JP2020128902A - Storage device for radioactive waste, monitoring device, and method for manufacturing radioactive waste - Google Patents

Abstract

To provide a storage device for a radioactive waste, a monitoring device, and a method for managing a radioactive waste which can easily manage a radioactive waste.SOLUTION: The present invention includes: a first container 21 for containing a radioactive waste; a state detector 22 in the first container 21 for detecting the state in the first container 21; a second container 23 for containing at least one first container 21; and a communication device 24 in the second container 23, the communication device sending the result of detection by the state detector 22 to the outside of the second container 23.SELECTED DRAWING: Figure 1

Description

The present invention relates to a radioactive waste storage device for storing radioactive waste, a radioactive waste monitoring device stored in the radioactive waste storage device, and a radioactive waste stored in the radioactive waste storage device. Management method.

At a nuclear facility, radioactive waste is stored in a dedicated storage container, is carried out to the outside in a state where the confinement is secured, and is stored and managed in a predetermined storage facility. In such a nuclear facility, multiple radioactive substances are confined and managed from the viewpoint of safety. For example, the nuclear fuel is stored in a cladding tube to form a fuel assembly, the fuel assembly is stored in a reactor vessel, and the reactor vessel is installed in a building.

As a technique for monitoring the radioactive substance stored in the storage container, for example, the sealed monitoring facility for the radioactive substance storage container described in Patent Document 1 below stores a cask containing a spent fuel assembly in a storage facility. Provide a sensor to measure the gas pressure between the primary lid and the secondary lid, and a sensor to measure the air temperature inside or outside the storage facility, and monitor the cask sealing performance based on the measured value of each sensor. It is a thing.

JP 2004-0264162 A

Among radioactive wastes, for example, fuel debris that is solidified by melting the nuclear fuel alone or with fuel assemblies and structures inside and outside the reactor vessel have various shapes and properties. .. Therefore, unlike the case of a fuel assembly whose shape and properties are predictable, when transporting or storing a storage container that stores radioactive waste that does not have uniform shape and properties, seal each storage container with a sealed container. There is a demand to monitor that performance is secured. With the equipment for monitoring the sealing of the radioactive substance storage container described in Patent Document 1, it is difficult to monitor the state of each of the contents of the cask, even if the sealing status of the cask can be monitored.

The present invention is to solve the above-mentioned problems, and an object of the present invention is to provide a radioactive waste storage device and a monitoring device that can facilitate the management of radioactive waste, and a radioactive waste management method. To do.

A radioactive waste storage device for achieving the above object includes a first storage container for storing the radioactive waste, and a state provided in the first storage container to detect an internal state of the first storage container. A detector, a second storage container capable of storing at least one of the first storage containers, and a detection result of the state detector provided in the second storage container and transmitted to the outside of the second storage container. And a communication device.

Therefore, since the radioactive waste is stored in the first storage container and the first storage container is stored in the second storage container, the trapping property of the radioactive waste is ensured. Then, the state detector detects the internal state of the first storage container and transmits the detection result to the outside of the second storage container by the communication device, so that the state change of the radioactive waste stored in the first storage container is changed. Can be always grasped. As a result, radioactive waste can be easily managed.

In the radioactive waste storage device of the present invention, the first storage container has a first storage container body and a first lid, and a seal member is provided between the first storage container body and the first lid. It is characterized by being provided.

Therefore, since the radioactive waste is confined and stored in the first storage container sealed by the sealing member, it is possible to suppress external leakage of radioactivity and improve safety.

In the radioactive waste storage device of the present invention, the second storage container has a body portion and a lid portion, and a seal member is provided between the body portion and the lid portion.

Therefore, the radioactive waste is confined and stored in the second storage container sealed by the sealing member, so that it is possible to suppress external leakage of radioactivity and improve safety.

In the radioactive waste storage device of the present invention, the state detector includes at least a pressure detector that detects a pressure inside the first storage container and a temperature detector that detects a temperature inside the first storage container. It is characterized by having and.

