JP2019027870A - Radioactive material storage container - Google Patents

Abstract

To provide a radioactive material storage container having a structure capable of preventing rainwater, dust or the like from entering an installation space of a sealed monitoring device for monitoring pressure of a space between a primary lid and a secondary lid.SOLUTION: A storage container 100 comprises: a container body 1 storing a radioactive material; a primary lid 2 for sealing an opening of the container body 1; a secondary lid 3 installed on the outside of the primary lid 2, and retaining pressure in a space S1 between itself and the primary lid 2 together with the primary lid 2 and the container body 1; a sealed monitoring device 4 provided at the secondary lid 3, and configured to monitor the pressure in the space S1; and a protective cover 5 covering an installation space S2 in the secondary lid 3 where the sealed monitoring device 4 is installed. A seal member 6 for sealing the installation space S2 is installed between the protective cover 5 and the secondary lid 3.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a storage container for radioactive material.

  For example, as disclosed in Patent Documents 1 and 2, a radioactive substance storage container includes a container main body that contains the radioactive substance, a primary lid that seals the opening of the container main body, and two containers installed outside the primary lid. And a secondary lid.

  Here, in the above storage containers as disclosed in Patent Documents 1 and 2, even if the sealing function of the primary lid is damaged, the radioactive substance in the container body is prevented from being released to the outside of the container body. The pressure is a negative pressure (pressure lower than atmospheric pressure). On the other hand, the pressure in the space between the primary lid and the secondary lid is a positive pressure (a pressure higher than the atmospheric pressure). Even if the sealing function of the primary lid is impaired, the radioactive material immediately flows out of the container body by the gas in the space flowing out from the space between the primary lid and the secondary lid into the container body. Release can be prevented.

  Therefore, the administrator monitors whether the sealing function of the primary lid is normally maintained by monitoring whether the pressure in the space between the primary lid and the secondary lid is lower than a predetermined pressure. . For example, Patent Documents 1 and 2 disclose that the pressure in the space is continuously monitored using the following device to always check whether the sealing function of the primary lid is maintained.

  In Patent Document 1, the pressure in the space between the primary lid and the secondary lid is monitored using a device called a pressure monitoring system including a pressure detector, a pressure propagation pipe, a valve, and the like. Yes. In Patent Document 2, the pressure in the space is monitored using a device called a sealing monitoring device.

  Here, both of the device disclosed in Patent Document 1 (pressure monitoring system) and the device disclosed in Patent Document 2 (sealing monitoring device) are installed on a secondary lid, and fall from the outside with a cover member. Protected from things.

JP, 2006-217890, A JP 2005-274237 A

On the other hand, in recent years, simplification of facilities for storing radioactive storage containers has been studied. Accordingly, the inventors of the present application have studied various problems of conventional storage containers that occur when the facility is simplified (for example, a facility that does not have a roof installed). In the meantime, it has been found that rainwater, dust and the like enter the installation space of the above-described devices (pressure monitoring system, sealing monitoring device), and that the device may break down.
The present invention has been made based on the above knowledge, and its purpose is to install rainwater, dust, etc. in the installation space of the sealing monitoring device for monitoring the pressure in the space between the primary lid and the secondary lid. It is to provide a storage container for a radioactive material having a structure capable of preventing intrusion of water.

  A radioactive substance storage container according to the present invention includes a container main body that contains a radioactive substance, a primary lid that seals the opening of the container main body, an outer space of the primary lid, and a space between the primary lid and the primary lid. A secondary lid for holding the pressure together with the primary lid and the container body; a seal monitoring device for monitoring the pressure in the space; and a secondary monitor installed on the secondary lid; And a protective cover for covering the installation space in the lid. A seal member for sealing the installation space is installed between the protective cover and the secondary lid.

  ADVANTAGE OF THE INVENTION According to this invention, even if it is a case where a storage facility is simplified, the storage container of the radioactive substance which can endure it can be provided.

