JP2024051957A - Radioactive material storage device and method - Google Patents

Abstract

[Problem] To suppress increases in facility costs in a radioactive material storage device and storage method. [Solution] The device includes a storage container for storing radioactive material, a gas supply line having an air intake valve and capable of supplying gas into the inside of the storage container, a gas exhaust line having an exhaust valve and capable of exhausting gas from the storage container, an exhaust fan provided in the gas exhaust line, a pressure detector for detecting the pressure inside the storage container, and a control device for controlling the opening and closing of the air intake valve and the exhaust valve based on the detection result of the pressure detector, and for controlling the operation of the exhaust fan. [Selected Figure] Figure 1

Description

This disclosure relates to a storage device and method for storing radioactive materials.

Radioactive materials such as radioactive waste are stored in dedicated storage containers to ensure containment, and are then stored and managed in specified storage facilities. In this case, if the radioactive material contains moisture, there is a possibility that hydrogen will be generated by radiolysis. For this reason, conventionally, air has been supplied into the storage container, or the gas within the container has been purged, thereby achieving both containment of the radioactive material and prevention of hydrogen retention. For example, an example of a conventional storage device for radioactive materials is described in Patent Document 1 below.

JP 2020-128902 A

Conventional radioactive material storage devices supply air to storage containers placed inside a storage building while scavenging the gas inside. This means that the various equipment installed in the storage building, such as air compressors, exhaust fans, piping, and filters, must be highly reliable, which creates the problem of increased equipment costs.

The present disclosure aims to solve the above-mentioned problems and provide a radioactive material storage device and method that can suppress increases in equipment costs.

To achieve the above object, the radioactive material storage device of the present disclosure comprises a storage container for storing radioactive material, a gas supply line having an air intake valve and capable of supplying gas to the inside of the storage container, a gas exhaust line having an exhaust valve and capable of exhausting gas from the storage container, an exhaust fan provided in the gas exhaust line, a pressure detector for detecting the pressure inside the storage container, and a control device for controlling the opening and closing of the air intake valve and the exhaust valve based on the detection result of the pressure detector and for controlling the operation of the exhaust fan.

The method for storing radioactive materials disclosed herein also includes a step of maintaining the inside of a storage container that stores radioactive materials in a negative pressure state, a step of detecting the pressure inside the storage container, and a step of scavenging the storage container when the pressure inside the storage container exceeds a preset upper pressure limit value.

The radioactive material storage device and storage method disclosed herein can suppress increases in equipment costs.

FIG. 1 is a schematic diagram showing the configuration of a radioactive material storage device according to this embodiment. FIG. 2 is a flow chart for carrying out the storage container scavenging process. FIG. 3 is a flow chart for carrying out the container monitoring process. FIG. 4 is a flow chart for carrying out a response process when an abnormality occurs.

Below, a preferred embodiment of the present disclosure will be described in detail with reference to the drawings. Note that the present disclosure is not limited to these embodiments, and when there are multiple embodiments, the present disclosure also includes configurations that combine the various embodiments. Furthermore, the components in the embodiments include those that a person skilled in the art would easily imagine, those that are substantially the same, and those that are within the so-called equivalent range.

<Radioactive material storage device>
FIG. 1 is a schematic diagram showing the configuration of a radioactive material storage device according to this embodiment.

As shown in FIG. 1, the radioactive material storage device 10 includes a storage container 11, a gas supply line 12, a gas exhaust line 13, an exhaust fan 14, a pressure detector 15, a hydrogen concentration detector 16, and a control device 17.

One or more storage containers 11 are placed at a predetermined position. The number of storage containers 11 to be placed is not limited. The multiple storage containers 11 are placed at intervals. The storage container 11 stores radioactive material 100, for example, radioactive waste, inside and is sealed. Here, the radioactive material is, for example, radioactive waste generated in a reprocessing plant, radioactive waste generated in decommissioning work, spent nuclear fuel generated in a nuclear power plant, etc. The storage container 11 has a container body and a lid, although not shown. The storage container 11 is a shielding container. Depending on the contents, the neutron shielding function may be enhanced by using a material or resin containing boron and boron compounds that have a neutron shielding function.

