KR102592753B1 - Packaging container for high-dose radioactive waste from nuclear power plant decommissioning and assembly method thereof - Google Patents

Abstract

We provide packaging containers for high-dose radioactive waste from nuclear power plant decommissioning. The packaging containers for high-dose radioactive waste from nuclear power plant decommissioning include base parts; A plurality of support pillar parts installed along the circumference of the base part; Side parts respectively installed between the support pillar parts on the base parts; and an upper cover part installed to cover an upper part of the support pillar part or the side part, wherein the support pillar part and the side part form an internal receiving space on the base part, and the internal receiving space contains a high dose dose. Cement is filled with radioactive waste.

Description

Packaging container for high-dose radioactive waste from nuclear power plant decommissioning and assembly method thereof}

The present invention relates to a packaging container for high-dose radioactive waste from nuclear power plant decommissioning and a method for assembling the same.

Radioactive waste generated during nuclear power plant decommissioning requires packaging, transportation, storage, and disposal. For this purpose, containers of various sizes, such as small and medium, are being developed. These radioactive wastes must be processed through cutting, decontamination, melting, etc. and placed in packaging containers to ensure suitability for disposal. In addition, in order to deliver packaging containers to the Korea Nuclear Environment Corporation, which manages low- and medium-level radioactive waste, the soundness of the disposal site must be considered among the Corporation's various acceptance requirements. After loading the disposal container into the industrial complex's disposal depot and closing the disposal depot, the inside of the depot is grouted with cement. At this time, if the inner bottom surface of the packaging container, the internal pillars, etc. are left as empty spaces without being filled with cement, this may be a factor in deteriorating the soundness of the disposal site after corrosion of the packaging container.

Korean Patent Publication No. 10-2021-0053590

The problem that the present invention seeks to solve is to provide a packaging container for high-dose radioactive waste from nuclear power plant decommissioning that can strengthen the safety of radioactive waste disposal and secure the reliability of acceptance criteria for disposal delivery.

In addition, the aim is to provide a packaging container for high-dose radioactive waste from nuclear power plant decommissioning that can prevent repackaging work from occurring because the internal filling requirements for housing radioactive waste are not properly met.

In addition, the aim is to provide a packaging container for high-dose radioactive waste from nuclear decommissioning that can suppress or reduce worker exposure due to internal filling requirements for housing radioactive waste not being properly met.

In addition, the object is to provide a packaging container for high-dose radioactive waste from nuclear power plant decommissioning that can prevent gaps between the internal filling and the corner pillars.

In addition, the aim is to provide a packaging container for high-dose radioactive waste from nuclear decommissioning that can accommodate radioactive waste and strengthen the integrity of the packaging through the application of a bent structure on the packaging container.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

A packaging container for high-dose radioactive waste from nuclear power plant decommissioning according to one aspect of the present invention for achieving the above task is a packaging container for high-dose radioactive waste from nuclear power plant decommissioning, and includes base parts; A plurality of support pillar parts installed along the circumference of the base part; Side parts respectively installed between the support pillar parts on the base parts; and an upper cover part installed to cover an upper part of the support pillar part or the side part, wherein the support pillar part and the side part form an internal receiving space on the base part, and the internal receiving space has a high dose dose. Cement is filled with radioactive waste.

Additionally, the side parts have protrusions and depressions alternately between the inner and outer surfaces.

In addition, a gap reinforcement body is provided on at least a portion of a circumference of the first inner peripheral surface, which is the inner peripheral surface of the support pillar part, and the second inner peripheral surface, which is the inner peripheral surface of the side part, and the gap reinforcement body is positioned to contact the upper cover part. Ensure that the seal between the upper cover parts and the internal receiving space is reinforced.

In addition, a handling structure for handling the packaging container is provided on the upper part of at least one of the support pillar parts, and the upper cover part is provided with a cutout corresponding to the handling structure, and the support pillar part or the When installed to cover the upper part of the side part, the handling structure is installed to enter the incision.

In addition, the support column parts include a first wall portion. A second wall portion bent to one side of the first wall portion, a third wall portion bent to the other side of the first wall portion, a fourth wall portion bent to one side of the second wall portion, and the third wall portion It includes a fifth wall portion bent to one side and a sixth wall portion bent to one side of the third wall portion, wherein the support column parts are configured to reinforce a gap caused by filling the cement in the internal receiving space, A filling reinforcement body is provided in the first wall portion and the second wall portion.

