JP2003207597A - Radioactive substance storage facility - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the size of a used fuel storage facility, and to reduce a cost for constructing the storage facility. <P>SOLUTION: The used fuel storage facility stores a stockpile of a metallic storage vessels housing a part or most of the fuel by reducing capacity more than a shape of a fuel assembly by forming powdery uranium oxide, plutonium oxide, and fission product oxide by processing a used fuel assembly. The storage facility area can be reduced to about 1/40 as compared with a case of storing used fuel as it is, by reducing stockpile capacity to 1/20 by storing metallic vessels housing the powdery uranium oxide, the plutonium oxide, and the fission product oxide by processing the used fuel assembly. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radioactive substance storage facility, and more particularly to a radioactive substance storage facility that stores spent fuel mainly generated from a nuclear power plant.

[0002]

2. Description of the Related Art Fuel used in a core of a nuclear power generation facility for a certain period of time is taken out of the core and temporarily stored in a spent fuel pool or the like. The fuel after the completion of this predetermined cooling period is finally carried out to a reprocessing plant where it is reprocessed and uranium and plutonium are taken out as recycled resources for reuse.

At present, since the spent fuel generated in nuclear power plants is increasing with the demand for power generation, the spent fuel generated in Japan exceeds the processing capacity in the reprocessing plant even if the reprocessing plant operates. Therefore, it is necessary to properly manage and store the material before it is reprocessed. The required storage capacity is 6000 tU scale in 2010 and 15 in 2020.
The scale is 000 tU.

As a method of managing and storing spent fuel on or off the site of a nuclear power plant, a dry storage system such as dry cask storage, vault storage, silo storage, concrete cask storage, etc., and a water pool wet storage system However, dry storage is drawing attention in view of cost and stable storage over a long period of time. Among the dry storage methods, the cask storage method that is currently put into practical use in Japan is a method of storing spent fuel in the form of a fuel assembly in a dry cask, which is a radioactive substance storage container.

There is a vault storage system as a storage system that can make the storage facility smaller than the cask storage system. As shown in Japanese Patent Laid-Open No. 9-166696 as an example of this storage system, as in the case of the metal cask system, a used combustion assembly is placed in a radioactive substance storage container and sealed, and then inserted into a storage pipe. There is a method of natural air cooling with flowing outside air. As another example of the vault storage system, JP-A-11-27
As shown in No. 1493, there is a system in which the storage tube is eliminated and the surroundings of the radioactive material storage container containing the spent fuel assembly are naturally cooled.

[0006]

In any of the above conventional radioactive substance storage facilities, since the spent fuel assemblies as radioactive substances are stored in the state in which the shape is preserved as it is, the inside of the metal storage container is Since there will be spaces other than radioactive substances, in order to make the storage facility compact, the number of spent fuel assemblies stored in the storage container must be increased, and the spacing between the storage containers must be narrowed. Are being considered. However, the increase in the number of the spent fuel storage units in the storage container has a limit because it lowers the heat removal performance of the storage container and increases the weight. In addition, there is a limit to narrowing the arrangement interval of the storage containers due to restrictions on the handling equipment or restrictions on the storage building structure.

An object of the present invention is to provide a compact radioactive material storage facility by reducing the volume of spent fuel assemblies.

[0008]

FIG. 1 shows a nuclear fuel cycle flow in the present invention for storing radioactive material having a reduced volume of a spent fuel assembly.

Spent fuel generated from a nuclear power plant is
Delivered to reprocessing plant. At the reprocessing plant, spent fuel assemblies are sorted and produced into uranium oxide, plutonium oxide, fission product oxides, and other components of the spent fuel assemblies. Of these, some or most of uranium oxide, plutonium oxide, and fission product oxide are stored in a storage container. After the predetermined storage period ends, the stored material is carried out to a fuel manufacturing factory as a raw material of a new fuel assembly, and the manufactured fuel assembly is used as a fuel in a nuclear power plant. Moreover, the uranium oxide produced in the reprocessing plant is carried out to the fuel production plant as a raw material for the new fuel assembly, and the produced fuel assembly is used as a fuel in the nuclear power plant.

The uranium oxide, plutonium oxide, and fission product oxide, which are filled in the storage container, are in the form of powder, and most of the space inside the storage container is filled with radioactive material. Compared with the case where the body is stored in the storage container, the volume can be greatly reduced and the body can be stored in the storage container.