Therefore, the pressure detector detects the pressure inside the first storage container, the temperature detector detects the temperature inside the first storage container, and the communication device determines the second pressure inside the first storage container. Send to the outside of the storage container. For example, if the pressure rise inside the first storage container indicates a pressure rise value due to the temperature rise, the radioactive waste inside the first storage container is safely managed. Further, if the pressure rise inside the first storage container exceeds the pressure rise value due to the temperature rise and the pressure rises, the moisture remaining in the radioactive waste is decomposed by radiation and hydrogen gas or oxygen gas is generated. It may have occurred, and the storage container is dried again. Furthermore, when the pressure inside the first storage container is lower than the pressure increase value due to the temperature rise, the internal gas of the first storage container may leak and its sealing performance may be impaired. The seal member of the first lid of the storage container is replaced. Therefore, the state of radioactive waste can be determined with high accuracy according to changes in the pressure and temperature inside the first storage container.

In the radioactive waste storage device of the present invention, the state detector further includes a concentration detector that detects a hydrogen concentration or an oxygen concentration inside the first storage container.

Therefore, the pressure detector detects the pressure inside the first storage container, the temperature detector detects the temperature inside the first storage container, and the concentration detector detects the hydrogen concentration or oxygen concentration inside the first storage container. Is detected and the pressure and temperature inside the first storage container and the hydrogen concentration or the oxygen concentration are transmitted to the outside of the second storage container by the communication device. For example, if all of the pressure and temperature inside the first storage container and the hydrogen concentration or the oxygen concentration increase, there is a possibility that water remains in the radioactive waste, and the radioactive waste is dried again. .. If the pressure and temperature inside the first storage container rise and the hydrogen concentration or oxygen concentration does not rise, the pressure and temperature may rise due to the decay heat of the radioactive waste. The pressure in the first storage container is released before a leak occurs and the second storage container is contaminated. Therefore, it is possible to accurately determine the state of the radioactive waste according to the change in the pressure and temperature inside the first storage container and the hydrogen concentration or the oxygen concentration, and take a necessary management method.

In the radioactive waste storage device of the present invention, a plurality of the first storage containers are vertically arranged inside the second storage container.

Therefore, since the plurality of first storage containers are vertically arranged inside the second storage container, the plurality of first storage containers can be efficiently stored inside the second storage container.

In the radioactive waste storage device of the present invention, the second storage container is provided with a radiation shielding member.

Therefore, since the radiation shielding member is provided in the second storage container, it is possible to suppress transmission of radiation from the radioactive waste stored in the first storage container.

In the radioactive waste storage device of the present invention, the second storage container is a cask provided with the radiation shielding member.

Therefore, since the second storage container is a cask, the radioactive waste stored in the first storage container can be safely transported and stored by the cask.

In the radioactive waste storage device of the present invention, the second storage container may be arranged inside the building formed by the radiation shielding member as a metal storage container having no radiation shielding function. It has a feature.

Therefore, in that case, since the second storage container is a metal storage container not provided with the radiation shielding member and is arranged in the building formed by the radiation shielding member, the second storage container can be simplified. At the same time, the manufacturing cost can be reduced, and a large number of metallic storage containers can be safely arranged in the building.

The radioactive waste monitoring apparatus of the present invention stores the radioactive waste in the first storage container based on the internal state of the radioactive waste storage apparatus and the first storage container transmitted by the communication device. And a monitoring unit that determines the state of the radioactive waste.

Therefore, when the state detector detects the state inside the first storage container and transmits the detection result to the monitoring unit by the communication device, the monitoring unit causes the radioactive substance stored inside the first storage container to be detected based on the detection result. Determine the state of waste. As a result, the state change of the radioactive waste stored in the first storage container can be constantly monitored from the outside of the second storage container.

In the radioactive waste monitoring apparatus of the present invention, the monitoring unit selects the management method of the first storage container based on the state of the radioactive waste stored inside the first storage container. There is.

Therefore, since the monitoring unit selects the management method for the first storage container based on the state of the radioactive waste, it is possible to select the optimum management method for the first storage container.

Further, in the radioactive waste management method of the present invention, in the radioactive waste storage device, the radioactive waste is stored in the first storage container based on the internal state of the first storage container transmitted by the communication device. Determining the state of the stored radioactive waste, and selecting a management method for the first storage container based on the state of the radioactive waste stored inside the first storage container. It is a feature.

Therefore, it is possible to constantly monitor the state change of the radioactive waste stored in the first storage container and select the optimum management method for the first storage container.

According to the radioactive waste storage device, the monitoring device, and the radioactive waste management method of the present invention, radioactive waste can be easily managed.