In addition, the filling reinforcement is provided with a first structural surface installed corresponding to the first wall portion and a second structural surface installed corresponding to the second wall portion, and the first structural surface and the second structure A large number of hollow areas are formed on the surface to strengthen the bonding force on the contact due to the cement filling.

In addition, it further includes connection parts positioned between the handling structures at the top of the side parts, wherein the handling structure includes a seating portion seated on an upper portion of the side parts, an upper portion of the seating portion, and the incision. It includes an entry part that enters the part, wherein the seating part is provided with a first lower recessed part (D1) in the lower part of one side and a second lower recessed part (D2) in the lower part of the other side, and the connection parts have both longitudinal ends, respectively, It is installed by inserting into the first lower recessed part (D1) and the second lower recessed part (D2).

A method of assembling a packaging container for high-dose radioactive waste from nuclear power plant decommissioning according to another aspect of the present invention for achieving the above problem is a method of assembling a packaging container for high-dose radioactive waste from nuclear power plant decommissioning, comprising the steps of preparing base parts; Installing a plurality of support column parts along the circumference of the base parts; Installing side parts between the support pillar parts on the base parts; Installing an upper cover part on top of the support pillar parts or the side parts, wherein the support pillar parts and the side parts form an internal receiving space on the base part, and the internal receiving space contains high-dose radioactivity. Cement is filled with waste.

According to the packaging container for high-dose radioactive waste from nuclear decommissioning and its assembly method of the present invention as described above, one or more of the following effects are achieved.

The present invention can provide a packaging container for high-dose radioactive waste from nuclear power plant decommissioning that can strengthen the safety of radioactive waste disposal and secure the reliability of acceptance criteria for disposal delivery.

In addition, it is possible to provide a packaging container for high-dose radioactive waste from nuclear decommissioning that can prevent repackaging work from occurring because the internal filling requirements for housing radioactive waste are not properly met.

In addition, it is possible to provide a packaging container for high-dose radioactive waste from nuclear decommissioning that can suppress or reduce worker exposure due to internal filling requirements for housing radioactive waste not being properly met.

In addition, it is possible to provide a packaging container for high-dose radioactive waste from nuclear power plant decommissioning that can prevent gaps between the internal filling and the corner pillars.

In addition, it is possible to provide a packaging container for high-dose radioactive waste from nuclear decommissioning that can accommodate radioactive waste and strengthen the integrity of the packaging through the application of a bent structure on the packaging container.

