container increases due to the increase in the outer size.
That is, since the dead space becomes large, the storage efficiency of the disposal container at the disposal site decreases. Also, when installing the lifting bolt on the top of the side plate of the container body,
Bend the top edge of the side plate inward or outward,
It is necessary to form a bolt threaded portion. When the upper end of the side plate is bent inward, the storage efficiency of radioactive waste is reduced and the shape thereof is restricted. Further, when the upper end portion of the side plate is bent outward, the occupied area of the disposal container increases due to the increase in the outer size, and the dead space increases, so that the storage efficiency of the disposal container at the disposal site decreases.

Among the methods of accommodating radioactive waste in the disposal container, in the method of accommodating the disposal container with mortar and solidifying it, the disposal container is buried under the condition that water remains. Therefore, the radiation emitted from the radioactive waste causes the moisture to be decomposed by radioactivity, and the disposing container may be corroded by the oxidizing chemical species generated by the radiolysis of the moisture. In the storage method in which the radioactive waste contained in the metal container is filled with a particulate adsorbent and the metal container is compression-molded, it is not always necessary to consider the radioactive waste generated when the power station is dismantled. It is not always possible to perform compression molding, and a compression process is required, which is not efficient. In addition, the volume reduction rate due to compression is inevitably worse than when only radioactive waste is used alone. Furthermore, it is difficult to confirm whether or not the amount of adsorbent necessary for trapping the nuclide during compression molding is secured.

As described above, in the case of the radioactive waste disposal container according to the conventional example described above, the radioactive waste is efficiently accommodated and the total disposal cost is reduced by efficiently accommodating the radioactive waste. The structure does not allow reduction. In addition, it is hard to say that the disposal container according to this conventional example has a configuration in which long-term confinement stability can be expected from the viewpoint of ensuring the confinement of the nuclide. Furthermore, in addition to the risk of corrosion of the disposal container, it is difficult to apply depending on the type of radioactive waste.

Therefore, the object of the present invention is to store radioactive waste efficiently and efficiently at a disposal site, and from the viewpoint of ensuring the confinement of nuclides, it is a long term. Disclosed is a radioactive waste disposal container capable of stably exhibiting a radionuclide confinement function, a suspender for the disposal container, and a method for accommodating the radioactive waste in the disposal container.

[0013]

The present invention has been made in view of the above circumstances, and therefore, in order to solve the above problems, the radioactive waste disposal container according to claim 1 of the present invention is adopted. The feature of the means is that, in a radioactive waste disposal container that accommodates radioactive waste inside, the container body is formed in a rectangular shape and is sealed by a rectangular container lid, and four end portions. A plurality of rectangular shielding plates each having a stepwise combination part, and these shielding plates are assembled so that adjacent shielding plates are at a right angle in the container body, and a rectangular shielding body is formed. It is configured to be.

The feature of the means adopted by the radioactive waste disposal container according to claim 2 of the present invention is that of claim 1
In the radioactive waste disposal container described in the paragraph [4], the rectangular shield is a multi-layered rectangular shield having a uniform thickness and a plurality of similar-shaped shield plates stacked.

The feature of the means adopted by the radioactive waste disposal container according to claim 3 of the present invention is that of claim 1
Alternatively, in the radioactive waste disposal container according to any one of items 2 or 3, the shielding plate is made of metal or concrete.

The feature of the means adopted by the radioactive waste disposal container according to claim 4 of the present invention is that of claim 1
Alternatively, in the radioactive waste disposal container according to any one of the items 2 and 2, the shielding plate is manufactured from radioactive metal waste.

The feature of the means adopted by the radioactive waste disposal container according to claim 5 of the present invention is that of claim 1
In the radioactive waste disposal container according to any one of items 1 to 4, the container body and the container lid are welded to each other.

The feature of the means adopted by the radioactive waste disposal container according to claim 6 of the present invention is that of claim 1
In the radioactive waste disposal container according to any one of items 1 to 5, a hanging metal fitting is provided inside an upper surface of the container lid.