[0011] Preferably, the stored material is a spent fuel from which a main heating element has been removed in advance, so that the temperature of the storage facility structure can be reduced.

[0012] Preferably, the heat transfer performance of the storage container can be improved by radially arranging the heat transfer promoting members in the storage container.

[0013] It is preferable to improve the heat removal performance of the storage container by arranging the heat transfer promoters in a grid shape in the storage container.

It is preferable to improve heat removal performance of the storage container by alternately accommodating the heat transfer promoter and the stored material provided in the storage container in the cross-sectional direction.

Preferably, the heat transfer performance of the storage container is improved by disposing a heat transfer promoter in the form of agglomerates in the storage container.

[0016] Preferably, the storage pipe for storing the storage container is installed in the storage facility in a seismic isolation structure to reduce the storage space in the storage facility.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION (Embodiment 1) In a storage facility of one embodiment of the present invention, spent fuel generated in a nuclear power plant is treated with uranium oxide, plutonium oxide, fission product oxide in a reprocessing plant. And a cladding tube that is a constituent of spent fuel, and a cylindrical metal storage container that stores a part or most of the uranium oxide, plutonium oxide, and fission product oxide among them as storage objects. It is configured to load what is stored in the storage tube.

FIG. 2 shows an example of a sectional view of a radioactive substance storage facility according to this embodiment. A storage unit for storing containers containing radioactive materials will be installed underground, and a storage container handling room for handling the storage containers will be installed above it.

The heat generated from the radioactive material is introduced into the storage section through the cooling air supply port provided on the ground section. The cooling air introduced into the storage unit removes heat generated from the container containing the radioactive material, and is discharged from the cooling air exhaust port provided on the ground. The cooling air is blown to the storage section by a blower provided between the cooling air supply port and the storage section. A room will be provided in the basement for installing blowers and incidental machinery for storage facilities. As a result, the above-ground portion has only the cooling air supply port and the cooling air exhaust port.

A similar effect can be obtained by providing an exhaust fan between the storage section and the cooling air exhaust port. However, since the exhaust fan is exposed to the hot air warmed in the storage section, as a countermeasure against it. Space is required, and the storage facility becomes larger,
Furthermore, heat resistance measures such as the exhaust fan and its auxiliary equipment are required.

Radiation generated from radioactive materials is
Since the storage unit that stores the containers that store radioactive materials is installed underground, the soil around the underground parts serves as a shield, and the effects of direct radiation from radioactive materials on the storage facility surrounding No special consideration is required. However, for the effect of radiation on the surroundings of the storage facility due to streaming from the cooling air supply port and cooling air exhaust port, set the required shielding thickness for the concrete structure of the cooling air supply port and cooling air exhaust port on the ground. In addition, the shape of the cooling air flow path is made to be a labyrinth shape that reduces streaming.

When considering the miniaturization of the storage facility, it is necessary to optimize the temperature of the storage object and the temperature of the structural material of the facility. If the porosity of the storage part is constant, the larger the diameter of the storage container, the higher the storage density, which is the ratio of the storage amount to the storage space, and the higher the storage temperature in the storage container and the facility structure material temperature. On the other hand, increasing the amount of cooling air is effective for reducing these temperatures. As a means therefor, there is a reduction in the flow resistance of the cooling air flowing through the storage section, or an increase in the blower air volume. However, in order to reduce the flow resistance, the porosity of the storage section increases, and in order to increase the blower air volume, the blower needs to be large. For this reason, there is an optimum shape of the storage container for the temperature limit value of the structural material inside the storage facility. Further, since the storage object of the present embodiment is in the form of powder,
As shown in FIG. 3, by loading a radial heat transfer enhancer inside the container, the effective thermal conductivity inside the container is adjusted to increase the size of the storage container. An increase in storage density can be achieved under the condition that the shape is optimized and the temperature limit value of the structural member inside the storage facility is satisfied. By removing some or most of the high-pyrogenic substances from the fission products of the object to be stored at this time, the calorific value per unit volume of the object to be stored is substantially reduced. The storage facility can be made compact. The high exothermic substance mentioned here is especially a strontium compound or a cesium compound.