The storage container 11 may be configured to suppress an increase in hydrogen concentration by disposing a hydrogen adsorbent or a hydrogen recombination catalyst inside.

The storage container 11 is connected to a gas supply line 12 and a gas exhaust line 13. The gas supply line 12 can supply gas (air) from outside the storage container 11 to the inside of the storage container 11. The gas exhaust line 13 can exhaust gas inside the storage container 11 to the outside.

The gas supply line 12 has an intake pipe 31, an intake connection pipe 32, a branch pipe 33, a connection hose 34, and a communication pipe 35. The gas supply line 12 has an intake opening/closing valve 36 and an intake air filter (e.g., a HEPA filter) 37 provided in the communication pipe 35. The intake pipe 31 is connected to the intake connection pipe 32. A plurality of branch pipes 33 (three in this embodiment) are provided by branching from the intake connection pipe 32. The branch pipe 33 is connected to the communication pipe 35 via the connection hose 34. The communication pipe 35 penetrates the storage container 11 and communicates with the inside of the storage container 11. The communication pipe 35 is provided with an intake opening/closing valve 36 and an intake air filter 37. Here, the intake air filter 37 is provided between the intake opening/closing valve 36 and the storage container 11. The gas supply line 12 may be provided with no intake air filter 37, and an intake air filter 37 may be provided in the intake pipe 31.

The gas exhaust line 13 has an exhaust pipe 41, an exhaust connecting pipe 42, a branch pipe 43, a connecting hose 44, and a connecting pipe 45. The gas exhaust line 13 has an exhaust opening/closing valve 46 and an exhaust air filter (e.g., a HEPA filter) 47 provided in the connecting pipe 45. The exhaust pipe 41 is connected to the exhaust connecting pipe 42. A plurality of branch pipes 43 (three in this embodiment) are provided by branching from the exhaust connecting pipe 42. The branch pipe 43 is connected to the connecting pipe 45 via the connecting hose 44. The connecting pipe 45 penetrates the storage container 11 and communicates with the inside of the storage container 11. The connecting pipe 45 is provided with an exhaust opening/closing valve 46 and an exhaust air filter 47. Here, the exhaust air filter 47 is provided between the exhaust opening/closing valve 46 and the storage container 11. Note that the gas exhaust line 13 may not have the exhaust air filter 47, and the exhaust air filter 47 may be provided in the exhaust pipe 41.

The exhaust fan 14 is provided in the gas exhaust line 13. The exhaust fan 14 is provided in the exhaust pipe 41.

The pressure detector 15 is provided in the storage container 11 and connected to the control device 17. The pressure detector 15 detects the pressure inside the storage container 11. The pressure detector 15 outputs the detected pressure inside the storage container 11 to the control device 17. The hydrogen concentration detector 16 is provided in the storage container 11 and connected to the control device 17. The hydrogen concentration detector 16 detects the hydrogen concentration inside the storage container 11. The hydrogen concentration detector 16 outputs the detected hydrogen concentration inside the storage container 11 to the control device 17.

The control device 17 is connected to the exhaust fan 14, the intake valve 36, the exhaust valve 46, the pressure detector 15, and the hydrogen concentration detector 16. The control device 17 is connected to the exhaust fan 14, the intake valve 36, the exhaust valve 46, the pressure detector 15, and the hydrogen concentration detector 16 by a wired or wireless communication device. The control device 17 controls the opening and closing of the intake valve 36 and the exhaust valve 46 based on the detection results of the pressure detector 15 and the hydrogen concentration detector 16, and also controls the operation of the exhaust fan 14.