Figure 1 is a perspective view showing a packaging container for high-dose radioactive waste from nuclear power plant decommissioning according to an embodiment of the present invention.
Figure 2 is a combined perspective view showing a packaging container for high-dose radioactive waste from nuclear power plant decommissioning according to Figure 1.
Figures 3 to 9 are diagrams showing the configurations according to Figure 1.
Figure 10 is a flow chart sequentially showing a method of assembling packaging containers for high-dose radioactive waste from nuclear power plant decommissioning according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely intended to ensure that the disclosure of the present invention is complete and to provide common knowledge in the technical field to which the present invention pertains. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.
Referring to Figures 1 to 3, the packaging container for high-dose radioactive waste from nuclear power plant decommissioning (hereinafter referred to as “packaging container 100”) according to an embodiment of the present invention includes base parts 110 and support pillar parts ( 120), side parts 130, upper cover parts 140, gap reinforcement 150, handling structure 160, connection parts 170, and filling reinforcement 180.
The support pillar parts 120 include a first wall portion 121, a second wall portion 122, a third wall portion 123, a fourth wall portion 124, a fifth wall portion 125, and a sixth wall portion 125. Includes a wall portion 126. The handling structure 160 includes a seating portion 161 and an entry portion 162.
Here, the base parts 110 of the packaging container 100 are provided in the form of a panel with a predetermined thickness. These base parts 110 are formed with a hollow forklift pocket 111 penetrating at least part of the interior.
The packaging container 100 can be lifted by entering a separate lifting means (for example, a lifting means such as a forklift) into the forklift pocket 111.
In addition, the support pillar parts 120 are installed in plural numbers along the circumference of the base parts 110. The side parts 130 are respectively installed between the support pillar parts 120 on the base parts 110.
Referring to Figure 4, the side parts 130 are provided with protrusions 131 and depressions 132 alternately between the inner and outer surfaces. The upper cover parts 140 are installed to cover the upper part of the support pillar parts 120 or the side parts 130.
Referring to FIG. 5, on the base part 110, the support pillar parts 120 and the side parts 130 form an internal receiving space (S). The internal receiving space (S) contains high-dose radioactive waste and Cement (SM) is filled together.
The gap reinforcement body 150 is provided on at least a portion of the circumference of the first inner peripheral surface of the support column parts 120 and the second inner peripheral surface of the side parts 130. The gap reinforcement body 150 is positioned to contact the upper cover parts 140. At this time, the gap reinforcer 150 reinforces the sealing state between the upper cover part 140 and the internal receiving space (S).
A handling structure 160 for handling the packaging container is provided on the top of at least one of the support pillar parts 120. Meanwhile, the upper cover parts 140 are provided with a cutout portion 141 corresponding to the handling structure 160.
In addition, the handling structure 160 is installed to cover the upper part of the support pillar part 120 or the side part 130, so that the handling structure 160 enters the cutout 141.
The first wall portion 121 of the support pillar parts 120 is provided in a predetermined standard. The second wall portion 122 is installed to be bent to one side of the first wall portion 121.
Here, the third wall portion 123 is installed to be bent to the other side of the first wall portion 121. The fourth wall portion 124 is installed to be bent to one side of the second wall portion 122.
In addition, the fifth wall portion 125 is installed to be bent to one side of the third wall portion 123. The sixth wall portion 126 is installed to be bent to one side of the fourth wall portion 124.
The filling reinforcement body 180 is used to reinforce the gap between the support column parts 120 due to filling of the cement SM in the internal receiving space S. For this purpose, the filling reinforcement 180 is provided in the first wall portion 121 and the second wall portion 122.
Referring to FIG. 6, the connection parts 170 are provided to be located between the upper part of the side part 130 and the handling structure 160. The seating portion 161 of the handling structure 160 is installed in a predetermined shape on the upper part of the side part 130.
Referring to Figures 7 and 8, the filled reinforcement body 180 is provided with a first structural surface 181 and a second structural surface 182. The first structural surface 181 is installed corresponding to the first wall portion 121. The second structural surface 182 is installed corresponding to the second wall portion 122.
A plurality of hollow regions (T) are formed on the first structural surface 181 and the second structural surface 182 to strengthen the bonding force on the contact due to filling with the cement (SM).
Referring to FIG. 9, the entry portion 162 of the handling structure 160 is provided at the top of the seating portion 161 and enters the cutout portion 141. The seating portion 161 is provided with a first lower recessed portion (D1) on one lower side and a second lower recessed portion (D2) on the other lower side.
The connection parts 170 are installed with both ends in the longitudinal direction inserted into the first lower recessed portion D1 and the second lower recessed portion D2, respectively. Meanwhile, at least the base parts 110 can be designed by, for example, bending 6t of steel plate and welding it.
Here, the side parts 130 can be formed of, for example, a 4t bent steel plate by welding. The support column parts 120 and the filling reinforcement 180 are also installed by welding, etc., and have a structure that allows cement to be filled inside during grouting.
The overall size of the packaging container 100 may be, for example, about 1800 mm wide, about 1800 mm long, about 950 mm high, and about 1 ton in weight. The gap reinforcement body 150 includes a rubber material for sealing.
Through this, when the upper cover parts 140 are seated on the support pillar parts 120, etc. after loading the contents, the packaging container 100 is maintained sealed. The handling structure 160 is provided with a hollow insertion hole for ease of handling.
These handling structures 160 are provided above and below the support pillar parts 120, respectively. The upper cover parts 140 can be connected to the connecting parts 170 with 16 M20 bolts, for example. The upper cover parts 140, for example, may have a structure in which the central portion is made of a 5t steel plate, and a bent steel plate 6t is welded to the circumferential side of the central portion.
The upper cover parts 140, for example, have a length of about 1794 mm, a width of about 1794 mm, a height of about 53 mm, and a weight of about 0.3 tons. Here, a lifting hook for lifting is mounted on the central portion of the upper cover part 140.
Referring to FIG. 10, in the method of assembling a packaging container for high-dose radioactive waste from nuclear power plant decommissioning (hereinafter referred to as “assembly method” (S100)) according to an embodiment of the present invention, base parts 110 of a predetermined shape are prepared. .
A plurality of support pillar parts 120 are installed along the circumference of the base parts 110. Side parts 130 are installed between the support pillar parts 120 on the base parts 110, respectively.
Upper cover parts 140 are installed on top of the support pillar parts 120 or the side parts 130. Here, the support pillar parts 120 and the side parts 130 on the base parts 110 form an internal receiving space (S). In addition, the internal receiving space (S) is filled with cement (SM) along with high-dose radioactive waste.
Although embodiments of the present invention have been described with reference to the above and the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. You will understand that it exists. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive.