FIG. 1 is a schematic configuration diagram showing a radioactive waste monitoring device to which the radioactive waste storage device of the present embodiment is applied. FIG. 2 is a vertical cross-sectional view showing the first storage container. FIG. 3 is a vertical cross-sectional view showing the second storage container. FIG. 4 is a horizontal sectional view of the second storage container. FIG. 5 is a schematic diagram showing a radioactive waste storage device according to another embodiment.

A preferred embodiment of a radioactive waste storage device and a monitoring device and a radioactive waste management method of the present invention will be described in detail below with reference to the accompanying drawings. It should be noted that the present invention is not limited to this embodiment, and when there are a plurality of embodiments, the present invention also includes those configured by combining the embodiments.

For example, fuel debris is generated when the nuclear fuel inside the reactor vessel is melted and solidified together with the structures inside and outside the reactor vessel. The fuel debris taken out from the reactor is stored and managed in a dedicated storage device. The radioactive waste storage device of the present embodiment stores radioactive waste such as fuel debris.

Since most of the fuel debris contains not only the nuclear fuel but also its structure and the like, its properties differ depending on the molten state of the core and the content of the nuclear fuel. The radioactive waste monitoring apparatus and method according to the present embodiment monitors the state of the fuel debris stored in the radioactive waste storage apparatus according to the present embodiment.

FIG. 1 is a schematic configuration diagram showing a radioactive waste monitoring device to which the radioactive waste storage device of the present embodiment is applied.

The radioactive waste monitoring device 10 of the present embodiment includes a radioactive waste storage device 11, a communication device 12, a monitoring unit 13, a database 14, and a display unit 15. The radioactive waste storage device 11 stores radioactive waste inside. The communication device 12 communicates with the radioactive waste storage device 11. The monitoring unit 13 determines the state of the radioactive waste based on the internal state of the radioactive waste storage device 11 from the communication result of the communication device 12. The monitoring unit 13 also selects a management method based on the state of the radioactive waste stored inside the radioactive waste storage device 11. The database 14 stores the state record of the monitoring items of the radioactive waste storage device 11, the state of the radioactive waste determined by the monitoring unit 13, and the management method of the radioactive waste selected by the monitoring unit 13. Further, the result of the management method may be stored.

The radioactive waste storage device 11 of the present embodiment includes a first storage container 21, a state detector 22, a second storage container 23, and a communication device 24.

First, the first storage container 21 will be described. FIG. 2 is a vertical cross-sectional view showing the first storage container.

As shown in FIG. 2, the first storage container 21 internally stores the fuel debris 100 in a sealed state. Here, the fuel debris 100 is a solid material obtained by melting and then solidifying the nuclear fuel alone or together with the fuel assembly and the constituent members inside and outside the reactor vessel, and a part of the fuel assembly remaining without being melted. , And the structure inside and outside the reactor vessel to which the solid matter containing the nuclear fuel is attached.

The first storage container 21 has a first storage container body 31 and a first lid 32. The first storage container body 31 has a cylindrical shape, one end of which is open and the other end of which is closed. A flange portion 31 a is provided on the outer peripheral portion on the opening side of one end portion of the first storage container body 31. The first lid 32 has the same diameter as the first storage container body 31, and is provided with a flange portion 32a on the outer peripheral portion. The first lid 32 has flange portions 31 a and 32 a closely contacting each other so as to close the opening of the first storage container body 31, and can be joined by a plurality of bolts 33. At this time, it is preferable to provide a seal member between the flange portions 31a and 32a.

Since the first storage container 21 stores the fuel debris 100 containing the nuclear fuel, after the fuel debris 100 is stored inside the first storage container 21, the outside of the first storage container 21 is prevented so that the nuclear fuel does not become critical. The diameter and length are specified. That is, the outer diameter and the length of the first storage container 21 are defined to be equal to or less than a predetermined dimension, so that the subcriticality of the fuel debris 100 stored inside is secured.

The first storage container 21 is provided with a state detector 22 that detects an internal state. The state detector 22 is provided on the first lid 32 of the first storage container 21, but may be provided on the first storage container body 31. The state detector 22 is preferably at least a pressure detector that detects the pressure inside the first storage container 21 and a temperature detector that detects the temperature inside the first storage container 21. As the state detector 22, it is preferable to provide a hydrogen concentration detector, an oxygen concentration detector, a radiation dose detector, etc. in addition to the pressure detector and the temperature detector.