The feature of the means adopted by the radioactive waste disposal container according to claim 7 of the present invention is that of claim 1
In the radioactive waste disposal container according to any one of items 1 to 6, a guide cylinder that surrounds the suspension fitting is projectingly provided on an upper surface of the container lid, and a guide tube that surrounds the bottom plate of the container main body is provided. It is provided with tubular legs that can be inserted into and removed from the guide tube.

A feature of the means adopted by the hanger of the radioactive waste disposal container according to claim 8 of the present invention is that the radioactive waste according to claim 6 or 7. In a lifting device for a disposal container having a lifting part provided with a metal fitting clamp for clamping the hanging metal part of the disposal container, the outer size of the lifting part is set to an outer size that can be accommodated in the container lid. It is in.

The feature of the means adopted by the method for accommodating radioactive waste in a disposal container according to claim 9 of the present invention is that the disposal container comprises a container lid and a container body sealed by this container lid. In the method of accommodating radioactive waste in a disposal container for accommodating radioactive waste in a shield in the container body, after accommodating radioactive waste in the shield, the inner surface of the shield and the radioactive waste are The space and the space formed between radioactive wastes are filled with a compression molding material obtained by compression molding bentonite at high pressure.

The feature of the means adopted in the method for accommodating radioactive waste in a disposal container according to claim 10 of the present invention is that the method for accommodating radioactive waste in a disposal container according to claim 9 is: The compression molding material has a ball shape or a board shape.

The feature of the means adopted by the method for accommodating radioactive waste in the disposal container according to claim 11 of the present invention is that the disposal container according to any one of claims 9 and 10. In the method of accommodating radioactive waste in, the space portion is filled with silica sand.

A feature of the means adopted in the method for accommodating radioactive waste in a disposal container according to claim 12 of the present invention is that the disposal container according to any one of claims 9 to 11. In the method for accommodating radioactive waste in, the space portion is filled with iron powder.

A feature of the means adopted in the method for accommodating radioactive waste in the disposal container according to claim 13 of the present invention is that the disposal container according to any one of claims 9 to 12 is characterized. In the method for accommodating radioactive waste in, the space is filled with a cement material.

The means adopted in the method for accommodating radioactive waste in the disposal container according to claim 14 of the present invention is characterized in that the disposal container according to any one of claims 9 and 10. In the method of accommodating radioactive waste in, the compression molding material is mixed with silica sand.

A feature of the means adopted in the method for accommodating radioactive waste in a disposal container according to claim 15 of the present invention is that the disposal container according to any one of claims 9 to 11 is characterized. In the method of accommodating radioactive waste in, the compression molding material is mixed with iron powder.

A feature of the means adopted in the method for accommodating radioactive waste in a disposal container according to claim 16 of the present invention is that the disposal container according to any one of claims 9 to 12. In the method of accommodating radioactive waste in, the cement-based material is mixed with the compression molding material.

[0029]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a radioactive waste disposal container and a suspender for the disposal container according to an embodiment of the present invention will be described with reference to the accompanying drawings. FIG. 1A is a plan view of a radioactive waste disposal container, and FIG. 1B is a plan view of FIG.
2 is a sectional view taken along line AA of FIG. 2, and FIG. 2 is an enlarged view of a B portion in FIG. Further, FIG. 3 (a) is a plan view of the suspending tool of the disposal container, FIG. 3 (b) is a front view of the suspending tool of the disposal container with a part of the metal fitting clamp omitted, and FIG. 4 is a metal fitting. It is a sectional view of a clamp (the left half in the figure shows the clamped state of the hanging metal fittings, and the right half shows the unclamped state of the hanging metal fittings).