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110: Base parts
120: Support pillar parts
130: Side parts
140: Upper cover parts
150: Gap reinforcement body
160: Handling structure
170: Connection parts
180: Filling reinforcement body

Claims (8)

As a packaging container for high-dose radioactive waste from nuclear power plant decommissioning,
base parts; A plurality of support pillar parts installed along the circumference of the base part; Side parts respectively installed between the support pillar parts on the base parts; and upper cover parts installed to cover the upper part of the support pillar parts or the side parts,
The support pillar parts and the side parts form an internal receiving space on the base part, and the internal receiving space is filled with cement along with high-dose radioactive waste,
A handling structure for handling the packaging container is provided on the top of at least one of the support pillar parts,
The upper cover part is provided with a cutout corresponding to the handling structure, and is installed to cover the upper part of the support column part or the side part so that the handling structure enters the cutout,
The support pillar parts include a first wall portion. It includes a second wall portion bent to one side of the first wall portion,
The support column parts are provided with filling reinforcements in the first wall portion and the second wall portion to reinforce the gap caused by filling the cement in the internal receiving space,
The filling reinforcement is provided with a first structural surface installed corresponding to the first wall portion and a second structural surface installed corresponding to the second wall portion, and the first structural surface and the second structural surface are provided. A packaging container for high-dose radioactive waste from nuclear power plant decommissioning in which a plurality of hollow regions are formed to strengthen the bonding force on the contact due to the cement filling. According to paragraph 1,
The side parts are packaging containers for high-dose radioactive waste from nuclear power plant decommissioning, wherein the side parts are provided with protrusions and depressions alternately between the inner and outer surfaces. According to paragraph 1,
A gap reinforcement body is provided on at least a portion of a peripheral portion of the first inner peripheral surface, which is the inner peripheral surface of the support column part, and the second inner peripheral surface, which is the inner peripheral surface of the side part,
The gap reinforcer is,
A packaging container for high-dose radioactive waste from nuclear power plant decommissioning, which is positioned in contact with the upper cover part to strengthen the seal between the upper cover part and the internal receiving space. delete delete delete According to paragraph 1,
It further includes connection parts provided to be positioned between the handling structures at the top of the side parts,
The handling structure is,
A seating portion that is seated on the upper part of the side parts,
It is provided at the upper part of the seating part and includes an entry part that enters the incision part,
The seating portion is provided with a first lower recessed portion on one lower side and a second lower recessed portion formed on the other lower side,
The connection parts are packaging containers for high-dose radioactive waste from nuclear power plant decommissioning, wherein both ends in the longitudinal direction are inserted and installed into the first lower recess and the second lower recess, respectively. As a method of assembling packaging containers for high-dose radioactive waste from nuclear power plant decommissioning,
Step in which base parts are prepared;
Installing a plurality of support column parts along the circumference of the base parts;
Installing side parts between the support pillar parts on the base parts;
It includes installing upper cover parts on top of the support pillar parts or the side parts,
On the base part, the support pillar parts and the side parts form an internal receiving space,
The internal receiving space is filled with cement along with high-dose radioactive waste,
A handling structure for handling the packaging container is provided on the top of at least one of the support pillar parts,
The upper cover part is provided with a cutout corresponding to the handling structure, and is installed to cover the upper part of the support column part or the side part so that the handling structure enters the cutout,
The support pillar parts include a first wall portion. It includes a second wall portion bent to one side of the first wall portion,
The support column parts are provided with filling reinforcements in the first wall portion and the second wall portion to reinforce the gap caused by filling the cement in the internal receiving space,
The filled reinforcement body is provided with a first structural surface installed corresponding to the first wall portion and a second structural surface installed corresponding to the second wall portion, and the first structural surface and the second structural surface have A method of assembling a packaging container for high-dose radioactive waste from nuclear power plant decommissioning, in which a plurality of hollow regions are formed to strengthen the bonding force on the contact due to the cement filling.