From the above, the radioactive material to be stored can achieve a compact storage facility by reducing the volume of the spent fuel assembly, and the amount of the spent fuel assembly can be reduced to about 1/2.
By reducing the volume to 0, the storage facility area can be reduced to about 1/40 as compared with the case where the spent fuel assembly is stored as it is.

(Embodiment 2) A spent fuel generated in a nuclear power plant which is another embodiment of the present invention is composed of uranium oxide, plutonium oxide, fission product oxide and spent fuel in a reprocessing plant. It is converted to a cladding tube, which is a material, and a part or most of the uranium oxide, plutonium oxide, and fission product oxide is stored as a storage object and is stored in a cylindrical metal storage container. It is configured to be loaded on a pipe.

FIG. 2 shows an example of a sectional view of a radioactive substance storage facility according to the present invention. A storage unit for storing containers containing radioactive materials will be installed underground, and a storage container handling room for handling the storage containers will be installed above it.

The heat generated from the radioactive material is introduced into the storage through the cooling air supply port provided on the ground. The cooling air introduced into the storage unit removes heat generated from the container containing the radioactive material, and is discharged from the cooling air exhaust port provided on the ground. The cooling air is blown to the storage section by a blower provided between the cooling air supply port and the storage section. A room will be provided in the basement for installing blowers and incidental machinery for storage facilities. As a result, the above-ground portion has only the cooling air supply port and the cooling air exhaust port.

The same effect can be obtained by providing an exhaust fan between the storage section and the cooling air exhaust port. However, since the exhaust fan is exposed to the hot air warmed in the storage section, this is taken as a countermeasure. Space is required, and the storage facility becomes larger,
Furthermore, heat resistance measures such as the exhaust fan and its auxiliary equipment are required.

Radiation generated from radioactive substances is
Since the storage unit that stores the containers that store radioactive materials is installed underground, the soil around the underground parts serves as a shield, and the effects of direct radiation from radioactive materials on the storage facility surrounding No special consideration is required. However, for the effect of radiation on the surroundings of the storage facility due to streaming from the cooling air supply port and cooling air exhaust port, set the required shielding thickness for the concrete structure of the cooling air supply port and cooling air exhaust port on the ground. In addition, the shape of the cooling air flow path is made to be a labyrinth shape that reduces streaming.

When considering the compactness of the storage facility, it is necessary to optimize the temperature of the storage object and the temperature of the structural material of the facility. If the porosity of the storage part is constant, the larger the diameter of the storage container, the higher the storage density, which is the ratio of the storage amount to the storage space, and the higher the storage temperature in the storage container and the facility structure material temperature. On the other hand, increasing the amount of cooling air is effective for reducing these temperatures. As a means therefor, there is a reduction in the flow resistance of the cooling air flowing through the storage section, or an increase in the blower air volume. However, in order to reduce the flow resistance, the porosity of the storage section increases, and in order to increase the blower air volume, the blower needs to be large. For this reason, there is an optimum shape of the storage container for the temperature limit value of the structural material inside the storage facility. Furthermore, since the storage object of the present invention is in the form of powder, by loading a lattice-shaped heat transfer enhancer inside the container as shown in FIG. 4, the effective thermal conductivity inside the container is improved. By adjusting the size of the storage container, the shape of the storage container can be optimized and the storage density can be increased under the condition that the temperature limit value of the structural member inside the storage facility is satisfied. By removing some or most of the high-pyrogenic substances from the fission products of the object to be stored at this time, the calorific value per unit volume of the object to be stored is substantially reduced. The storage facility can be made compact. The high exothermic substance mentioned here is especially a strontium compound or a cesium compound.

From the above, the radioactive material to be stored can achieve a compact storage facility by reducing the volume of the spent fuel assembly, and the amount of the spent fuel assembly can be reduced to about 1/2.
By reducing the volume to 0, the storage facility area can be reduced to about 1/40 as compared with the case where the spent fuel assembly is stored as it is.

(Embodiment 3) In a storage facility which is another embodiment of the present invention, spent fuel generated in a nuclear power plant is used for uranium oxide, plutonium oxide, fission product oxide and used in a reprocessing plant. Converted to cladding, which is a component of spent fuel, of which uranium oxide, plutonium oxide,
In this configuration, a part or most of the fission product oxide is stored in a cylindrical metal storage container and the storage pipe is loaded.