Next, the second storage container 23 will be described. FIG. 3 is a vertical sectional view showing the second storage container, and FIG. 4 is a horizontal sectional view of the second storage container.

As shown in FIGS. 3 and 4, the second storage container 23 includes a body portion 41, a lid portion 42, and a basket 43. The basket 43 is configured so that the plurality of first storage containers 21 can be stored inside. The body 41 and the lid 42 seal the inside of the second storage container 23.

A radiation shielding member is provided on the body portion 41 and the lid portion 42. That is, the second storage container 23 is a cask having a radiation shielding ability.

The basket 43 is composed of a plurality (69 in this embodiment) of cells 55 partitioned by combining plate materials in a grid pattern. A neutron absorbing material (addition) may be used for the plate material, or a steel material (plate material) and a neutron absorbing material may be superposed. The basket 43 is configured such that a plurality (three in the present embodiment) of the first storage containers 21 can be arranged in the vertical direction.

The body 41 constitutes a sealed container, and the body 51 having a γ-ray shielding function is arranged therein. The body 51 has a cylindrical shape in which an opening 52 is formed on one side, that is, an upper portion, and a bottom portion 53 is formed on the other side, that is, a lower portion, and a basket 43 is arranged inside. Further, the body 51 and the bottom portion 53 thereof are carbon steel forged products having a γ-ray shielding function. The body 51 and the bottom portion 53 thereof may be made of stainless steel instead of carbon steel.

In the body portion 41, an outer cylinder 56 is arranged on the outer peripheral side of the body 51 with a predetermined gap, and a heat transfer fin 57 is arranged between the outer peripheral surface of the body 51 and the inner peripheral surface of the outer cylinder 56. A plurality of pieces are welded at predetermined intervals in the direction. The body portion 41 is a neutron shield composed of a resin containing boron or a boron compound, which is a polymer material containing a large amount of hydrogen and has a neutron shielding function, in the space between the body 51 and the outer cylinder 56. A body 58 is provided.

Further, in the body portion 41, a bottom plate 60 is connected below the bottom portion 53 by a plurality of connecting plates 59 with a predetermined gap, and a neutron shield 61 made of a resin is provided in this space. Further, the trunnion 62 is fixed to a predetermined position on the outer peripheral portion of the body portion 41.

The lid 42 includes a primary lid 63 and a secondary lid 64. Although not shown, a tertiary lid may be provided. The primary lid 63 has a disk shape made of stainless steel or carbon steel that shields γ rays. The secondary lid 64 has a disc shape made of stainless steel or carbon steel, and a neutron shield 65 made of a resin is provided therein. The primary lid portion 63 and the secondary lid portion 64 are detachably attached to the upper end portion of the body 51 by bolts (not shown) made of stainless steel or carbon steel. In this case, a metal gasket (not shown) serving as a sealing member is interposed between the primary lid portion 63 and the secondary lid portion 64 and the body 51 to secure the internal hermeticity.

Further, the cask as the second storage container 23 is detachably attached to the lid portion 42 side and the bottom portion 53 at the time of transportation. The cushioning body 71 is attached to the outside of the lid portion 42 and the body portion 41, and the cushioning body 72 is attached to the outside of the bottom portion 53 of the body portion 41. The second storage container 23 is stored with the buffers 71 and 72 removed during storage or intermediate storage. On the other hand, the second storage container 23 is provided with the buffers 71 and 72 when it is transported to a storage location or an intermediate storage location.

As shown in FIG. 1, the second storage container 23 is provided with a wireless or wired communication device 24. The communication device 24 transmits the detection result of the state detector 22 provided in the first storage container 21 to the outside of the second storage container 23. Here, the communication device 24 obtains the detection result of the state detector 22 by wireless transmission from the state detector 22. The monitoring unit 13 receives, by the communication device 12, the detection result of the state detector 22 transmitted by the communication device 24. The monitoring unit 13 determines the state of radioactive waste based on the detection result of the state detector 22, and determines the management method based on the state of radioactive waste. In this case, the monitoring unit 13 can identify the signal of the state detector 22 received from the communication device 12 to identify the first storage container 21 to which the state detector 22 is attached. Here, the signal of the state detector 22 includes information for identifying the first storage container 21.

As described above, the state detector 22 includes a pressure detector that detects the pressure inside the first storage container 21, a temperature detector that detects the temperature inside the first storage container 21, and an inside of the first storage container 21. And a hydrogen concentration detector for detecting the hydrogen concentration in the first storage container 21.

