KR102467059B1 - A lid and a bottom filter construction of a Defective fuel storage container - Google Patents

Abstract

The present invention relates to a filter structure of a cover and bottom of a defective fuel storage container, and more particularly, by installing a perforated plate and a mesh net together in the storage container to increase the efficiency of preventing nuclear fuel material from leaking from the storage container, but through the perforated plate. It relates to a filter structure of a cover and bottom of a defective fuel storage container that enhances the integrity of the mesh network and does not deteriorate the cooling performance of the defective fuel.
To this end, a storage container body forming a charging space into which defective fuel can be charged; an opening and closing plate corresponding to the charging space and extending upward along the circumference of the opening and closing plate to open and close the charging space of the storage container body; A rotational space is formed through the partition wall, but the partition wall is inserted into the charging space and is provided to shield the charging space; A metal perforated plate and a mesh net are installed in the pores, and a restraining hole communicating with the charging space is formed around the storage container body, and a corresponding hole corresponding to the restraining hole is formed in the partition wall, while rotating in the rotational space of the cover. A cross-shaped rotating blade is installed to enter and exit the corresponding hole and the restraining hole, fasten the cover to the storage container body or release the cover fastened to the storage container body, and the ventilation hole installed on the opening and closing plate ( Perforated plate and mesh net) provides a filter structure of the cover and bottom of the defective fuel storage container, characterized in that disposed with the rotor blades interposed when the rotor blades fasten the cover to the storage container body.

Description

A lid and a bottom filter construction of a defective fuel storage container}

The present invention relates to a filter structure of a cover and bottom of a defective fuel storage container, and more particularly, a mesh net and a perforated plate are configured together to prevent leakage of nuclear fuel material and to maintain cooling efficiency. It relates to a filter structure of a defective fuel storage container cover and bottom to prevent damage to the mesh network through a perforated plate.

Defective spent fuel (hereinafter referred to as 'defective fuel') refers to spent fuel that requires special management for handling, transportation and storage due to damage to the fuel assembly or fuel rod. Defective fuel generated from domestic light-water reactor nuclear power plants is stored in a separate storage container within the spent fuel storage tank, and if a dry storage facility is established in the future, it will be transported to and stored in a dry storage facility for permanent storage. Defective fuel storage containers are divided into storage containers that can be stored in fuel rod units (containers made by pulling out only defective fuel rods and gathering them together to form an assembly) and storage containers that can be stored in assembly units (containers that store nuclear fuel assemblies as they are). The fuel rod unit storage container has the disadvantage of long working time and risk factors because the nuclear fuel assembly must be disassembled to withdraw only defective fuel rods. Although it has the advantage of being excluded, it has the disadvantage of increasing the number of storage containers to be managed. However, nuclear fuel assemblies that are difficult to repair and handle due to structural defects must be handled by storing them in defective fuel storage containers.

As shown in FIG. 1, the defective fuel storage container 10 is composed of a body 11, which is a cylindrical storage container made of carbon steel, and a cover 12 made of stainless steel that can open and close the inside of the body 11. do.

On the other hand, the defective fuel storage container is formed with a plurality of drainage holes (not shown) in the upper and lower portions of the defective fuel storage container to enable drying for heat removal or dry storage when storing the defective fuel. However, there is a problem in that nuclear fuel microparticles may leak out from the defective fuel stored in the storage container because only a drain hole having a relatively large perforation size is present in the conventional defective fuel storage container. Of course, there are cases in which a mesh net having a relatively small hole size is installed in place of the drainage hole, but there is a problem in that the mesh net can be easily damaged by the external environment due to the nature of the mesh material.

Republic of Korea Registration No. 10-0421332

The present invention has been made to solve the above problems, and an object of the present invention is to install a perforated plate and a mesh net for drainage and drying on the bottom and cover of the storage container body, respectively, so that nuclear fuel material leaks from the storage container body. It is intended to provide a filter structure of the cover and bottom of the defective fuel storage container to prevent damage to the mesh network through the perforated plate while maintaining the cooling efficiency of the defective fuel.