FIG. 2 shows an example of a sectional view of a radioactive substance storage facility according to the present invention. A storage unit for storing containers containing radioactive materials will be installed underground, and a storage container handling room for handling the storage containers will be installed above it.

The heat generated from the radioactive substance is introduced into the storage section through the cooling air supply port provided on the ground section. The cooling air introduced into the storage unit removes heat generated from the container containing the radioactive material, and is discharged from the cooling air exhaust port provided on the ground. The cooling air is blown to the storage section by a blower provided between the cooling air supply port and the storage section. A room will be provided in the basement for installing blowers and incidental machinery for storage facilities. As a result, the above-ground portion has only the cooling air supply port and the cooling air exhaust port.

The same effect can be obtained by providing an exhaust fan between the storage section and the cooling air exhaust port. However, since the exhaust fan is exposed to the high temperature air warmed in the storage section, this is taken as a countermeasure. Space is required, and the storage facility becomes larger,
Furthermore, heat resistance measures such as the exhaust fan and its auxiliary equipment are required.

Radiation generated from radioactive substances is
Since the storage unit that stores the containers that store radioactive materials is installed underground, the soil around the underground parts serves as a shield, and the effects of direct radiation from radioactive materials on the storage facility surrounding No special consideration is required. However, for the effect of radiation on the surroundings of the storage facility due to streaming from the cooling air supply port and cooling air exhaust port, set the required shielding thickness for the concrete structure of the cooling air supply port and cooling air exhaust port on the ground. In addition, the shape of the cooling air flow path is made to be a labyrinth shape that reduces streaming.

When considering the miniaturization of the storage facility, it is necessary to optimize the temperature of the storage object and the temperature of the structural material of the facility. If the porosity of the storage part is constant, the larger the diameter of the storage container, the higher the storage density, which is the ratio of the storage amount to the storage space, and the higher the storage temperature in the storage container and the facility structure material temperature. On the other hand, increasing the amount of cooling air is effective for reducing these temperatures. As a means therefor, there is a reduction in the flow resistance of the cooling air flowing through the storage section, or an increase in the blower air volume. However, in order to reduce the flow resistance, the porosity of the storage section increases, and in order to increase the blower air volume, the blower needs to be large. For this reason, there is an optimum shape of the storage container for the temperature limit value of the structural material inside the storage facility. Further, since the storage object of the present embodiment is in the form of powder,
As shown in Fig. 5, the disk-shaped heat transfer enhancer is sandwiched with the stored material to adjust the effective thermal conductivity inside the container, thereby increasing the size of the storage container. It is possible to increase the storage density under the condition that the shape of the storage container is optimized and the temperature limit value of the structural member inside the storage facility is satisfied. However, in this case, since the storage of the stored material and the installation of the heat transfer promoter are performed alternately, the process of filling the storage container with the stored material becomes complicated. Among the fission products of the storage object at this time, by removing a part or most of the high exothermic substance in advance, by substantially reducing the calorific value per unit volume of the storage object,
The storage facility can be made more compact. The high exothermic substance mentioned here is especially a strontium compound or a cesium compound.

From the above, the radioactive material to be stored can achieve a compact storage facility by reducing the volume of the spent fuel assembly, and the amount of the spent fuel assembly can be reduced to about 1/2.
By reducing the volume to 0, the storage facility area can be reduced to about 1/40 as compared with the case where the spent fuel assembly is stored as it is.

(Embodiment 4) In a storage facility which is another embodiment of the present invention, spent fuel generated in a nuclear power plant is used at a reprocessing plant for uranium oxide, plutonium oxide, fission product oxide and use. Converted to cladding, which is a component of spent fuel, of which uranium oxide, plutonium oxide,
In this configuration, a part or most of the fission product oxide is stored in a cylindrical metal storage container and the storage pipe is loaded.

FIG. 2 shows an example of a sectional view of a radioactive substance storage facility according to the present invention. A storage unit for storing containers containing radioactive materials will be installed underground, and a storage container handling room for handling the storage containers will be installed above it.

The heat generated from the radioactive material is introduced into the storage section from the cooling air supply port provided on the ground section. The cooling air introduced into the storage unit removes heat generated from the container containing the radioactive material, and is discharged from the cooling air exhaust port provided on the ground. The cooling air is blown to the storage section by a blower provided between the cooling air supply port and the storage section. A room will be provided in the basement for installing blowers and incidental machinery for storage facilities. As a result, the above-ground portion has only the cooling air supply port and the cooling air exhaust port.