For example, when all of the pressure, temperature, hydrogen concentration or oxygen concentration inside the first storage container 21 rises and exceeds a preset value, the monitoring unit 13 remains due to radiation from the fuel debris 100. It is determined that the pressure and temperature inside the first storage container 21 and the hydrogen concentration or the oxygen concentration have increased due to the generation of hydrogen, oxygen, etc. by decomposing the water content, the organic matter, etc. present therein. At this time, the monitoring unit 13 may remove the first storage container 21 from the second storage container 23 because there is a possibility that water remains in the fuel debris 100, and then the drying process of the fuel debris 100 is performed. It is displayed on the display unit 15 so as to be executed again. At this time, an alarm may be sounded.

Further, when the pressure and temperature inside the first storage container 21 increase and exceed the specified values, but the hydrogen concentration or the oxygen concentration does not increase, the monitoring unit 13 causes the radiation from the fuel debris 100 to cause the first storage. It is determined that the pressure and temperature inside the first storage container 21 have risen because the temperature inside the container 21 has risen. At this time, the monitoring unit 13 needs to reduce the pressure and the temperature inside the first storage container 21, and the display unit 15 displays the first storage container 21 by taking it out from the second storage container 23 and opening it. indicate.

In order to reduce the pressure inside the first storage container 21, when opening the first storage container 21, either the first lid 32 of the first storage container 21 is opened or a leak valve (not shown) is installed. The pressure inside the first storage container 21 may be released by operation. Further, when the increase rate of the hydrogen concentration and the oxygen concentration inside the first storage container 21 is, for example, 2:1, the decomposition of water is suspected, and therefore the drying process is performed in this case. Further, when the hydrogen concentration is high, etc., decomposition of organic substances is assumed, so sampling and analysis of the contents are performed after opening the first storage container 21. Further, when the first storage container 21 is stored in the second storage container 23, if the first storage container 21 having the same rise in pressure and temperature is stored, the second storage container 23 is opened, The frequency of taking out the first storage container 21 is reduced, and efficient management becomes possible.

Although the cask is used as the second storage container 23 in the above embodiment, the second storage container 23 is not limited to the cask. FIG. 5 is a schematic diagram showing a radioactive waste storage device according to another embodiment.

As shown in FIG. 5, the second storage container 23A is a metallic storage container. The second storage container 23A is a canister as a metal storage container, and is arranged inside the building 81 of the radioactive substance storage facility 80 formed by the radiation shielding member.

Although not shown, the canister as the second storage container 23A includes a body portion, a lid portion, and a basket, similarly to the cask. The canister has almost the same structure as the cask, but the neutron shield or the radiation shield member is not provided on the body or lid. Therefore, the canister is arranged inside the building 81 of the radioactive substance storage facility 80 formed by the radiation shielding member.

The building 81 of the radioactive substance storage facility 80 has an installation floor 82, a ceiling wall 83, and a plurality of side walls 84. The building 81 has a hollow interior, and an installation floor 82, a ceiling wall 83, and each side wall 84 are constituted by radiation shielding members. The radiation shielding member is obtained by being made of concrete, for example. The plurality of canisters as the second storage container 23A are arranged on the installation floor 82 of the building 81 with a predetermined interval. Although not shown, the building 81 is provided with a loading/unloading gate, a loading/unloading pit, a transfer crane, and the like.

Further, the building 81 has an intake port 85 provided on an upper portion of the side wall 84. In the building 81, partition walls 86 are provided on the inner surface side of the side walls 84 at predetermined intervals. An upper end of the partition wall 86 is fixed to the ceiling wall 83, and a lower end of the partition wall 86 is positioned on the installation floor 82 with a predetermined gap, and a duct 87 is formed. In the building 81, an exhaust port 88 is provided at the center of the ceiling wall 83.

Therefore, the outside air is taken into the building 81 through the intake port 85, descends through the duct 87, and cools the plurality of second storage containers 23A (canisters) arranged on the installation floor 82. The air that has cooled the second storage container 23A rises and is discharged from the exhaust port 88 to the outside of the building 81. In this case, the air that has cooled the second storage container 23A rises and is discharged from the exhaust port to the outside of the building 81, so that the inside of the building 81 becomes a negative pressure, and the outside air is sucked from the intake port 85 and the duct 87. Is taken into.

