KR20240049917A - Steel plate concrete structure precision connection system and method for small modular reactor - Google Patents

Abstract

Provides a system and method for manufacturing steel plate concrete structures for small module nuclear power plants. The steel plate concrete structure manufacturing system for small module nuclear power plants includes steel plate concrete assembly; and a steel sheet concrete structure obtained through combination of the steel sheet concrete assemblies transported to the joining site, wherein the steel sheet concrete assembly includes a first steel plate, a first linkage body installed on the first steel plate, and the first steel plate. A 1-1 assembly including a first reinforcing interlocking body installed on a steel plate, a second steel plate, a second interlocking body installed on the second steel plate, and a second reinforcing interlocking body installed on the second steel plate. A 2-1 assembly including a 1-2 assembly including a third steel plate, a third linkage installed on the third steel plate, and a third reinforcement linkage installed on the third steel plate; , a 2-2 assembly including a fourth steel plate, a fourth interlocking body installed on the fourth steel plate, and a fourth reinforcing interlocking body installed on the fourth steel plate, and the first assembly is , are mutually coupled to the 1-2 assembly through the first linkage and the second linkage, and the 1-2 assembly is connected to the 2-2 assembly with the second reinforcing linkage and the second linkage. 4 They are coupled to each other through reinforcing linkages, and the 2-2 assembly is coupled to the 2-1 assembly through the third linkage and the 4th linkage, and the 2-1 assembly is , are mutually coupled to the 1-1 assembly via the first reinforcing linkage and the third reinforcing linkage.

Description

Steel plate concrete structure manufacturing system and method for small modular nuclear power plant {Steel plate concrete structure precision connection system and method for small modular reactor}

The present invention relates to a system and method for manufacturing steel plate concrete structures for small module nuclear power plants.

In the case of small module nuclear power plant steel-plate concrete (SC) structures, land transportation must be possible. Therefore, after manufacturing small unit modules at the factory, they must be brought to the site and then pre-combined into medium modules at a workshop near the site. Afterwards, it is transported back to the construction site and installed.

During the on-site workshop mid-module assembly and construction site installation process, bonding between unit modules occurs, such as bonding between SC structures or between composite modules and SC structures linked to SC structural modules.

In this connection, there is a problem that the constructability of the joint is deteriorated due to errors in the production of the SC structure module and installation errors in the system equipment that occur during the module manufacturing and construction process. In addition, there is a problem that the construction period is delayed due to the deterioration of the constructability of these joints. Therefore, special measures are needed to improve constructability when joining small module nuclear power plant SC modules.

Korean Patent Publication No. 10-2015-0061767

The problem that the present invention aims to solve is to facilitate bonding between unit modules, such as bonding between SC structures or between composite modules linked to SC structural modules and SC structures during field workshop heavy module assembly and construction site installation.

In particular, in this connection, it is intended to prevent deterioration of the constructability of the joint due to SC structural module manufacturing errors and system equipment installation errors that occur during the module manufacturing and construction process.

In addition, this is to prevent the construction period from being delayed due to the deterioration of the constructability of these joints.

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 method of manufacturing a steel sheet concrete structure for a small module nuclear power plant according to an aspect of the present invention for achieving the above problem, comprising the steps of preparing a steel sheet concrete assembly; A step of transporting the steel plate concrete assembly to a joining site and combining it into a steel plate concrete structure, wherein the steel plate concrete assembly includes a first steel plate, a first annexation body installed on the first steel plate, and a first linkage body installed on the first steel plate. A 1-1 assembly including a first reinforcing interlocking body installed, a second steel plate, a second interlocking body installed on the second steel plate, and a second reinforcing interlocking body installed on the second steel plate. It includes a 1-2 assembly, wherein the second assembly includes a third steel plate, a third linkage body installed on the third steel plate, and a third reinforcement linkage body installed on the third steel plate. -Comprising a 2-2 assembly including a 1 assembly, a 4th steel plate, a 4th linkage installed on the 4th steel plate, and a 4th reinforcement linkage installed on the 4th steel plate, wherein the first -1 assembly is coupled to the 1-2 assembly via the first linkage and the second linkage, and the 1-2 assembly is connected to the 2-2 assembly with the second reinforcement linkage. They are coupled to each other through the sieve and the fourth reinforcing linkage, and the 2-2 assembly is coupled to the 2-1 assembly through the third linkage and the fourth linkage, and the second The -1 assembly is coupled to the 1-1 assembly via the first reinforcing linkage and the third reinforcing linkage.