Reference numeral 1 shown in FIGS. 1A and 1B and FIG.
Is a disposal container for radioactive waste according to the first embodiment of the present invention. This disposal container 1 is provided with a container body 2 made of a carbon steel plate whose quality is guaranteed by the JIS standard to facilitate quality control. The container body 2 is formed in a rectangular shape, and its upper opening is configured to be sealed by welding a container lid 3 made of the same material as the container body 2 and having a configuration described later. ing. Further, on the upper surface of the container lid 3 and on the two diagonal lines Ld connecting the opposite corner portions, a pair of guide cylinders 3a each having a taper portion inside the upper end portion of the opening are projected. ing. At the center of each of the guide cylinders 3a in the radial direction, a hanging fitting 4 having a large-diameter head 4a formed on the top is provided in a protruding manner. As described above, by providing the hanging metal fitting 4 inside the guide cylinder 3a, it is possible to prevent the hanging metal fitting 4 from being damaged due to interference with other objects.

Further, at four locations (only two locations are shown in FIG. 1B) on the lower surface of the bottom plate of the container body 2, the radial center is the radial center of the guide cylinder 3a. Matching legs 2a are provided. A space into which the suspension fitting 4 can project is formed inside the leg 2a.
"a" is designed so that it can be removably fitted into a guide cylinder 3a provided on the container lid 3 of another container body 2.
With such a configuration, when the disposal containers 1 are stored in the disposal site, the disposal containers 1 can be stacked in an orderly manner without being displaced in the front, rear, left, and right directions, and the collapse of the stacked disposal containers can be prevented. Then, in the disposal container 1 having such a configuration, a rectangular shield 5 having a configuration described later for accommodating the radioactive waste is assembled.

The rectangular shield 5 is composed of four side shield plates (all having the same shape and the same size) 5a.
And a bottom shielding plate 5b, and an upper shielding plate 5c having the same shape and the same size as the bottom shielding plate 5b. More specifically, each of the side shield plate 5a, the bottom shield plate 5b, and the upper shield plate 5c has a stepwise combination portion formed at each of four end portions, and in the container body 2, Adjacent shield plates are assembled at right angles to each other to form a rectangular parallelepiped (rectangular shape). The side shield plate 5a, the bottom shield plate 5b, and the top shield plate 5c are all set to have the same constant thickness, and are manufactured from radioactive metal waste or concrete.

The dimensions of the side shield plate 5a, the bottom shield plate 5b, and the upper shield plate 5c are manufactured in advance according to the size of the container body 2. for that reason,
The bottom shielding plate 5b, the side shielding plate 5a, and the upper shielding plate 5c are simply inserted into the container body 2 in this order, and the bottom shielding plate 5b, the side shielding plate 5a, and the upper shielding plate 5c are accommodated in the container body 2. The position is automatically determined, and the rectangular shield 5 having a predetermined size is formed.

In the disposal container 1 according to the present embodiment, the number of steps of the stairs of the combination portion formed at the four end portions of each of the side shield plate 5a, the bottom shield plate 5b, and the upper shield plate 5c. Has a two-stage configuration, as is well understood from FIGS. 1 (a) and 1 (b). However,
Since the number of steps of these combination parts may be three or more, it is not particularly limited to the number of steps of the combination part.
In this case, the shape and size of the shielding plate differ depending on the shape of the container body 2, but when the number of the shielding layer is one, at most three types will suffice. There is an economic effect that can be reduced.

By the way, in the above, the four side shield plates 5 are provided.
The case of the one-layer rectangular shield 5 including a and one bottom shield plate 5b and one top shield plate 5c has been described. However, as shown in FIG. 5A of the plan view of the disposal container for radioactive waste according to another embodiment and FIG. 5B of the sectional view taken along the line CC of FIG. 5A, The rectangular shield 5 can have a multilayer structure. That is, the surface dose value of the disposal container 1 can be easily kept within a fixed value by forming the rectangular shield 5 into a multi-layer structure according to the radiation level of the radioactive waste.