It is a side view of the storage container concerning one embodiment of the present invention. It is a top view of the storage container shown in FIG. It is AA sectional drawing of FIG. It is a figure equivalent to FIG. 3 for showing the modification of a protective cover.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  A radioactive substance storage container 100 according to an embodiment of the present invention will be described with reference to FIGS. The storage container 100 is installed on the outside of the primary lid 2 and the primary lid 2 (see FIG. 3) that seals the opening of the primary container 2, the primary container 2 that contains a radioactive substance (for example, spent fuel). 2, a secondary lid 3 (see FIG. 3) that holds the pressure in the space S <b> 1 with the primary lid 2. In addition, the container main body 1 (storage container 100) may be installed vertically or may be installed horizontally. 1 and 2 show a container body 1 (storage container 100) installed vertically. Further, the storage container 100 may be a storage container dedicated to the storage of radioactive materials, or may be a storage / storage container used for transporting radioactive materials (transport / storage container).

  The container body 1 has, for example, a bottomed cylindrical shape, and the material thereof is a metal such as carbon steel, concrete, or the like. By forming the container body 1 from a metal such as carbon steel, concrete, or the like, the container body 1 has a radiation shielding function. Inside the container body 1, for example, a metal basket (not shown) formed in a lattice shape is arranged. A plurality of trunnions 9 for handling are attached to the outer peripheral portion of the container body 1.

  The primary lid 2 is a lid that seals the opening of the container body 1, and has a metal gasket 28 in order to keep the radioactive substance sealed (see FIG. 3). The metal gasket 28 is installed between the container body 1 and the outer peripheral edge of the primary lid 2. The secondary lid 3 is a lid that holds the pressure in the space S1 between the primary lid 2 and the primary lid 2 and the container body 1, and has a metal gasket 29 to hold the pressure in the space S1. (See FIG. 3). The metal gasket 29 is installed between the container body 1 and the outer peripheral edge of the secondary lid 3 on the outer side of the metal gasket 28.

  The material of the primary lid 2 and the secondary lid 3 is a metal such as carbon steel, for example. By forming the primary lid 2 and the secondary lid 3 with a metal such as carbon steel, the primary lid 2 and the secondary lid 3 have a radiation shielding function. Further, a neutron shielding material may be placed inside the secondary lid 3. The material of the primary lid 2 and the secondary lid 3 may be concrete.

  Next, as shown in FIG. 3, the storage container 100 includes a sealing monitoring device 4 for monitoring the pressure in the space S <b> 1 between the primary lid 2 and the secondary lid 3. For example, the sealing monitoring device 4 is installed in a recess 3 a provided on the upper surface of the secondary lid 3.

  For example, even if the sealing function of the primary lid 2 is damaged due to a failure of the metal gasket 28, the pressure in the container body 1 is negative (pressure lower than atmospheric pressure) so that the radioactive substance is not released to the outside. ). On the other hand, the pressure in the space S1 between the primary lid 2 and the secondary lid 3 is a positive pressure (a pressure higher than the atmospheric pressure). If the sealing function of the primary lid 2 is impaired, the gas in the space S1 flows out from the space S1 into the container body 1, and as a result, the pressure in the space S1 decreases. The administrator always checks whether the sealing function of the primary lid 2 is normally maintained by continuously monitoring whether the pressure in the space S1 is lower than a predetermined pressure using the sealing monitoring device 4. can do. The space S1 between the primary lid 2 and the secondary lid 3 and the container body 1 are filled with an inert gas such as helium gas.

  The sealing monitoring device 4 includes a pressure sensor 4a that measures the pressure in the space S1, and accessories such as piping and valves. At the bottom of the recess 3 a of the secondary lid 3, a pore 13 (gas pressure introduction path) communicating with the space S <b> 1 is provided, and a pipe constituting the sealing monitoring device 4 is connected to the pore 13. The pressure (gas) in the space S1 is guided to the pressure sensor 4a through the pores 13 and the piping.

  The cable 12 for taking out the signal of the pressure sensor 4a to the outside is inserted into the duct 18 and connected to the monitoring panel 19 (see FIGS. 1 and 2). A signal from the pressure sensor 4 a is input to the monitoring panel 19 via the cable 12 and the duct 18. Whether the sealing function of the primary lid 2 is impaired by constantly monitoring the pressure (gas pressure) in the space S1 between the primary lid 2 and the secondary lid 3 with such a configuration (container body 1 It is possible to constantly check whether the inside is kept sealed.