In addition, the steel plate welding is performed on the first side portion of the first steel plate and the second side portion of the second steel plate opposite the first side portion, and the first side portion and the second side portion are indented inward while facing each other. A recessed portion is formed, and the steel sheet welding is performed on the recessed portion.

In addition, the recessed portion is formed in the vertical direction, and the steel plate welding is performed on the recessed portion along the vertical direction.

In addition, the first linkage body includes a 1-1 structural part installed on the first steel plate side, a 1-2 structural part positioned to face the 1-1 structural part on the first steel plate side, and the first structural part. It includes a first extension part connecting the -1 structural part and the 1-2 structural part.

In addition, the first reinforcing linkage body includes a 2-1 structural part installed on the second steel plate side, a 2-2 structural part positioned to face the 2-1 structural part on the second steel plate side, and the second structural part. It includes a second extension part connecting the -1 structural part and the 2-2 structural part.

In addition, the 1-1 structural part and the 1-2 structural part are arranged to face the first steel plate side from the first extension part, and the 2-1 structural part and the 2-2 structural part are disposed toward the second extension part. It is arranged to face from the second steel plate side, and the first linkage body and the first reinforcing linkage body are formed to be symmetrical to each other.

In addition, the first extension portion and the second extension portion are coupled in a first coupling manner in which the first extension portion and the second extension portion are coupled through a penetrating coupling member that penetrates and couples the first extension portion to each other while facing each other.

In addition, the first extension includes a first protruding structure protruding toward the second steel plate, and the second extension has an accommodating space having a shape corresponding to the first protruding structure, and the first extension and The second extension part is coupled by a second coupling method in which the first protruding structure is inserted into the receiving space in an upward direction.

In addition, the first steel plate has the first reinforcing interlocking body installed in a direction perpendicular to the first interlocking body, and the third steel plate has the second reinforcing interlocking body installed in a direction perpendicular to the third interlocking body. In the steel plate, a third reinforcing interlocking body is installed in a direction perpendicular to the first reinforcing interlocking body, and in the fourth steel plate, a fourth reinforcing interlocking body is installed in a direction perpendicular to the fourth interlocking body.

In addition, the first linkage includes a 1-1 structural part installed on the first steel plate side and a first extension part extending in a right angle direction from the 1-1 structural part, and the first reinforcing linkage includes the first structural part. It includes a 2-1 structural part installed on the second steel plate side, and a second extension part extending in a right angle direction from the 2-1 structural part, and the third linkage body is installed on the third steel plate side. It includes a structural part and a third extension part extending perpendicularly from the 3-1 structural part, and the fourth linkage body includes a 4-1 structural part installed on the fourth steel plate side, and a third extension part extending at a right angle from the 3-1 structural part. It includes a fourth extension extending in a right angle direction.

A steel sheet concrete structure manufacturing system for small module nuclear power plants according to another aspect of the present invention for achieving the above problem, comprising: a steel sheet concrete assembly; and a steel sheet concrete structure obtained through combination of the steel sheet concrete assemblies transported to the joining site, wherein the steel sheet concrete assembly includes a first steel plate, a first linkage body installed on the first steel plate, and the first steel plate. A 1-1 assembly including a first reinforcing interlocking body installed on a steel plate, a second steel plate, a second interlocking body installed on the second steel plate, and a second reinforcing interlocking body installed on the second steel plate. A 1-2 assembly comprising a 1-2 assembly, wherein the second assembly includes a 3rd steel plate, a 3rd linkage body installed on the 3rd steel plate, and a 3rd reinforcement linkage body installed on the 3rd steel plate. It includes a 2-1 assembly, a 4th steel plate, a 4th linkage installed on the 4th steel plate, and a 2-2 assembly including a 4th reinforcement linkage installed on the 4th steel plate, The 1-1 assembly is coupled to the 1-2 assembly via the first linkage and the second linkage, and the 1-2 assembly is connected to the 2-2 assembly with the second linkage. They are coupled to each other through the reinforcing linkage and the fourth reinforcing linkage, and the 2-2 assembly is coupled to the 2-1 assembly through the third and fourth linkages, The 2-1 assembly is coupled to the 1-1 assembly via the first reinforcing linkage and the third reinforcing linkage.