In the following, regarding the constitution of the rectangular shield of the disposal container according to this embodiment, the same components as those shown in FIGS. 1 (a) and 1 (b) are designated by the same reference numerals and have the same names. Will be explained. The rectangular shield 5 of this disposal container 1 is assembled in the container main body 2 and is composed of four side shield plates 5a, and one bottom shield plate 5b and one upper shield plate 5c. A mold shield 5 ₁ is provided. Also, this first
The four side shield plates 5 are assembled in the square type shield 5 ₁ .
The second rectangular shield 5 ₂ is composed of a ′ and one bottom shield plate 5b ′ and one upper shield plate 5c ′. Further, it is assembled in the second rectangular shield 5 ₂ and
A third rectangular shield 5 _{3 including} one side shield plate 5a ″, and one bottom shield plate 5b ″ and one upper shield plate 5c ″ is provided. In this case, a second square shield is provided. The shielding plates that form the body 5 ₂ and the third rectangular shield 5 ₃ are formed to have similar shapes to the shielding plates that form the first rectangular shield 5 ₁ .

Next, the suspending metal fitting 4 formed on the container lid 3 is clamped to suspend the disposal container 1 and the suspending tool of the disposal container 1 for releasing the clamp is shown in FIG. It will be described with reference to FIG.

Reference numeral 6 shown in FIGS. 3 (a) and 3 (b) is a suspending tool for suspending the disposal container 1 for storing in the disposal site. The hoisting tool 6 includes a hoisting portion 7 in which a beam member 7a made of channel steel and having opening sides facing each other is formed in a dozen shape. The outer size of the lifting portion 7 is set to a shape and size that can be accommodated in the container lid 3 as well understood from FIG. A pair of hanging brackets 8 are provided at the center of the hoisting portion 7, and metal fitting clamps 9 to be described later are provided near the ends of the four beam members 7a. There is. In addition, this hanger 6
It is configured to be suspended by a moving device (not shown) to reciprocate forward, backward, leftward and rightward, and to be raised and lowered.

As shown in FIGS. 3 (b) and 4, the metal member clamp 9 has a power cylinder 9c pivotally attached to a column member 9a protruding from the upper end of the beam member 7a via a bracket 9b. There is. A spring retainer 9d is fitted into each of the holes formed on both side surfaces of the tip of the beam member 7a, and a pair of clamp bodies 9f are urged by a spring 9e assembled to the spring retainer 9d. There is. The clamp body 9f is formed in an inverted L shape, a spring seat for receiving the spring 9e is provided at one end of the horizontal member, and an inclined surface 9g is provided on the opposite side of the spring seat. Is provided. In addition, the pair of clamp bodies 9
At the lower end of the vertical member of f, the upper surface is the head 4 of the hanging fitting 4.
Suspending claws 9h that come into contact with the lower surface of a are provided.

Inside the beam member 7a, a clamp body holding casing 9i is arranged so that a guide cylinder 9j which is removably fitted inside the guide cylinder 3a projects downward. In the clamp body holding casing 9i,
The pair of clamp bodies 9f are incorporated so as to be horizontally movable. The clamp body 9f has a slidable inclined surface 9l that is installed inside the beam member 7a and above the clamp body holding casing 9i, and an inclined surface 9g of the clamp body 9f slides. , The power cylinder 9c
The pair of clamp bodies 9f is configured to approach and separate from each other by the metal fitting push-back member 9k that is moved up and down by.

That is, according to the metal fitting clamp 9, when the metal fitting pushing-back member 9k is raised by the power cylinder 9c, the spring seat of the clamp body 9f is urged by the spring 9e and pressed toward the hanging metal fitting 4. And a pair of clamp bodies 9f
The hanging metal fitting 4 is clamped by the holding claw 9h. On the other hand, when the metal fitting push-back member 9k is lowered by the power cylinder 9c, the pair of clamp bodies 9f causes the metal fitting push-back member to be pushed although the spring seat is biased by the spring 9e toward the hanging metal fitting 4. The sliding inclined surface 9l of 9k pushes it back in a direction away from the hanging fitting 4, and the clamped state of the hanging fitting 4 by the holding claws 9h of the pair of clamp bodies 9f is released. The operation of the power cylinder 9c is performed by remote control.