It is preferable to process the fuel debris 100 using both the cask as the second storage container 23 and the canister as the second storage container 23A. For example, first, the fuel debris 100 is stored in the first storage container 21 and sealed. Next, the empty cask is conveyed to the plant where the fuel debris 100 is generated, and the plurality of first storage containers 21 in which the fuel debris 100 is stored are stored inside the cask. Then, the cask is transported to the radioactive substance storage facility 80 by a transportation vehicle or the like. Then, the cask is carried into the building 81, the first storage container 21 inside is transferred to the inside of the canister, and the canister is stored in the building 81.

As described above, in the radioactive waste storage device of the present embodiment, the first storage container 21 that stores the fuel debris 100 as the radioactive waste, and the internal state provided in the first storage container 21 to detect the internal state State detector 22, a second storage container 23 for storing at least one or more first storage containers 21, and a detection result of the state detector 22 provided in the second storage container 23 outside the second storage container 23. And a communication device 24 for transmitting the data.

Therefore, since the fuel debris 100 is stored in the first storage container 21 and the plurality of first storage containers 21 are stored in the second storage container 23, double confinement property for the fuel debris 100 is ensured. Then, the state detector 22 detects the internal state of the first storage container 21, and the communication device 24 transmits the detection result to the outside of the second storage container 23. Therefore, the fuel stored in the first storage container 21 is detected. The state change of the debris 100 can be always grasped from the outside. As a result, the fuel debris 100 can be easily managed.

That is, the plurality of first storage containers 21 storing the fuel debris 100 are stored in the second storage container 23. Then, the state detector 22 provided in the first storage container 21 transmits the internal state of the first storage container 21 to the outside of the second storage container 23. Therefore, when the internal condition of one or a plurality of first storage containers 21 deteriorates, after opening the second storage container 23, only the specific first storage container 21 has to be opened, and the normal first storage It is not necessary to open the container 21. Therefore, periodic inspection management and 100% inspection of the first storage container 21 are not required, and labor saving of inspection work by an operator can be achieved. In addition, the frequency of inspection work by workers can be reduced and exposure management can be rationalized.

In the radioactive waste storage device of the present embodiment, the first storage container 21 has a first storage container body 31 and a first lid 32, and is provided between the first storage container body 31 and the first lid 32. A seal member is provided. Therefore, it is possible to prevent external leakage of radioactivity and improve safety.

In the radioactive waste storage device of the present embodiment, the second storage container 23 has a body portion 41 and a lid portion 42, and a seal member is provided between the body portion 41 and the lid portion 42. Therefore, it is possible to prevent external leakage of radioactivity and improve safety.

In the radioactive waste storage device of this embodiment, the state detector 22 includes a pressure detector that detects at least the pressure inside the first storage container 21 and a temperature detector that detects the temperature inside the first storage container 21. And a vessel. Therefore, the pressure detector detects the pressure inside the first storage container 21, the temperature detector detects the temperature inside the first storage container 21, and the communication device 12 detects the pressure inside the first storage container 21. The temperature is transmitted to the outside of the second storage container 23. Therefore, the state of the fuel debris 100 can be determined with high accuracy according to changes in the pressure and temperature inside the first storage container 21.

In the radioactive waste storage device of this embodiment, the state detector 22 further includes a concentration detector that detects the hydrogen concentration or the oxygen concentration inside the first storage container 21. Therefore, the state of the fuel debris 100 can be determined with high accuracy according to changes in the pressure and temperature inside the first storage container and hydrogen concentration or oxygen concentration.

In the radioactive waste storage device of the present embodiment, a plurality of first storage containers 21 are vertically arranged inside the second storage container 23. Therefore, it is possible to efficiently store the plurality of first storage containers 21 inside the second storage container 23.

In the radioactive waste storage device of the present embodiment, the second storage container 23 is provided with a radiation shielding member. Therefore, the transmission of radiation from the fuel debris 100 stored in the first storage container 21 can be suppressed.

In the radioactive waste storage device of the present embodiment, the second storage container 23 is a cask provided with a radiation shielding member. Therefore, the fuel debris 100 stored in the first storage container 21 can be safely transported and stored by the cask.

In the radioactive waste storage device of the present embodiment, the second storage container 23A is arranged in the building 81 formed by the radiation shielding member as a metal storage container having no radiation shielding function. Therefore, the second storage container 23A can be simplified, the manufacturing cost can be reduced, and a large number of canisters can be safely arranged in the building 81.