According to the precision joining system and method of steel plate concrete modules for small module nuclear power plants of the present invention as described above, one or more of the following effects are achieved.

The present invention can easily perform bonding between unit modules, such as bonding between SC structures or between composite modules linked to SC structural modules and SC structures during field workshop heavy module assembly and construction site installation.

In particular, in this connection, it is possible to prevent deterioration of the constructability of the joint due to SC structural module manufacturing errors and system equipment installation errors that occur during the module manufacturing and construction process.

In addition, it is possible to prevent delays in the construction period due to deterioration of the constructability of such joints.

Figure 1 is a rear view showing a steel plate concrete structure for a small module nuclear power plant according to an embodiment of the present invention.
Figure 2 is a diagram showing the vertical combination of the configuration according to Figure 1.
Figure 3 is a diagram showing the left and right combination of the configuration according to Figure 1.
Figures 4 to 6 are diagrams showing the configuration according to Figure 1.
Figures 7 to 10 are diagrams showing the configuration according to Figure 1.
FIG. 11 is a diagram showing the installation state of the configuration according to FIG. 1.
Figure 12 is a flow chart sequentially showing a method of manufacturing a steel plate concrete structure for a small module nuclear power plant 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. Advantages and features of the present invention and preferred embodiments of the present invention will be described in detail below with reference to the attached drawings. The advantages and features of the present invention and its achievement will become clear by referring to the embodiments described in detail below along with the accompanying drawings. The present invention is not limited to the embodiments posted below, but may be implemented in various different forms. These examples are provided solely to ensure that the disclosure of the present invention is complete and to fully inform those skilled in the art of the present invention of the scope of the invention, and that the present invention is defined by the scope of the claims. It just becomes. Like reference numerals refer to like elements throughout the specification.

Referring to FIG. 1, a steel sheet concrete structure manufacturing system for a small module nuclear power plant according to an embodiment of the present invention includes a steel sheet concrete assembly 100. The steel plate concrete assembly 100 includes a 1-1 assembly 10, a 1-2 assembly 20, a 2-1 assembly 30, and a 2-2 assembly 40.

Here, the 1-1 assembly 10 includes a first steel plate 11, a first linkage 110, and a first reinforcement linkage 210. The 1-2 assembly 20 includes a second steel plate 12, a second linkage body 120, and a second reinforcing linkage body 220.

The 2-1 assembly 30 includes a third steel plate 21, a third linkage 130, and a third reinforcing linkage 230. The 2-2 assembly 40 includes a fourth steel plate 22, a fourth linkage body 140, and a fourth reinforcement linkage body 240.

In addition, the first linkage body 110 includes a 1-1 structural part 111, a 1-2 structural part 112, and a first extension part 113. The second linkage body 120 includes a 2-2 structural part 122, a 2-2 structural part 122, and a second extension part 123.

The steel plate concrete structure is obtained through the steel plate concrete assembly (100). The steel plate concrete assembly 100 is transported to a preset joining site and combined to produce the steel plate concrete structure. The first steel plate 11 of the 1-1 assembly 10 is provided to a preset standard.

The first linkage body 110 of the 1-1 assembly 10 is provided on the first steel plate 11. The first reinforcing linkage 210 is installed on the first steel plate 11. The second steel plate 12 of the 1-2 assembly 20 is provided to a preset standard. The second linkage body 120 of the 1-2 assembly 20 is provided on the second steel plate 12.

Meanwhile, the second reinforcing linkage 220 of the 1-2 assembly 20 is installed on the second steel plate 12. The third steel plate 21 of the 2-1 assembly 30 is provided to a preset standard.