The same effect can be obtained by providing an exhaust fan between the storage section and the cooling air exhaust port. However, since the exhaust fan is exposed to the high temperature air warmed in the storage section, this is taken as a countermeasure. Space is required, and the storage facility becomes larger,
Furthermore, heat resistance measures such as the exhaust fan and its auxiliary equipment are required.

Radiation generated from radioactive substances is
Since the storage unit that stores the containers that store radioactive materials is installed underground, the soil around the underground parts serves as a shield, and the effects of direct radiation from radioactive materials on the storage facility surrounding No special consideration is required. However, for the effect of radiation on the surroundings of the storage facility due to streaming from the cooling air supply port and cooling air exhaust port, set the required shielding thickness for the concrete structure of the cooling air supply port and cooling air exhaust port on the ground. In addition, the shape of the cooling air flow path is made to be a labyrinth shape that reduces streaming.

When considering a compact storage facility, it is necessary to optimize the temperature of the storage object and the temperature of the structural material of the facility. If the porosity of the storage part is constant, the larger the diameter of the storage container, the higher the storage density, which is the ratio of the storage amount to the storage space, and the higher the storage temperature in the storage container and the facility structure material temperature. On the other hand, increasing the amount of cooling air is effective for reducing these temperatures. As a means therefor, there is a reduction in the flow resistance of the cooling air flowing through the storage section, or an increase in the blower air volume. However, in order to reduce the flow resistance, the porosity of the storage section increases, and in order to increase the blower air volume, the blower needs to be large. For this reason, there is an optimum shape of the storage container for the temperature limit value of the structural material inside the storage facility. Furthermore, since the storage object of the present invention has a powder form, as shown in FIG. 6, by filling the storage container with the heat transfer promoter in the form of agglomerates, the effective thermal conductivity inside the container is improved. By adjusting the size of the storage container, the shape of the storage container can be optimized and the storage density can be increased under the condition that the temperature limit value of the structural member inside the storage facility is satisfied. However, in this case, a step for making the heat transfer promoter uniformly exist inside the storage container is added. By removing some or most of the high-pyrogenic substances from the fission products of the object to be stored at this time, the calorific value per unit volume of the object to be stored is substantially reduced. The storage facility can be made compact.
The high exothermic substance mentioned here is especially a strontium compound or a cesium compound.

From the above, the radioactive material to be stored can achieve a compact storage facility by reducing the volume of the spent fuel assembly, and the amount of the spent fuel assembly can be reduced to about 1/2.
By reducing the volume to 0, the storage facility area can be reduced to about 1/40 as compared with the case where the spent fuel assembly is stored as it is.

(Embodiment 5) In the storage facility of the present invention, spent fuel generated in a nuclear power plant is treated with uranium oxide, plutonium oxide, fission product oxide and spent fuel in a reprocessing plant. Convert to a cladding tube, etc., and store some or most of the uranium oxide, plutonium oxide, and fission product oxide in the cylindrical metal storage container as a storage pipe It is configured to be loaded.

FIG. 2 shows an example of a sectional view of a radioactive substance storage facility according to the present invention. A storage unit for storing containers containing radioactive materials will be installed underground, and a storage container handling room for handling the storage containers will be installed above it.

The heat generated from the radioactive material is introduced into the storage section from the cooling air supply port provided on the ground section. The cooling air introduced into the storage unit removes heat generated from the container containing the radioactive material, and is discharged from the cooling air exhaust port provided on the ground. The cooling air is blown to the storage section by a blower provided between the cooling air supply port and the storage section. A room will be provided in the basement for installing blowers and incidental machinery for storage facilities. As a result, the above-ground portion has only the cooling air supply port and the cooling air exhaust port.

The same effect can be obtained by providing an exhaust fan between the storage section and the cooling air exhaust port. However, since the exhaust fan is exposed to the high temperature air warmed in the storage section, this is taken as a countermeasure. Space is required, and the storage facility becomes larger,
Furthermore, heat resistance measures such as the exhaust fan and its auxiliary equipment are required.