  Here, the protective cover 5 that covers the installation space S <b> 2 in the secondary lid 3 in which the sealing monitoring device 4 is installed is attached to the secondary lid 3 by the locking member 8. The protective cover 5 is a member for protecting the installation space S2 from a fallen object from the outside, and the locking member 8 is, for example, a bolt. The material of the protective cover 5 is a metal such as carbon steel or stainless steel. Since the material of the protective cover 5 is a metal such as carbon steel or stainless steel, the sealing monitoring device 4 is protected from damage due to impact such as falling objects from the outside. In addition, since the protective cover 5 is made of metal in this way, the radiation shielding effect above the protective cover 5 can have the same effect as that of other parts.

  If the pressure sensor 4a breaks down, the monitoring of whether the sealing function of the primary lid 2 is not impaired is not accurately performed in the first place. Therefore, when one seal monitoring device 4 includes one pressure sensor 4a, usually two seal monitoring devices 4 including a spare may be installed on the secondary lid 3 as shown in FIG. When one seal monitoring device 4 includes two pressure sensors 4 a including a spare, one seal monitoring device 4 may be installed on the secondary lid 3. From the viewpoint of minimizing the shielding defect portion of radiation as much as possible, it is preferable that one hermetic monitoring device 4 including two pressure sensors 4 a including a spare is installed on the secondary lid 3.

  Here, a sealing member 6 for sealing the installation space S2 is installed between the protective cover 5 and the secondary lid 3. The sealing member 6 prevents rainwater, dust and the like from entering the installation space S2 of the sealing monitoring device 4. The seal member 6 may be installed between the lower surface of the protective cover 5 and the secondary lid 3, or may be installed between the side surface of the protective cover 5 and the secondary lid 3.

  As the seal member 6, for example, a rubber O-ring, a metal gasket, or the like is used. Since the rubber O-ring has a watertight function, the use of the rubber O-ring as the seal member 6 prevents rainwater, dust and the like from entering the installation space S2 of the seal monitoring device 4.

  On the other hand, the metal gasket has an airtight function for highly permeable helium gas in addition to a watertight function. By using a metal gasket as the seal member 6, rainwater, dust and the like are prevented from entering the installation space S <b> 2 of the sealing monitoring device 4, and the installation space S <b> 2 is the same as the space S <b> 1. Airtight state is maintained.

  Here, the gas (for example, helium gas) in the space S1 is introduced into the pressure sensor 4a, the piping, and the valve constituting the sealing monitoring device 4. Even if gas leaks into the installation space S2 from the connection part between the pipes constituting the sealing monitoring device 4, if the metal gasket is used as the seal member 6, the leaked gas will enter the installation space S2. It stays and does not leak outside between the protective cover 5 and the secondary lid 3. When the pressure in the space S1 and the pressure in the installation space S2 reach equilibrium, the gas leakage from the seal monitoring device 4 stops.

  That is, when a metal gasket is used as the seal member 6, the pressure drop in the space S <b> 1 due to gas leakage from the seal monitoring device 4 can be suppressed. Whether or not the pressure drop in the space S1 is large and the sealing function (sealability) of the primary lid 2 is maintained is monitored by the sealing monitoring device 4, so that the metal gasket 28 of the primary lid 2 and the metal gasket of the secondary lid 3 are monitored. The pressure drop in the space S1 due to causes other than 29 should be as small as possible.

  When a metal gasket is used as the seal member 6, even if the hermeticity of the sealing monitoring device 4 is somewhat inferior, the pressure drop in the space S1 due to this is suppressed, and the primary lid 2 of the sealing monitoring device 4 can be suppressed. Sealability monitoring is properly maintained. Therefore, in the past, a long service life of, for example, 60 years has been required for the seal monitoring device 4, but this need is eliminated by using a metal gasket as the seal member 6, and the pressure sensor constituting the seal monitoring device 4 4a, piping, valves and the like can be simplified. In other words, it is possible to lower the grade of the sealing performance of the sealing monitoring device 4 (for example, the sealing performance of the connecting portion between the pipes constituting the sealing monitoring device 4).