The third steel plate 21 of the 2-1 assembly 30 is provided to a preset standard. The third linkage body 130 of the 2-1 assembly 30 is installed on the third steel plate 21. The fourth steel plate 22 of the 2-2 assembly 40 is provided to a preset standard.

In addition, the fourth linkage body 140 of the 2-2 assembly 40 is installed on the fourth steel plate 22. The fourth reinforcing linkage 240 of the 2-2 assembly 40 is installed on the fourth steel plate 22.

The 1-1 assembly 10 is coupled to the 1-2 assembly 20 via the first linkage 110 and the second linkage 120. The 1-2 assembly 20 is coupled to the 2-2 assembly 40 via the second reinforcement linkage 220 and the fourth reinforcement linkage 240.

Here, the 2-2 assembly 40 is coupled to the 2-1 assembly 30 via the third linkage 130 and the fourth linkage 140. The 2-1 assembly 30 is coupled to the 1-1 assembly 10 via the first reinforcement linkage 210 and the third reinforcement linkage 230.

In addition, the first steel plate 111, the second steel plate 12, the third steel plate 21, and the fourth steel plate 22 are provided adjacent to each other in the vertical direction, left and right direction, etc. (See Figures 2 and 3)

The steel plate welding is performed on the first side portion of the first steel plate 11 and the second side portion of the second steel plate 12 opposite the first side portion. The first side portion and the second side portion face each other to form a recessed portion E that is recessed into the inner side. (see Figure 4)

It is possible to form such an indented portion (H) using an incision method or the like. A welding area (E) through the steel plate welding is formed in the recessed portion (H). The recessed portion (H) is formed in the vertical direction. (see Figure 4)

The steel plate welding is performed on the recessed portion (H) along the vertical direction. The 1-1 structural part 111 of the first linkage body 110 is installed in a predetermined shape on the first steel plate 11 side. (see Figure 4)

In addition, the 1-2 structural part 112 of the first linkage body 110 is positioned to face the 1-1 structural part 111 on the side of the first steel plate 11. The first extension 113 of the first linkage 110 is provided to connect the 1-1 structural part 111 and the 1-2 structural part 112. (see Figure 5)

The 2-1 structural part 121 of the second linkage body 220 is installed in a predetermined shape on the second steel plate 12 side. The 2-2 structural part 122 of the second linkage body 120 is positioned to face the 2-1 structural part 121 on the second steel plate 12 side. (see Figure 5)

Meanwhile, the second linkage body 120 is provided to connect the 2-1 structural part 121 and the 2-2 structural part 122. The 1-1 structural part 111 and the 1-2 structural part 112 are arranged in the first direction L1 from the first extension part 112 toward the first steel plate 11. (see Figure 5)

The 2-1 structural part 121 and the 2-2 structural part 122 are arranged in the second direction L2 from the second extension part 123 toward the second steel plate 12. The first linkage body 110 and the second linkage body 120 are formed to be symmetrical to each other.

At this time, the first extension part 112 and the second extension part 123 are coupled by a first coupling method in which they are coupled through a penetrating coupling member 123 that penetrates and couples them while facing each other.

The first steel plate 11 has the first reinforcing linkage body 210 installed in a direction perpendicular to the first linkage body 110. In the third steel plate 21, the second reinforcing linkage body 220 is installed in a direction perpendicular to the third linkage body 130.

In addition, the second steel plate 12 has a third reinforcing interlocking body 230 installed in a direction perpendicular to the first reinforcing interlocking body 210. The fourth steel plate 22 is provided with a fourth reinforcing linkage body 240 in a direction perpendicular to the fourth linkage body 140.

The first extension portion 113 extends in a right angle direction from the first structural portion 111. The second extension portion 123 extends in a right angle direction from the 2-1 structural portion 121.

With the same structure, the third extension part (not shown) extends in a right angle direction from the 3-1 structural part (not shown). The fourth extension part (not shown) extends in a right angle direction from the 4-1 structural part (not shown).