Specifically, the control device 17 controls the opening and closing of the intake valve 36 and the exhaust valve 46, and also controls the operation of the exhaust fan 14, thereby maintaining the inside of the storage container 11 in a negative pressure state. Furthermore, when the pressure inside the storage container 11 exceeds a preset upper pressure limit, the control device 17 opens the intake valve 36 and the exhaust valve 46 and operates the exhaust fan 14 to scavenge the inside of the storage container 11. When the hydrogen concentration inside the storage container 11 exceeds a preset upper hydrogen concentration limit, the control device 17 opens the intake valve 36 and the exhaust valve 46 and operates the exhaust fan 14 to scavenge the inside of the storage container 11.

The storage container 11 stores radioactive material 100 with the inside maintained at negative pressure. In other words, by closing the air supply valve 36 and the exhaust valve 46, the gas supply line 12 and the gas exhaust line 13 are cut off from the outside, and the negative pressure state is maintained in the storage container 11. In the radioactive material 100 stored in the storage container 11, residual moisture and organic matter are decomposed by radiation to generate hydrogen and other substances. When hydrogen is generated, the pressure inside the storage container 11 increases and the hydrogen concentration also increases. When the internal pressure of the storage container 11 increases, it becomes difficult to maintain the negative pressure state. Furthermore, when the hydrogen concentration inside the storage container 11 increases, there is a risk of a hydrogen explosion.

Therefore, the control device 17 monitors the pressure and hydrogen concentration inside the storage container 11, and when the pressure and hydrogen concentration exceed the upper limit, it scavenges the gas inside the storage container 11. The control device 17 then maintains the inside of the storage container 11 in a negative pressure state again.

The control device 17 is a controller, and is realized by, for example, a CPU (Central Processing Unit) or an MPU (Micro Processing Unit) executing various programs stored in the memory unit using the RAM as a working area.

The control device 17 is also connected to an operation device 51 and a display device 52. The operation device 51 can be operated by an operator. The operation device 51 can be operated by an operator to input various command signals to the control device 17. The operation device 51 is, for example, a keyboard or a touch-type display. The display device 52 displays the judgment results and processing contents of the control device 17. The display device 52 is, for example, a monitor.

Furthermore, an earthquake detector 53 is connected to the control device 17. The earthquake detector 53 measures the seismic intensity of the storage container 11 and outputs the measured value to the control device 17. The control device 17 controls the opening and closing of the air intake valve 36 and the exhaust valve 46 based on the detection result of the earthquake detector 53. Specifically, the control device 17 closes the air intake valve 36 and the exhaust valve 46 when the seismic intensity detected by the earthquake detector 53 exceeds a preset upper seismic intensity limit.

<How to store radioactive materials>
The method for storing radioactive materials in this embodiment includes a step of maintaining the inside of a storage container 11 that stores radioactive materials 100 in a negative pressure state, a step of detecting the pressure inside the storage container 11, and a step of performing a scavenging process of the storage container 11 when the pressure inside the storage container 11 exceeds a preset upper pressure limit value.

<Storage vessel scavenging process>
First, a description will be given of the scavenging process of the storage container 11 for creating a negative pressure state inside the storage container 11. Fig. 2 is a flow chart for carrying out the scavenging process of the storage container.

As shown in Figures 1 and 2, radioactive material 100 is stored inside storage container 11. In step S11, control device 17 opens air supply valve 36 and exhaust valve 46. In step S12, control device 17 operates exhaust fan 14. When exhaust fan 14 operates, a suction force acts on the inside of storage container 11 from gas exhaust line 13, and gas inside storage container 11 is exhausted to the outside through gas exhaust line 13. At the same time, outside air is supplied to the inside of storage container 11 through gas supply line 12. Therefore, scavenging process is performed on storage container 11 by exhausting internal gas to the outside and filling it with outside air.

In step S13, the control device 17 determines whether a preset predetermined time has elapsed since the air intake valve 36 and the air exhaust valve 46 were opened to operate the exhaust fan 14. Here, the predetermined time is the time until all the gas inside the storage container 11 is exhausted to the outside and replaced by external air, and is set according to the volume of the storage container 11 and the capacity of the exhaust fan 14, and is determined in advance by experiments, simulations, etc.