In order to achieve the above object, the present invention provides a storage container body forming a charging space into which defective fuel can be loaded; an opening and closing plate that opens and closes the charging space of the storage container body and corresponds to the charging space, and the opening and closing plate A rotational space is formed through a partition wall extending upward along the circumference of the cover, the partition wall is inserted into the charging space and provided to shield the charging space; Pores are formed, respectively, and a metal perforated plate and a mesh net are installed in the ventilation hole, a restraining hole communicating with the charging space is formed around the storage container body, and a corresponding hole corresponding to the restraining hole is formed in the partition wall, Rotating in the rotational space of the cover, entering and exiting the corresponding hole and restraining hole, and a cross-shaped rotary blade for fastening the cover to the storage container body or releasing the cover fastened to the storage container body, is installed, Ventilation holes (perforated plate and mesh net) installed in the opening and closing plate are defective fuel storage container cover and bottom filter, characterized in that disposed with the rotary blades interposed when the rotary blades fasten the cover to the storage container body. provide structure.

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In addition, the plurality of mesh networks are overlapped, and the mesh networks are preferably overlapped so that the open rate is at least 10.67%.

The filter structure of the cover and bottom of the defective fuel storage container according to the present invention is composed of a perforated plate and a double mesh net, so that fine particles that may leak from the inside of the storage container are filtered through the mesh net, and the perforated plate provides cooling performance and While increasing the ease of drainage, the perforated plate has the effect of increasing the soundness of the filter structure of the defective fuel storage container by enabling to protect the relatively soft mesh network.

1 is a view showing a defective fuel storage container according to the prior art.
2 is an exploded view showing a defective fuel storage container having a cover and a bottom filter structure according to a preferred embodiment of the present invention.
Figure 3 is a perspective view showing the bottom surface of the defective fuel storage container provided with a filter structure of the defective fuel storage container lid and bottom according to a preferred embodiment of the present invention.
Figure 4 is a plan view showing the cover of the defective fuel storage container provided with the defective fuel storage container cover and the filter structure of the bottom according to a preferred embodiment of the present invention.
Figure 5a is a view showing a partial cross-section of the lid of the defective fuel storage container and the cover of the bottom filter structure according to a preferred embodiment of the present invention, Figure 5b is a partial cross-sectional view showing the bottom of the storage container body.
6 is a graph showing the change in pressure inside the storage container body when the defective fuel storage container is vacuum-dried.
7 is a view showing the soundness evaluation of the mesh network when the pressure inside the defective fuel storage container changes.
8 is a table showing a configuration in which the mesh network of the filter structure of the lid and the bottom of the defective fuel storage container overlaps according to a preferred embodiment of the present invention.
9 is a graph showing the temperature change of the defective fuel storage container region according to the mesh opening rate of the defective fuel storage container.

The terms or words used in this specification and claims are not limited to the usual or dictionary meanings, and the inventor can properly define the concept of the term in order to explain his or her invention in the best way. Based on this, it should be interpreted as a meaning and concept consistent with the technical spirit of the present invention.

Hereinafter, a filter structure (hereinafter referred to as 'filter structure') of a defective fuel storage container lid and bottom according to a preferred embodiment of the present invention will be described with reference to FIGS. 2 to 8 attached.

The filter structure is composed of a perforated plate for cooling and drying the defective fuel storage container and a mesh network that prevents foreign substances from being discharged from the defective fuel storage container. Accordingly, the filter structure can increase the cooling and drying efficiency as well as the foreign matter discharge prevention efficiency, and the perforated plate can protect the mesh network to prevent damage to the mesh network.

As shown in FIG. 2, the filter structure includes a storage container body 100, a cover 200, a rotary blade 300, a perforated plate 400, and a mesh network 500.

The storage container body 100 forms a charging space S into which defective fuel can be loaded. A restraining hole 110 is formed along the circumference of the upper end of the storage container body 100 . The storage container body 100 preferably has a square shape when viewed from a plane, and more preferably a square shape. The restraining hole 110 is formed on each side of the storage container body 100 . Constraint hole 110 is preferably in the form of a long hole (長空). At this time, a ventilation hole 120 is formed at the bottom of the storage container body as shown in FIGS. 3 and 5B, and a perforated plate 400 and a mesh network 500 are installed in the ventilation hole 120. The ventilation hole 120 is preferably formed in the center of the bottom of the storage container body 100 and is preferably formed in a circular shape.