Further, in the radioactive waste monitoring device of the present embodiment, the first storage container 21 is based on the internal state of the radioactive waste storage device 11 and the first storage container 21 transmitted by the communication device 24. And a monitoring unit 13 that determines the state of the fuel debris 100 housed inside.

Therefore, when the state detector 22 detects the internal state of the first storage container 21 and the communication device 24 transmits the detection result to the monitoring unit 13, the monitoring unit 13 detects the state of the first storage container 21 based on the detection result. The state of the fuel debris 100 stored inside is determined. As a result, the state change of the fuel debris 100 stored in the first storage container 21 can be constantly monitored from the outside of the second storage container 23.

In the radioactive waste monitoring apparatus of the present embodiment, the monitoring unit 13 selects the management method of the first storage container 21 based on the state of the fuel debris 100 stored inside the first storage container 21. Therefore, the optimal management method for the first storage container 21 can be selected.

Further, in the radioactive waste management method of the present embodiment, the fuel debris 100 stored in the first storage container 21 based on the internal state of the first storage container 21 transmitted by the communication device 24. And a step of selecting a management method for the first storage container 21 based on the state of the fuel debris 100 stored inside the first storage container 21. Therefore, the state change of the fuel debris 100 stored in the first storage container 21 can be constantly monitored, and the optimum management method for the first storage container 21 can be selected.

10 Radioactive Waste Monitoring Device 11 Radioactive Waste Storage Device 12 Communication Device 13 Monitoring Unit 14 Database 15 Display Unit 21 First Storage Container 22 State Detector 23, 23A Second Storage Container 24 Communication Device 31 First Storage Container Main Body 32 1st lid 33 Bolt 41 Body part 42 Lid part 43 Basket 51 Body part 52 Opening part 53 Bottom part 55 Cell 56 Outer cylinder 57 Heat transfer fin 58 Neutron shield 59 Connection plate 60 Bottom plate 61 Neutron shield 62 Trunnion 63 Primary lid part 64 Secondary lid 71, 72 Buffer 80 Radioactive material storage facility 81 Building 100 Fuel debris (radioactive waste)

Claims (12)

A first storage container for storing radioactive waste;
A state detector provided in the first storage container for detecting a state inside the first storage container;
A second storage container capable of storing at least one or more of the first storage containers;
A communication device which is provided in the second storage container and transmits the detection result of the state detector to the outside of the second storage container;
A storage device for radioactive waste, comprising: The first storage container has a first storage container main body and a first lid, and a seal member is provided between the first storage container main body and the first lid. Storage device for radioactive waste described. The radioactive waste according to claim 1 or 2, wherein the second storage container has a body and a lid, and a seal member is provided between the body and the lid. Storage device for things. The state detector includes at least a pressure detector that detects a pressure inside the first storage container and a temperature detector that detects a temperature inside the first storage container. 4. The storage device for radioactive waste according to claim 3. The radioactive waste storage device according to claim 4, wherein the state detector further includes a concentration detector that detects a hydrogen concentration or an oxygen concentration inside the first storage container. The radioactive waste storage device according to claim 1, wherein a plurality of the first storage containers are arranged in a vertical direction of the second storage container. 7. The radioactive waste storage device according to claim 1, wherein the second storage container is provided with a radiation shielding member. The radioactive waste storage device according to claim 7, wherein the second storage container is a cask provided with the radiation shielding member. The said 2nd storage container can also be arrange|positioned inside the building formed of the radiation shielding member as a metal storage container which does not provide a radiation shielding member, The said 2nd storage container can be arrange|positioned. The radioactive waste storage device according to any one of claims. A radioactive waste storage device according to any one of claims 1 to 9,
A monitoring unit that determines the state of the radioactive waste stored inside the first storage container based on the internal state of the first storage container transmitted by the communication device;
An apparatus for monitoring radioactive waste, comprising: The radioactive waste according to claim 10, wherein the monitoring unit selects a management method of the first storage container based on a state of the radioactive waste stored inside the first storage container. Monitoring equipment. The radioactive waste storage device according to any one of claims 1 to 9,
Determining the state of the radioactive waste stored inside the first storage container based on the internal state of the first storage container transmitted by the communication device;
Selecting a management method for the first storage container based on the state of radioactive waste stored inside the first storage container;
A method for managing radioactive waste, which comprises:

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