In step S13, if the control device 17 determines that a predetermined time has not elapsed since the intake valve 36 and the exhaust valve 46 were opened and the exhaust fan 14 was operated (No), the control device 17 continues the process. On the other hand, if the control device 17 determines that a predetermined time has elapsed since the intake valve 36 and the exhaust valve 46 were opened and the exhaust fan 14 was operated (Yes), the control device 17 closes the intake valve 36 in step S14. Then, the gas supply line 12 is closed, and the supply of air through the gas supply line 12 to the inside of the storage container 11 is stopped. On the other hand, the operation of the exhaust fan 14 continues, and the gas inside the storage container 11 is discharged to the outside through the gas discharge line 13. Therefore, the inside of the storage container 11 is in a negative pressure state as the gas inside is discharged to the outside.

In step S15, the control device 17 determines whether the pressure inside the storage container 11 has reached a preset specified negative pressure. Here, the specified negative pressure is a pressure for maintaining the inside of the storage container 11 in a negative pressure state, which is lower than atmospheric pressure and is set in advance.

If the control device 17 determines in step S15 that the pressure inside the storage container 11 has not reached the specified negative pressure (No), the process continues. On the other hand, if the control device 17 determines that the pressure inside the storage container 11 has reached the specified negative pressure (Yes), the control device 17 closes the exhaust opening/closing valve 46 in step S16. Then, in step S17, the exhaust fan 14 is stopped. Then, in step S18, the inside of the storage container 11 is maintained at a specified negative pressure state (specified negative pressure).

<Storage container monitoring process>
Next, a description will be given of a monitoring process for the storage container 11 for monitoring the radioactive material 100 stored in the storage container 11. Fig. 3 is a flow chart for carrying out the monitoring process inside the storage container.

As shown in Figures 1 and 3, radioactive material 100 is stored inside storage container 11, and the interior is maintained at a predetermined negative pressure state (prescribed negative pressure) by the scavenging process described above. Over time, the radioactive material 100 stored in storage container 11 decomposes remaining moisture and organic matter due to radiation, generating hydrogen and other substances. The internal pressure of storage container 11 increases due to the generation of hydrogen from radioactive material 100, a temperature rise, and the like. Control device 17 monitors the generation of hydrogen from radioactive material 100, the pressure rise, and the like.

In step S21, the control device 17 determines whether the pressure inside the storage container 11 has exceeded a preset upper pressure limit. The control device 17 compares the pressure inside the storage container 11 detected by the pressure detector 15 with the upper pressure limit. Here, the upper pressure limit is a pressure at which the inside of the storage container 11 cannot be kept sealed, and may be, for example, a pressure higher than atmospheric pressure. If the control device 17 determines that the pressure inside the storage container 11 has not exceeded the upper pressure limit (No), the control device 17 proceeds to step S22. On the other hand, if the control device 17 determines that the pressure inside the storage container 11 has exceeded the upper pressure limit (Yes), the control device 17 proceeds to step S23.

That is, when the internal pressure has not increased due to hydrogen generation or temperature rise, in step S22, the control device 17 determines whether the hydrogen concentration inside the storage container 11 has exceeded a preset hydrogen concentration upper limit value. The control device 17 compares the hydrogen concentration inside the storage container 11 detected by the hydrogen concentration detector 16 with the hydrogen concentration upper limit value. Here, the hydrogen concentration upper limit value is the hydrogen concentration at which the concentration of hydrogen generated inside the storage container 11 becomes high enough to pose a risk of explosion, and is determined in advance by experiments, etc.

When the control device 17 determines that the hydrogen concentration inside the storage container 11 does not exceed the hydrogen concentration upper limit value (No), it exits from this routine. On the other hand, when the control device 17 determines that the hydrogen concentration inside the storage container 11 has exceeded the hydrogen concentration upper limit value (Yes), it proceeds to step S23.