The first extension part 112 and the second extension part 123 are coupled by a first coupling method in which the first extension part 112 and the second extension part 123 are coupled through a penetrating coupling member 123 that penetrates and couples them while facing each other. (See (a) in Figure 6)

Meanwhile, here, the first extension portion 112 and the second extension portion 123 may be provided with the first-second structural portion 112 and the second-second structural portion 122 omitted, respectively. (See (b) in Figure 6)

The first extension 112 includes a first protruding structure 114 that protrudes toward the second steel plate 12. The second extension portion 123 is formed with a receiving space 124 having a shape corresponding to the first protrusion structure. (See (c) in Figure 6)

In addition, the first extension 112 and the second extension 123 are coupled by a second coupling method in which the first protruding structure 114 is inserted into the receiving space 124 in the upward direction. (See (c) in Figure 6)

The first linkage 110 and the second linkage 120 include the 1-1 structural part 111, the 1-2 structural part 112, the 2-1 structural part 121, and the first structural part 1-1. At least a portion of the middle region P in which the 2-2 structural portion 122 does not exist is provided. (see Figure 9)

Here, the first linkage body 110 is provided with a first intermediate region (P1) among the intermediate regions (P). The second linkage body 120 is provided with a second intermediate region (P2) among the intermediate regions (P).

The first interlocking reinforcement body 210 is coupled to the first interlocking body 110 via the first intermediate region (P1). The second interlocking reinforcement body 220 is coupled to the second interlocking body 120 via the second intermediate region (P2). (See Figures 7 to 10)

The first intermediate region (P1) and the second intermediate region (P2) are in the "ㄷ" shape of the first interlocking reinforcement body 210 and the second interlocking reinforcement body 220, and have a symmetrical "ㄷ" shape. "Includes structures corresponding to ruler shapes, etc. (See Figures 7 to 10)

Meanwhile, the combination site includes adjacent to a nuclear power plant or within the nuclear power plant site. The steel plate concrete assembly 100 is preferably made by finally placing the concrete (C) within the nuclear power plant site. (see Figure 11)

Referring to FIG. 12, in the method (S100) of manufacturing a steel plate concrete structure for a small module nuclear power plant according to an embodiment of the present invention, a steel plate concrete assembly 100 is prepared. Here, the steel sheet concrete assembly is the basis for obtaining the steel sheet concrete structure.

The steel plate concrete assembly 100 includes a single component and an alternative or complex combination of a plurality of components. These steel plate concrete assemblies include those that are already manufactured and provided by manufacturers such as factories.

In addition, the steel plate concrete assembly 100 is transported to the joining site and combined into a steel plate concrete structure. Here, the combined site includes the target site prior to input into the nuclear power plant and the interior of the nuclear power plant.

The steel plate concrete assembly 100 for manufacturing the steel plate concrete structure includes at least a portion of the 1-1 assembly 10 to the 1-4 assembly 40. Each of the 1-1 assemblies 10 to 1-4 assemblies 40 can be prepared by being manufactured and combined at a manufacturing site such as a factory.

The 1-1 assembly 10 includes a first steel plate 11, a first linkage body 110 installed on the first steel plate 11, and a first assembly 110 installed on the first steel plate 11. Includes a reinforcing interlocking body (210).

The 1-2 assembly 20 includes a second steel plate 12, a second linkage body 120 installed on the second steel plate 12, and a second reinforcement installed on the second steel plate 12. Includes interlocking body 220, etc.

Here, the 2-1 assembly 30 includes a third steel plate 21, a third linkage body 130 installed on the third steel plate 21, and a third reinforcement installed on the third steel plate 21. Includes interlocking body 230, etc.

The 2-2 assembly 40 includes a fourth steel plate 22, a fourth linkage 140 installed on the fourth steel plate 22, and a fourth reinforcement linkage installed on the fourth steel plate 22. Including sieve 240, etc.

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.