The cover 200 serves to open and close the charging space S of the storage container body 100, and is preferably composed of an opening and closing plate 210 and a partition wall 220. The opening and closing plate 210 is configured to shield the charging space (S), and the partition wall 220 is configured to be inserted into the charging space (S) of the storage container body 100, and is directed upward from the circumference of the bottom plate 210. extension is formed. With this configuration, the cover 200 has a space formed between the opening/closing plate 210 and the partition wall 220, and the space is a rotational space 230 that allows the rotation blades 300 to be described below to rotate. A corresponding hole 240 corresponding to the restriction hole 110 of the storage container body 100 is formed in the partition wall 220 . Corresponding hole 240 is also preferably a long hole. It is preferable that a sealing member is installed in the partition wall 220 along the circumference of the corresponding hole 240 . Meanwhile, ventilation holes 211 are formed in the opening and closing plate 210 as shown in FIGS. 4 and 5A , and a perforated plate and a mesh network are installed in the ventilation holes 211 . A plurality of ventilation holes are formed in the opening and closing plate, which is to avoid interference with the rotating blades.

The rotary blade 300 serves to fasten the cover 200 to the storage container body 100 and is coupled to an axis so as to be rotated in the cover 200. The rotary blade 300 is axially coupled in the rotation space 230 of the cover 200 and is installed so as to be rotated through the tool 1 for fastening the cover. The rotary blade 300 is preferably in the form of a cross extending in all directions around the axis. That is, the rotary blade 300 is composed of four blades. The rotary blade 300 is formed to a length that can be inserted into the corresponding hole 240 and the restraining hole 110, respectively. That is, as the rotary blade 300 installed in the cover 200 can be inserted into the corresponding hole 240 of the cover 200 and the restraining hole 110 of the storage container body 100, the rotary blade 300 Is an intermediary means that can integrally fasten the cover 200 and the storage container body 100. The length of the rotary blade 300 is preferably a length that does not protrude from the restraining hole 110 of the storage container body 100. That is, the rotating blade 300 has a rotation radius that can be rotated in the rotating space 230, and the maximum length of the rotating blade 300 is provided to a length that can be positioned in the restraining hole 110.

The perforated plate 400 is a passage through which water for cooling the defective fuel charged into the charging space S of the storage container body 100 is introduced or water from the storage container body 100 is drained, and the ventilation holes 120 and 211 ) is installed in The perforated plate 400 filters foreign substances in the process of inflow or drainage of water as described above, and the foreign substances filtered through the perforated plate 400 are foreign substances having relatively large particles. The perforated plate 400 is made of metal and has a plurality of holes. For convenience of description, the perforated plate 400 installed in the ventilation hole 120 formed in the storage container body 100 is referred to as the main body perforated plate 410, and is installed in the ventilation hole 211 formed in the opening and closing plate 210 of the cover 200. The perforated plate 400 is called a cover perforated plate 420. The main body perforated plate 410 corresponds to the ventilation hole 120 formed in the center of the bottom of the storage container body 100, and is located on the outermost side of the bottom of the storage container body 100, as shown in FIGS. 3 and 5B. That is, the main body perforated plate 410 is to protect the mesh network 500 to be described later, and is installed on the outermost side of the bottom of the storage container main body 100. The cover perforated plate 420 is installed in the ventilation hole 211 formed in the cover 200 and is provided in plurality. The cover perforated plate 420 is installed on both sides with the rotary blade 300 interposed in order to avoid interference with the rotary blade 300. Since the rotary blade 300 is in the form of a cross, the cover perforated plate 420 is shown in FIG. As shown in, four are installed. The perforated cover plate 420 is also provided with metal, and is installed on the outermost side of the opening and closing plate 210 as shown in FIG. 5A to protect the mesh network 500.