If the pressure inside the storage container 11 exceeds the upper pressure limit or the hydrogen concentration inside the storage container 11 exceeds the upper hydrogen concentration limit, the above-mentioned scavenging process of the storage container 11 is executed in step S23 and thereafter. That is, in step S23, the control device 17 opens the intake valve 36 and the exhaust valve 46. In step S24, the control device 17 operates the exhaust fan 14. In step S25, the control device 17 determines whether a predetermined time has elapsed since the intake valve 36 and the exhaust valve 46 were opened and the exhaust fan 14 was operated. If the control device 17 determines (No) that the predetermined time has not elapsed since the intake valve 36 and the exhaust valve 46 were opened and the exhaust fan 14 was operated, the process continues. On the other hand, if the control device 17 determines that a predetermined time has elapsed since the air intake valve 36 and the exhaust valve 46 were opened and the exhaust fan 14 was operated (Yes), then in step S26, the control device 17 closes the air intake valve 36.

In step S27, the control device 17 determines whether the pressure inside the storage container 11 has reached the specified negative pressure. If the control device 17 determines that the pressure inside the storage container 11 has not reached the specified negative pressure (No), the control device 17 continues processing. On the other hand, if the control device 17 determines that the pressure inside the storage container 11 has reached the specified negative pressure (Yes), the control device 17 closes the exhaust opening/closing valve 46 in step S28. Then, in step S29, the exhaust fan 14 is stopped. Then, in step S30, the inside of the storage container 11 is maintained at a specified negative pressure state (specified negative pressure).

<Response process when an abnormality occurs>
Finally, a description will be given of a process for dealing with an abnormality occurring in the storage container 11. Fig. 4 is a flow chart for carrying out the process for dealing with an abnormality occurring.

As shown in Figures 1 and 4, radioactive material 100 is stored inside storage container 11, and the inside is maintained at a predetermined negative pressure state (prescribed negative pressure). In this state, if an abnormality occurs in storage container 11 or the like, it may become difficult for storage container 11 to maintain the safety of radioactive material 100, and control device 17 monitors abnormalities in storage container 11 and the like.

In step S41, the control device 17 determines whether or not an abnormality has been detected. Specifically, the control device 17 determines whether or not the seismic intensity detected by the earthquake detector 53 exceeds a preset upper seismic intensity limit. The control device 17 compares the seismic intensity detected by the earthquake detector 53 with the upper seismic intensity limit. Here, the upper seismic intensity limit is a seismic intensity at which the safety of the storage container 11 and the like cannot be ensured, and is set in advance.

When the control device 17 determines that the seismic intensity detected by the earthquake detector 53 does not exceed the seismic intensity upper limit (No), it exits this routine. On the other hand, when the control device 17 determines that the seismic intensity detected by the earthquake detector 53 exceeds the seismic intensity upper limit (Yes), in step S42, the control device 17 closes the air supply valve 36 and the exhaust valve 46. In step S43, the control device 17 determines whether or not there is an abnormality in the various devices. Here, the various devices are the gas supply line 12, the gas exhaust line 13, the exhaust fan 14, the pressure detector 15, the hydrogen concentration detector 16, etc. In addition, the control device 17 determines whether or not the various devices are damaged based on input from a damage detector provided in the various devices. In addition, the control device 17 may determine whether or not the various devices are damaged based on input information on the equipment damage status by an operator.

If the control device 17 determines in step S43 that there is no damage to the various devices (No), then in step S44 it performs a scavenging process on the storage container 11 using the regular equipment. The scavenging process on the storage container 11 using the regular equipment is the scavenging process described with reference to FIG. 2, which is performed using existing equipment. On the other hand, if the control device 17 determines that there is damage to the various devices (Yes), then in step S45 it performs a scavenging process on the storage container 11 using emergency equipment. The scavenging process on the storage container 11 using emergency equipment is the scavenging process using emergency equipment prepared separately from the existing equipment. That is, the worker prepares a portable supply and exhaust equipment as emergency equipment, connects the portable supply and exhaust equipment to the storage container 11, and performs the scavenging process.