The operation mode of the disposal container 1 having the above structure will be described below. According to the disposal container 1 according to the present embodiment, the rectangular shield 5 has a multi-layered structure, whereby the layer thickness of the shielding layer is increased. Can be easily adjusted. And, although the rectangular shield 5 has a multi-layered structure, a side shield plate,
It is only necessary to manufacture the bottom shield plate and the top shield plate, and there are few types of shield plates related to shape and size, so that mass production effect can be expected. Therefore, the disposal container 1 according to the present embodiment has a far simpler manufacturing process than the conventional example having the steel plate-integrated rectangular shield, and thus is far more advantageous in manufacturing cost than the conventional example.

Even when radioactive metal waste is used as the material of the shield, the shield layer of the disposal container 1 according to the present embodiment uses the molten metal of radioactive metal waste as in the conventional example. The shielding layer is not cast by pouring molten metal into a container. That is, as described above, in the container body 2 or the first
The bottom shield plate, the side shield plate, and the top shield plate are inserted into the rectangular shield 5 ₁ or the second rectangular shield 5 ₂ in this order to position each shield plate and the square shield. It is a structure formed in. Therefore, the container body 2 of the disposal container 1 is not affected by high temperature heat as in the conventional example.
There is no fear that the material of the container body 2 will be altered, and the nuclide confinement function can be stably exerted for a long period of time.

Further, in the present embodiment, the container lid 3 is welded to the upper opening of the container body 2, and the container lid is not bolted to the upper opening of the container body as in the conventional example. It is not necessary to provide a screwed portion inside or outside the upper end of the side plate of the container body 2. Therefore, since there is no restriction on the shape of the radioactive waste, the storage efficiency does not decrease, and the storage efficiency of the disposal container 1 at the disposal site does not decrease. Further, in the present embodiment, as described above, the container lid 3 is welded to the upper opening of the container body 2. Therefore, unlike the conventional example, there is no risk of deterioration of the sealing material for maintaining airtightness, deterioration of durability, corrosion of dissimilar metal batteries and corrosion of contact surface crevices.

Further, in the present embodiment, the hanging metal fitting 4 having a large-diameter head 4a formed on the top of the container lid 3 projects on the diagonal line Ld connecting the opposing corners. It is set up. Therefore, as in the conventional example, a bulge is formed on the side plate of the container body, a handle is attached to the side plate of the container body, a trunnion is attached to the side plate of the container body, and a lifting bolt is attached to the upper part of the side plate of the container body. It is not necessary to provide a special lifting means, and the outer size of the disposal container 1 does not become large.

Therefore, since the dead space does not increase, the storage efficiency of the disposal container 1 at the disposal site does not decrease. Moreover, according to the hanger 6 according to the present embodiment, the hanger 6 that suspends the disposal container 1 is provided.
The outer size of the lifting part 7 is set to fit inside the container lid 3. Therefore, when the disposal container 1 is stored in the disposal site, there is no possibility that the hanger 6 interferes with the already disposed disposal container 1, so that the disposal container 1 can be stored in the disposal site with high efficiency.

As described above, according to the disposal container 1 of the present embodiment, radioactive waste can be efficiently stored, and the disposal site can be stored efficiently and efficiently. It is more advantageous than the conventional example in terms of total disposal cost. Further, according to the disposal container 1 according to the present embodiment, it is possible to keep the surface dose value within a fixed value for a longer period than the disposal container according to the conventional example.

Next, a storage method for storing radioactive waste in the rectangular shield 5 assembled in the container body 2 will be described. First, the radioactive waste is stored in the rectangular shield 5. When the radioactive waste is stored, a space having a shape corresponding to the shape of the radioactive waste is formed between the inner surface of the rectangular shield 5 and the radioactive waste and between the radioactive wastes. Therefore, depending on the shape of the space, this space is filled with a ball-shaped or board-shaped compression molded material obtained by compression-molding bentonite at a high pressure by a cold isostatic molding device. Furthermore, in addition to this compression molding material, silica sand, iron powder, and a cement material are filled.