  In addition, as shown in FIG. 3, in this embodiment, rainwater, dust or the like does not enter the installation space S2 in the secondary lid 3 in which the sealing monitoring device 4 is installed from the signal extraction unit of the pressure sensor 4a. In addition, the connection terminal 7 to which the cable 12 is connected is attached (embedded) to the protective cover 5. According to this configuration, rainwater, dust and the like are prevented from entering the installation space S2 from the signal extraction portion of the pressure sensor 4a.

  In order to further prevent rainwater, dust and the like from entering the installation space S2, the connection terminal 7 portion may be hardened with resin or the like. Furthermore, a connection terminal called a hermetic seal may be used as the connection terminal 7 in order to more reliably prevent rainwater, dust and the like from entering the installation space S2. The hermetic seal is a connection terminal for sealing an electronic component or an electric component in a container or the like. Hermetic seal has a hermetically sealed structure that completely shuts off the outside air, and is sealed with glass, ceramic, silver brazing, and metal to protect electronic and electrical parts from moisture, dust, and heat in the air. Being done. Further, without using the connection terminal 7, the cable 12 extraction portion (for example, a hole through which the cable 12 passes) from the protective cover 5 or the like and the space of the cable 12 may be hardened with resin or the like.

  Furthermore, the signal extraction of the pressure sensor 4a may be performed wirelessly instead of wired (cable 12). In this case, a wireless transmitter is installed in the installation space S2, for example, a wireless receiver is installed in the monitoring panel 19. If the signal extraction of the pressure sensor 4a is performed wirelessly, the signal extraction portion of the pressure sensor 4a is not necessary in the first place, and it is not necessary to provide a hole or the like in the protective cover 5 or the like. In addition, since the reliability of a signal is higher than that of a wireless signal, it is preferable that the signal extraction of the pressure sensor 4a is a wired signal (cable 12). In addition, in taking out the signal from the pressure sensor 4a, it is preferable that the connection terminal 7 to which the cable 12 is connected is attached to the protective cover 5 in consideration of the maintainability of the device.

  Here, when the pressure sensor 4a, the piping, the valve, and the like constituting the seal monitoring device 4 are simplified on the condition that the installation space S2 of the seal monitoring device 4 is sealed by the seal member 6 or the like, the seal is sealed. In order to more appropriately maintain the monitoring of the sealing performance of the primary lid 2 by the monitoring device 4, the volume of the installation space S2 is as small as possible than the volume of the space S1 between the primary lid 2 and the secondary lid 3. Is preferred. Specifically, when the volume of the installation space S2 is v and the volume of the space S1 is V, it is preferable that v / V is a value smaller than 0.1. Even if the pressure in the space S1 is reduced due to gas leakage from the sealing monitoring device 4, if the v / V is a value smaller than 0.1, the primary lid 2 of the sealing monitoring device 4 The pressure in the space S1 hardly decreases to such an extent that the monitoring of the sealing performance is affected.

  Next, as shown in FIG. 3, in this embodiment, the protective cover 5 is attached to the secondary lid 3 so as to be flush with the outer surface 3 b of the secondary lid 3. According to this configuration, the volume of the installation space S2 can be made smaller than the case where the protective cover 25 is protruded outside the outer surface 3b of the secondary lid 3 as in a protective cover 25 shown in FIG. it can. In addition, in order to make the volume of installation space S2 smaller, the whole protective cover 5 may be located in the position inside the outer surface 3b of the secondary lid 3.

  Further, in the protective cover 25 shown in FIG. 4 to be described later, the connection terminal 7 to which the cable 12 is connected is attached to the side surface of the protective cover 25. On the other hand, when the connection terminal 7 is attached to the upper surface instead of the side surface of the protective cover 25, the protective cover is positioned flush with the outer surface 3b of the secondary lid 3 as in the protective cover 5 shown in FIG. As a result, as described above, the volume of the installation space S2 can be reduced.