For example, if an earthquake occurs during the scavenging process of the storage container 11, the air intake valve 36 and the exhaust valve 46 that were open are immediately closed. Also, if an earthquake occurs while the storage container 11 is being maintained at negative pressure, the air intake valve 36 and the exhaust valve 46 that were closed are kept closed. Then, after checking the damage status of various equipment, scavenging is performed using normal equipment or emergency equipment, and a negative pressure state is maintained in the storage container 11 in which the radioactive material 100 is stored.

[Effects of this embodiment]
The radioactive material storage device of the first aspect comprises a storage container 11 for storing radioactive material 100, a gas supply line 12 having an air intake valve 36 and capable of supplying gas into the inside of the storage container 11, a gas discharge line 13 having an exhaust valve 46 and capable of discharging gas from the storage container 11, an exhaust fan 14 provided on the gas discharge line 13, a pressure detector 15 for detecting the pressure inside the storage container 11, and a control device 17 for controlling the opening and closing of the air intake valve 36 and the exhaust valve 46 based on the detection result of the pressure detector 15 and for controlling the operation of the exhaust fan 14.

According to the radioactive material storage device of the first aspect, the control device 17 controls the opening and closing of the air intake valve 36 and the exhaust valve 46 based on the pressure inside the storage container 11, and also controls the operation of the exhaust fan 14. That is, the storage container 11 can create a negative pressure inside by operating the exhaust fan 14. With the storage container 11 maintained at a negative pressure, the control device 17 controls the opening and closing of the air intake valve 36 and the exhaust valve 46 based on the pressure inside the storage container 11, and also controls the operation of the exhaust fan 14, thereby scavenging the inside of the storage container 11 and maintaining the negative pressure after the scavenging process. As a result, the control device 17 does not need to operate the exhaust fan 14 all the time, and does not need to ensure high reliability for various equipment such as the gas supply line 12, the gas exhaust line 13, and the exhaust fan 14, and can suppress an increase in equipment costs.

The radioactive material storage device according to the second aspect is the radioactive material storage device according to the first aspect, and furthermore, the control device 17 maintains the inside of the storage container 11 in a negative pressure state by controlling the operation of the exhaust fan 14. This makes it possible to easily ensure a negative pressure state inside the storage container 11.

The radioactive material storage device according to the third aspect is the radioactive material storage device according to the first or second aspect, and further, when the pressure inside the storage container 11 exceeds a preset upper pressure limit, the control device 17 opens the exhaust opening/closing valve 46 and operates the exhaust fan 14. As a result, when the negative pressure state cannot be maintained due to an increase in pressure inside the storage container 11, the storage container 11 can be maintained in a negative pressure state again after performing a scavenging process inside the storage container 11.

The radioactive material storage device according to the fourth aspect is a radioactive material storage device according to any one of the first to third aspects, and further includes a hydrogen concentration detector 16 that detects the hydrogen concentration inside the storage container 11, and the control device 17 opens the air intake valve 36 and the exhaust valve 46 and operates the exhaust fan 14 when the hydrogen concentration inside the storage container 11 exceeds a preset hydrogen concentration upper limit value. This makes it possible to maintain the storage container 11 in a negative pressure state again after performing a scavenging process inside the storage container 11 when safety cannot be maintained due to an increase in the hydrogen concentration inside the storage container 11.

The radioactive material storage device according to the fifth aspect is the radioactive material storage device according to any one of the first to fourth aspects, and further includes an air intake filter 37 between the air intake valve 36 and the storage container 11 in the gas supply line 12, and an exhaust air filter 47 between the exhaust valve 46 and the storage container 11 in the gas exhaust line 13. This prevents harmful substances such as radioactive material 100 from adhering to the gas supply line 12, gas exhaust line 13, and exhaust fan 14, eliminates the need to require high reliability for the gas supply line 12 and gas exhaust line 13, and ensures the safety of maintenance and replacement work.