In the space, the compression molded material made of bentonite, silica sand, iron powder, and cement-based material have the following functions, respectively, and such functions provide the following effects. Bentonite Low water permeability, Nuclide adsorption, Opening sealing function (by swelling and closing the opening): Suppressing migration of nuclide Good thermal conductivity of silica sand: Improved heat dissipation Good iron powder thermal conductivity: Heat dissipation Improved Eh (oxidation-reduction potential) low value: Corrosion environment control in container (suppression of corrosion) High cement cement material pH value: Corrosion environment control in container (suppression of corrosion)

More specifically, since the water content can be reduced, the radiation emitted from the radioactive waste rarely decomposes the water content, and the disposal container 1 may be corroded from the inside. Less is. And
Since the disposal container 1 is not compression-molded, even radioactive waste that cannot be compression-molded due to the dismantling of a power plant can be stored in the disposal container 1 and easily disposed of.
Moreover, it is possible to easily confirm whether or not the amount of adsorbent required to trap the nuclide is secured. Further, by filling bentonite or the like into the disposal container 1, external pressure such as earth pressure and water pressure acting on the disposal container 1 buried in the disposal site can be supported from the inside, so that the disposal container 1 is prevented from being deformed and the external pressure is prevented. It is possible to suppress damage to the disposal container 1 due to the above. Further, the conventional technique of filling the adsorbent in the form of powder or granules is not efficient because it requires a compression process, but if the densely packed bentonite is filled, the compression process is not necessary, and therefore it is efficient. In consideration of the above effects obtained with each filler, it is sufficient to appropriately select and fill the materials other than the compression molded material made of bentonite.

In the method of storing the radioactive waste in the disposal container, a compression molding material made of bentonite, silica sand,
The example of individually filling the iron powder and the cement-based material has been described. However, not limited to this, silica sand, iron powder, and cementitious material are mixed in advance with bentonite, or silica sand,
Iron powder and cementitious materials are selectively mixed and mixed. Even if the space is filled with a mixture obtained by compression-molding the mixture into a ball shape or a board shape under high pressure, the same effect as in the case of the above-described filling method of individually filling can be obtained.

In the disposal container 1 according to the above embodiment, the cases of the rectangular shield 5 having one shield layer and the rectangular shield 5 having three shield layers have been described as examples. . However, the rectangular shield 5 assembled in the container body 2 can have two shielding layers, and
Since the number of layers can be more than one, the number of layers of the shielding layer is not limited to the number of layers of the rectangular shielding body 5 according to the above-described embodiment. Further, in the above-described method for accommodating radioactive waste in the disposal container, the case where radioactive waste is accommodated in the rectangular shield 5 assembled in the container body 2 has been described as an example. Since the technical idea of the present invention can be applied to a disposal container, it is not limited to the method of accommodating radioactive waste in the rectangular disposal container of the present invention.

[0053]

As described in detail above, the first aspect of the present invention
In the case of the radioactive waste disposal container according to any one of items 1 to 7, the layer thickness of the shielding layer can be easily adjusted by forming the rectangular shielding body in a multilayer structure. And, although the rectangular shield has a multi-layered structure, the side shield plate, the bottom shield plate,
It is only necessary to manufacture the upper shield plate, and there are few kinds of shield plates related to shape and size, so that mass production effect can be expected. Therefore, according to the disposal container of the present embodiment, the manufacturing process is much simpler than that of the conventional example having the steel plate-integrated rectangular shield, so that the manufacturing cost is much more advantageous than the conventional example. .

Even when radioactive metal waste is used as the material for the shield, in the case of the present invention, the molten metal of radioactive metal waste is poured into a container as in the conventional example. The shield layer is not cast. That is, the bottom shield plate, the side shield plate, and the top shield plate are inserted into the container main body in this order to be positioned and formed into a square shape. Therefore, since the container body is not affected by high temperature heat as in the conventional example, there is no fear that the material of the container body is deteriorated and the nuclide confinement function can be stably exerted for a long period of time. .

Further, in the case of the present invention, the container lid is welded to the upper opening of the container body, and unlike the conventional example, the container lid is not bolted to the upper opening of the container body. It is not necessary to provide a screwed portion inside or outside the upper end of the side plate of the container body 2. Therefore, since there is no restriction on the shape of the radioactive waste, the storage efficiency does not decrease, and the storage efficiency of the disposal container at the disposal site does not decrease. Further, unlike the conventional example, there is no risk of deterioration of the sealing material for maintaining airtightness, deterioration of durability, corrosion of dissimilar metal batteries and corrosion of contact surface crevices.