Radiation generated from radioactive materials is
Since the storage unit that stores the containers that store radioactive materials is installed underground, the soil around the underground parts serves as a shield, and the effects of direct radiation from radioactive materials on the storage facility surrounding No special consideration is required. However, for the effect of radiation on the surroundings of the storage facility due to streaming from the cooling air supply port and cooling air exhaust port, set the required shielding thickness for the concrete structure of the cooling air supply port and cooling air exhaust port on the ground. In addition, the shape of the cooling air flow path is made to be a labyrinth shape that reduces streaming.

When considering the optimization of the installation of the storage pipe loaded with the storage container, it is taken into consideration that the storage space is reduced although the flow resistance increases and the heat removal performance decreases when the porosity of the facility is small. There is a need. For this reason, there is an optimum value for the gap in the storage area. On the other hand, the storage tube holding structure is
Not only hindering effective use of storage space, but also increasing cost as a structural material. Therefore, by adopting a seismic isolation structure for the storage pipe, the storage space can be made compact and the facility cost can be reduced. As shown in FIG. 7, as an example of the seismic isolation structure, there is a structure in which the storage pipe is hung from the ceiling of the storage section and installed.

From the above, the radioactive material to be stored can achieve a compact storage facility by reducing the volume of the spent fuel assembly, and the amount of the spent fuel assembly can be reduced to about 1/2.
By reducing the volume to 0, the storage facility area can be reduced to about 1/40 as compared with the case where the spent fuel assembly is stored as it is.

[0052]

According to the present invention, the radioactive substance storage facility can be remarkably made compact as compared with the case where the spent fuel assembly is stored as it is.

[Brief description of drawings]

FIG. 1 is a flow chart of volume reduction and storage of spent fuel in the present invention.

FIG. 2 is a sectional view of a spent fuel storage facility according to the first embodiment of the present invention.

FIG. 3 is a perspective view of the radioactive substance storage canister according to the first embodiment of the present invention.

FIG. 4 is a perspective view of a radioactive substance storage canister according to a second embodiment of the present invention.

FIG. 5 is a configuration diagram of a radioactive substance storage canister according to a third embodiment of the present invention.

FIG. 6 is a configuration diagram of a radioactive substance storage canister according to a fourth embodiment of the present invention.

[Fig. 7] Fig. 7 is a configuration diagram of a suspension frame of a storage pipe according to a sixth embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Storage container, 2 ... Storage pipe, 3 ... Shield plug, 4 ... Storage part, 5 ... Storage container handling chamber, 6 ... Cooling air supply port, 7 ... Cooling air exhaust port, 8 ... Blower, 9 ... Blower chamber ,
DESCRIPTION OF SYMBOLS 10 ... Machine room, 11 ... Powdery radioactive material, 12 ... Heat transfer promoter, 13 ... Heat transfer promotion agglomerate, 14 ... Storage container lid, 15 ...
Storage room ceiling, 16 ... sealing lid, 17 ... suspension frame.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Koki Iga             3-1-1 Sachimachi, Hitachi City, Ibaraki Prefecture Stock Association             Hitachi, Ltd. Nuclear Business Division

Claims (8)

[Claims] 1. A storage room which is provided underground and stores a storage container containing a radioactive substance, an air supply passage for guiding air taken in from the outside to the storage room, and air discharged from the storage room to the outside. An air discharge passage, the storage container,
A radioactive material storage facility, characterized in that it stores the volume of spent fuel and stores it in powder form. 2. The radioactive substance storage facility according to claim 1, wherein the stored material has a chemical form of any one of oxides, nitrides, and carbides. 3. The radioactive substance storage facility according to claim 1, wherein the stored material is obtained by previously removing a main heating element from the spent fuel. 4. The radioactive substance storage facility according to any one of claims 1 to 3, wherein heat transfer enhancers are radially arranged in the storage container in a radial direction. 5. The radioactive substance storage facility according to claim 1, wherein the heat transfer promoters are arranged in a grid in the storage container. 6. The heat transfer promoter and the stored material, which are provided in the cross-sectional direction, are alternately stored in the storage container.
The radioactive substance storage facility according to any one of 1. 7. The radioactive substance storage facility according to any one of claims 1 to 3, wherein a heat transfer accelerator in the form of agglomerates is arranged in the storage container. 8. The radioactive substance storage facility according to claim 1, wherein a storage pipe for storing the storage container is installed in the storage facility with a seismic isolation structure.