  In addition, when the protective cover 5 is in a position flush with the outer surface 3b of the secondary lid 3 or inward of the outer surface 3b of the secondary lid 3, it is added when the storage container 100 is transported. The tertiary lid (not shown, a tertiary lid for transportation) installed in (1) can be easily attached to the outside of the secondary lid 3 as it is. That is, there is an advantage that the work of replacing the protective cover between the time of transportation and storage becomes unnecessary, and the same protective cover can be used both during transportation and storage.

  Further, when the storage container 100 is stored, a secondary lid 3 installed outside the primary lid 2 and a tertiary lid (not shown, a tertiary lid for storage) that covers the entire upper end of the container body 1 from above are provided. Further, it may be installed. According to this configuration, rainwater, dust, and the like are further prevented from entering the installation space S2 of the sealing monitoring device 4.

  FIG. 4 is a view corresponding to FIG. 3 for illustrating a modified example of the protective cover. In FIG. 4, the same reference numerals are assigned to the same devices and members as those shown in FIG.

  As described above, the protective cover 5 shown in FIG. 3 is flush with the outer surface 3 b of the secondary lid 3. On the other hand, the protective cover 25 of the embodiment shown in FIG. 4 is projected outward from the outer surface 3 b of the secondary lid 3. The protective cover 25 has a hat shape (convex shape), and a handle 26 is attached to the upper surface thereof. The connection terminal 7 to which the cable 12 is connected is attached to the side surface of the protective cover 5.

  If the protective cover 5 is protruded outside the outer surface 3b of the secondary lid 3, the operator who checks the sealing monitoring device 4 can easily remove the protective cover 5, and thus can easily perform the inspection work.

  Moreover, if the protective cover 25 is protruded outside the outer surface 3 b of the secondary lid 3, it is easy to increase the thickness of the upper surface portion of the protective cover 25. When the thickness of the upper surface portion of the protective cover 25 is increased, the function of protecting the sealing monitoring device 4 from falling objects or the like and the function of shielding radiation are sufficiently secured. Furthermore, since the connection terminal 7 to which the cable 12 is connected can be attached to the side surface of the protective cover 25, falling objects or the like fall on the connection terminal 7, causing damage to the connection terminal 7 and disconnection of the cable 12. The possibility can be reduced. Note that the material of the protective cover 25 is, for example, a metal such as carbon steel or stainless steel, like the protective cover 5.

1: Container body 2: Primary lid 3: Secondary lid 3b: Outer surface of secondary lid 4: Sealing monitoring device 4a: Pressure sensor 5: Protective cover 6: Seal member 7: Connection terminal 12: Cable 100: Storage container (radioactive Material storage container)
S1: Space (space between primary lid and secondary lid)
S2: Installation space (installation space for the sealing monitoring device)

Claims (6)

A container body for containing a radioactive substance;
A primary lid for sealing the opening of the container body;
A secondary lid that is installed outside the primary lid and holds the pressure in the space between the primary lid and the primary lid and the container body;
A sealing monitoring device installed on the secondary lid for monitoring the pressure in the space;
A protective cover covering an installation space in the secondary lid where the sealing monitoring device is installed;
With
A radioactive substance storage container, wherein a sealing member for sealing the installation space is installed between the protective cover and the secondary lid. The radioactive substance storage container according to claim 1,
The seal monitoring device has a pressure sensor for measuring the pressure of the space,
A radioactive substance storage container, wherein a connection terminal to which a cable for taking out a signal of the pressure sensor to the outside of the installation space is connected is attached to the protective cover. The radioactive substance storage container according to claim 1 or 2,
A radioactive substance storage container where v / V is less than 0.1, where v is the volume of the installation space and V is the volume of the space. In the storage container of the radioactive substance in any one of Claims 1-3,
The radioactive substance storage container, wherein the protective cover is flush with an outer surface of the secondary lid, or is inward of the outer surface of the secondary lid. In the storage container of the radioactive substance in any one of Claims 1-4,
A radioactive substance storage container, wherein the sealing member is a metal gasket.   A storage container for a radioactive substance according to any one of claims 1 to 5, which is also used for transporting a radioactive substance.

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