Further, in the disposal container according to the sixth aspect of the present invention, the hanging metal fitting is provided inside the upper surface of the container lid. Therefore, as in the conventional example, a bulge is formed on the side plate of the container body, a handle is attached to the side plate of the container body, a trunnion is attached to the side plate of the container body, and a lifting bolt is attached to the upper part of the side plate of the container body. It is not necessary to provide a special lifting means, and the outer size of the disposal container does not become large. Therefore, since the dead space does not become large, the storage efficiency of the disposal container at the disposal site does not decrease.

Further, in the disposal container according to the seventh aspect of the present invention, the bottom of the bottom plate of the container main body is provided with the tubular leg which can be removably fitted into the guide cylinder. Therefore, when the disposal containers are stored in the disposal site, the disposal containers can be stacked orderly without being displaced in the front, rear, left, and right directions, and the stacked disposal containers can be prevented from collapsing.

According to the suspending tool according to the eighth aspect of the present invention, the outer dimension of the suspending tool for suspending the disposal container is set to the outer size that can be accommodated in the container lid. Therefore, when the disposal container is stored in the disposal site, there is no possibility that the suspending tool interferes with the already disposed disposal container, so that the disposal container can be stored in the disposal site with high efficiency.

According to the method for accommodating radioactive waste in the disposal container according to the ninth to sixteenth aspects of the present invention, the water content can be reduced, and therefore the water content is decomposed by the radiation emitted from the radioactive waste material. There is little risk that the disposal container will be corroded from the inside.
And since the disposal container is not compression-molded, even radioactive waste that cannot be compression-molded due to the dismantling of the power plant can be stored in the disposal container and easily disposed of, and the nuclide is confined. It is possible to easily confirm whether or not the amount of adsorbent required for the above is secured. Also,
By filling bentonite, etc. into the disposal container, it is possible to support the external pressure, such as the ground pressure and water pressure, that acts on the disposal container buried in the disposal site, so the deformation of the disposal container is prevented and the disposal container caused by the external pressure. Can be suppressed.

[Brief description of drawings]

FIG. 1 relates to an embodiment of the present invention, FIG. 1 (a) is a plan view of a radioactive waste disposal container, and FIG. 1 (b) is FIG. 1 (a).
FIG. 9 is a sectional view taken along line AA of FIG.

FIG. 2 is an enlarged view of a B part in FIG.

FIG. 3 is a plan view of a suspending tool for a disposal container according to an embodiment of the present invention, and FIG. 3 (b) is a suspending tool for a disposal container in which a part of a metal fitting clamp is omitted. FIG.

FIG. 4 is a cross-sectional view of a metal fitting clamp according to an embodiment of the present invention (the left half in the drawing shows a clamped state of a hanging metal fitting,
The right half shows the unclamping state of the suspension fitting).

5 (a) is a plan view of a radioactive waste disposal container according to another embodiment of the present invention, and FIG. 5 (b) is a plan view of FIG.
It is the CC sectional view taken on the line of (a).

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Disposal container 2 ... Container body 2a ... Leg 3 ... Container lid 3a ... Guide cylinder 4 ... Hanging metal fittings 4a ... Head 5 ... Square shield 5a ... Side shield 5b ... Bottom shield 5c ... upper shield plate 5 ₁ ... first rectangular shield 5a ... side shield plate 5b ... bottom shield plate 5c ... upper shield plate 5 ₂ ... second square shield 5a '... side shield plate 5b '...
Bottom shield plate 5c '... Top shield plate 5 ₃ ... Third rectangular shield 5a "... Side shield plate 5b" ...
Bottom shield plate 5c "... Top shield plate 6 ... Lifting tool 7 ... Lifting portion, 7a ... Beam member 8 ... Lifting bracket 9 ... Bracket clamp, 9a ... Strut member, 9b ... Bracket, 9c ... Power cylinder, 9d ... Spring retainer, 9e ...
Spring, 9f ... Clamping body, 9g ... Inclined surface, 9h ... Holding claw, 9i ... Clamping body holding casing, 9j ... Guide tube, 9k ... Metal fitting pushing back member, 9l ... Sliding inclined surface Ld ... Diagonal line