The radioactive material storage device according to the sixth aspect is the radioactive material storage device according to any one of the first to fifth aspects, and further includes an earthquake detector 53, and the control device 17 controls the opening and closing of the air intake valve 36 and the exhaust valve 46 based on the detection results of the earthquake detector 53. As a result, by closing the air intake valve 36 and the exhaust valve 46 when an earthquake occurs, the containment of the storage container 11 can be ensured and safety can be improved even if an earthquake occurs and various equipment is damaged.

The radioactive material storage device according to the seventh aspect is a radioactive material storage device according to any one of the first to sixth aspects, and further, the storage container 11 is a shielding container made of a radiation shielding material. This allows the radioactive material 100 to be safely stored inside the storage container 11.

The method for storing radioactive material according to the eighth aspect includes the steps of maintaining the inside of a storage container 11 that stores radioactive material 100 in a negative pressure state, detecting the pressure inside the storage container 11, and scavenging the storage container 11 when the pressure inside the storage container 11 exceeds a preset upper pressure limit. This eliminates the need to operate the exhaust fan 14 at all times and the need to ensure high reliability for various pieces of equipment such as the gas supply line 12, the gas exhaust line 13, and the exhaust fan 14, thereby suppressing increases in equipment costs.

In the above-described embodiment, a temperature detector for detecting the temperature inside the storage container 11 and an oxygen concentration detector for detecting the oxygen concentration inside the storage container 11 may be provided. In this case, it is preferable that the control device 17 is configured to control the opening and closing of the air supply valve 36 and the exhaust valve 46 in accordance with the temperature detector and the oxygen concentration detector, and to control the operation of the exhaust fan 14.

REFERENCE SIGNS LIST 10 Radioactive material storage device 11 Storage container 12 Gas supply line 13 Gas exhaust line 14 Exhaust fan 15 Pressure detector 16 Hydrogen concentration detector 17 Control device 36 Air intake opening/closing valve 37 Air intake filter 46 Exhaust opening/closing valve 47 Exhaust air filter 53 Earthquake detector 100 Radioactive material

Claims (8)

A storage container for storing radioactive materials;
a gas supply line having an air supply opening/closing valve for supplying gas into the storage container;
a gas exhaust line having an exhaust on-off valve for exhausting gas from the storage container;
An exhaust fan provided in the gas exhaust line;
a pressure detector for detecting a pressure inside the container;
a control device that controls the opening and closing of the intake valve and the exhaust valve based on a detection result of the pressure detector and also controls the operation of the exhaust fan;
A radioactive material storage device comprising: The control device controls the operation of the exhaust fan to maintain the inside of the storage container in a negative pressure state.
2. The radioactive material storage device according to claim 1. When the pressure inside the storage container exceeds a preset upper pressure limit value, the control device opens the exhaust opening/closing valve and operates the exhaust fan.
3. The radioactive material storage device according to claim 1 or 2. a hydrogen concentration detector for detecting a hydrogen concentration inside the storage container;
When the hydrogen concentration inside the storage container exceeds a preset hydrogen concentration upper limit value, the control device opens the air intake valve and the exhaust valve and operates the exhaust fan.
3. The radioactive material storage device according to claim 1 or 2. the gas supply line is provided with an intake filter between the intake valve and the storage container, and the gas exhaust line is provided with an exhaust filter between the exhaust valve and the storage container;
2. The radioactive material storage device according to claim 1. An earthquake detector is provided.
the control device controls the opening and closing of the intake valve and the exhaust valve based on a detection result of the earthquake detector.
2. The radioactive material storage device according to claim 1. The storage container is a shielding container made of a radiation shielding material.
2. The radioactive material storage device according to claim 1. maintaining the inside of a storage container for storing radioactive material under a negative pressure;
detecting a pressure inside the container;
performing a scavenging process on the storage container when the pressure inside the storage container exceeds a preset upper pressure limit;
A method for storing radioactive materials.

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