The mesh network 500 is a configuration for preventing nuclear fuel material from leaking out of the storage container body 100 from the charging space S of the storage container body 100, and filters out foreign substances having smaller particles than the perforated plate 400. It is a composition that The mesh network 500 corresponds to each perforated plate 400 and is protected by the perforated plate 400 . Accordingly, the mesh network (hereinafter referred to as 'floor mesh network': 510) of the bottom of the storage container body 100 is installed inside the bottom of the storage container body 100, as shown in FIG. 5B, and the mesh of the cover A network (hereinafter referred to as a 'cover mesh network': 520) is installed on the lower surface of the opening/closing plate 210 as shown in FIG. 5A. On the other hand, it is preferable that each of the mesh networks 510 and 520 is overlapped in plurality. That is, after providing a plurality of mesh networks 510 and 520 to increase rigidity, it is preferable to overlap and install, preferably overlapping two sheets. For example, when vacuum drying the defective fuel storage container, as shown in FIG. 6, even if the pressure due to the evaporation of moisture contained in the storage container body 100 increases, as shown in FIG. 500) can be seen that the soundness is higher than that of the mesh network 500 of one sheet. In addition, as can be seen from FIG. 8 when the mesh net 500 is overlapped in two sheets, when the open rate is at least 10.67%, the maximum size of the hole (opening) is 0.14 mm, so even fine particles of nuclear fuel of 0.2 mm or less leak out. can prevent it from happening. Accordingly, it can be understood that the filtering efficiency does not decrease even if the mesh network 500 is overlapped with two sheets. At this time, in order to minimize the open rate of the mesh networks 500, it is understandable that when the mesh networks 500 are overlapped, the holes (open eyes) of each overlapping mesh network 500 should be staggered with each other. At this time, as shown in FIG. 9, since the cooling performance can be satisfied if the open rate of the mesh 500 is 10% or more, even if the mesh 500 is overlapped with two sheets, the open rate of the mesh 500 is Since it is at least 10.67%, it is understandable that the cooling efficiency does not decrease.

As described above, in the filter structure of the cover and bottom of the defective fuel storage container according to the present invention, the metal perforated plate 400 and the mesh network 500 are installed together, but the mesh network 500 is overlapped to form a storage container body ( 100) to prevent leakage of nuclear fuel material, while preventing deterioration in the cooling efficiency of defective fuel. In particular, the filter structure of the cover and bottom of the defective fuel storage container can improve the integrity of the mesh network 500 by allowing the metal perforated plate 400 to protect the mesh network 500.

Although the present invention has been described in detail with respect to the described embodiments, it is obvious to those skilled in the art that various changes and modifications are possible within the scope of the technical spirit of the present invention, and these changes and modifications belong to the appended claims.

100: storage container body 110: restraint hole
120,211: ventilation hole 200: cover
210: opening and closing plate 220: bulkhead
230: Rotation space 240: Corresponding ball
300: rotary blade 400: perforated plate
410: perforated plate for main body 420: perforated plate for cover
500: mesh network 510: floor mesh network
520: cover mesh network

Claims (3)

A storage container body forming a charging space in which defective fuel can be loaded;
Opens and closes the charging space of the storage container body, and forms a rotational space through an opening and closing plate corresponding to the charging space and a partition wall extending upward along the circumference of the opening and closing plate, the partition wall being inserted into the charging space to A cover provided to shield the space;
Ventilation holes are formed in the bottom of the storage container body and the opening and closing plate of the cover, respectively, and a metal perforated plate and a mesh net are installed in the ventilation holes,
A restriction hole communicating with the charging space is formed on the circumference of the storage container body, and a corresponding hole corresponding to the restriction hole is formed in the partition wall,
Rotating in the rotational space of the cover, entering and exiting the corresponding hole and restraining hole, and a cross-shaped rotary blade for fastening the cover to the storage container body or releasing the cover fastened to the storage container body, is installed,
Ventilation holes (perforated plate and mesh network) installed in the opening and closing plate are defective fuel storage container cover and bottom filter, characterized in that disposed with the rotary blades interposed when the rotary blades fasten the cover to the storage container body. rescue. delete According to claim 1,
The mesh network is overlapped in plurality, and the mesh network is overlapped so that the open rate is at least 10.67%.

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