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Ryutaro Wada             1-5-5 Takatsukadai, Nishi-ku, Kobe City, Hyogo Prefecture             Kobe Steel Co., Ltd.Kobe Research Institute (72) Inventor Tsutomu Nishimura             1-5-5 Takatsukadai, Nishi-ku, Kobe City, Hyogo Prefecture             Kobe Steel Co., Ltd.Kobe Research Institute (72) Inventor Masahisa Sawada             1-5-5 Takatsukadai, Nishi-ku, Kobe City, Hyogo Prefecture             Kobe Steel Co., Ltd.Kobe Research Institute F term (reference) 4D004 AA50 AB09 BB09

Claims (16)

[Claims] 1. A radioactive waste disposal container for accommodating radioactive waste, wherein the container body is formed in a rectangular shape and is sealed by a rectangular container lid, and stairs are provided at each of four end portions. And a plurality of rectangular shielding plates having a combination portion of a rectangular shape, and these shielding plates are assembled so that adjacent shielding plates are at right angles in the container body to form a rectangular shielding body. A disposal container for radioactive waste characterized by being configured. 2. The square-shaped shield is a multi-layered square-shaped shield having a constant thickness and a plurality of similar-shaped shields stacked on each other. Disposal container for radioactive waste. 3. The shield plate is made of metal or concrete, and the shield plate is made of metal or concrete.
The disposal container for radioactive waste according to any one of the items. 4. The disposal container for radioactive waste according to claim 1, wherein the shielding plate is manufactured from radioactive metal waste. 5. The disposal container for radioactive waste according to any one of claims 1 to 4, wherein the container body and the container lid are welded to each other. 6. The radioactive waste disposal container according to any one of claims 1 to 5, wherein a hanging metal fitting is provided inside an upper surface of the container lid. 7. A guide cylinder surrounding the hanging fitting is provided on the upper surface of the container lid in a protruding manner, and on the lower surface of the bottom plate of the container body,
7. The radioactive waste disposal container according to any one of claims 1 to 6, further comprising: a tubular leg that can be inserted into and removed from the guide tube. 8. A lifting tool for a disposal container, comprising a lifting part provided with a metal fitting clamp for clamping the hanging metal fitting for the radioactive waste disposal container according to claim 6 or 7. 2. The lifting tool for a disposal container according to claim 1, wherein an outer size of the lifting portion is set to fit in the container lid. 9. A method of accommodating a radioactive waste in a disposal container for accommodating the radioactive waste in a shield body in the container body of the disposal container, which comprises a container lid and a container body sealed by the container lid, After accommodating radioactive waste in the shield, a compression molding material obtained by compression-molding bentonite at high pressure in a space formed between the inner surface of the shield and the radioactive waste and between the radioactive wastes. A method for accommodating radioactive waste in a disposal container, which is characterized by filling the container. 10. The method for accommodating radioactive waste in a disposal container according to claim 9, wherein the compression-molded material has a ball shape or a board shape. 11. The method for accommodating radioactive waste in a disposal container according to claim 9, wherein the space is filled with silica sand. 12. The method for accommodating radioactive waste in a disposal container according to claim 9, wherein the space portion is filled with iron powder. 13. The method of accommodating radioactive waste in a disposal container according to claim 9, wherein the space portion is filled with a cement material. 14. The method for accommodating radioactive waste in a disposal container according to claim 9, wherein the compression molding material is mixed with silica sand. 15. The method for accommodating radioactive waste in a disposal container according to claim 9, wherein iron powder is mixed in the compression molded material. 16. The method for accommodating radioactive waste in a disposal container according to claim 9, wherein the compression molding material is mixed with a cement material. .