10: 1-1 assembly
20: 1-2 assembly
30: 2-1 assembly
40: 2-2 assembly
11: First steel plate
12: Second steel plate
21: Third steel plate
22: Chapter 4
110: first interlocking body
111: 1-1 structural unit
112: 1-2 structural unit
113: 1st extension
120: second linkage body
121: 2-1 Rescue Department
122: 2-2 structural unit
123: Second extension

Claims (11)

A method of manufacturing a steel plate concrete structure for a small module nuclear power plant,
Preparing a steel plate concrete assembly; and
Including the step of transporting the steel plate concrete assembly to a joining site and combining it into a steel plate concrete structure,
The steel plate concrete assembly,
A 1-1 assembly including a first steel plate, a first interlocking body installed on the first steel plate, and a first reinforcing interlocking body installed on the first steel plate,
A 1-2 assembly including a second steel plate, a second interlocking body installed on the second steel plate, and a second reinforcing interlocking body installed on the second steel plate,
A 2-1 assembly including a third steel plate, a third interlocking body installed on the third steel plate, and a third reinforcing interlocking body installed on the third steel plate,
It includes a 2-2 assembly including a fourth steel plate, a fourth interlocking body installed on the fourth steel plate, and a fourth reinforcing interlocking body installed on the fourth steel plate,
The 1-1 assembly is coupled to the 1-2 assembly via the first linkage and the second linkage,
The 1-2 assembly is coupled to the 2-2 assembly via the second reinforcement linkage and the fourth reinforcement linkage,
The 2-2 assembly is coupled to the 2-1 assembly via the third linkage and the fourth linkage,
The method of manufacturing a steel sheet concrete structure for a small module nuclear power plant, wherein the 2-1 assembly is coupled to the 1-1 assembly through the first reinforcing linkage and the third reinforcing linkage. According to paragraph 1,
Steel plate welding is performed on the first side portion of the first steel plate and the second side portion of the second steel plate opposite the first side portion,
A method of manufacturing a steel plate concrete structure for a small module nuclear power plant, wherein the first side portion and the second side portion are formed to be recessed into the inside while facing each other, and the steel plate welding is performed on the recess portion. According to paragraph 2,
A method of manufacturing a steel sheet concrete structure for a small module nuclear power plant, wherein the recessed portion is formed in the vertical direction and the steel plate welding is performed on the recessed portion along the vertical direction. According to paragraph 2,
The first linkage body,
A 1-1 structural part installed on the first steel plate side, a 1-2 structural part positioned to face the 1-1 structural part on the first steel plate side, and the 1-1 structural part and the 1- A method of manufacturing a steel plate concrete structure for a small module nuclear power plant, including a first extension connecting the two structural parts. According to paragraph 4,
The first reinforcement linkage is
A 2-1 structural part installed on the second steel plate side, a 2-2 structural part positioned to face the 2-1 structural part on the second steel plate side, and the 2-1 structural part and the 2- A method of manufacturing a steel plate concrete structure for a small module nuclear power plant, including a second extension part connecting the two structural parts. According to clause 5,
The 1-1 structural part and the 1-2 structural part are arranged to face the first steel plate from the first extension part,
The 2-1 structural part and the 2-2 structural part are arranged to face the second steel plate from the second extension part,
A method of manufacturing a steel plate concrete structure for a small module nuclear power plant, wherein the first linkage body and the first reinforcing linkage body are formed to be symmetrical to each other. According to clause 6,
A method of manufacturing a steel sheet concrete structure for a small module nuclear power plant, wherein the first extension and the second extension are coupled in a first coupling manner through a penetrating coupling member that penetrates and couples each other while facing each other. According to clause 6,
The first extension includes a first protruding structure protruding toward the second steel plate,
The second extension portion is formed with an accommodating space having a shape corresponding to the first protrusion structure,
The first extension and the second extension are combined in a second coupling method in which the first protruding structure is inserted into the receiving space in the upward direction. According to clause 8,
The first steel plate is installed with the first reinforcing linkage in a direction perpendicular to the first linkage,
The third steel plate is installed with the second reinforcing linkage in a direction perpendicular to the third linkage,
In the second steel plate, a third reinforcing interlocking body is installed in a direction perpendicular to the first reinforcing interlocking body,
A method of manufacturing a steel plate concrete structure for a small module nuclear power plant, wherein the fourth steel plate is installed as a fourth reinforcing linkage in a direction perpendicular to the fourth linkage. According to clause 9,
The first linkage body includes a 1-1 structural part installed on the first steel plate side, and a first extension part extending in a right angle direction from the 1-1 structural part,
The first reinforcing linkage body includes a 2-1 structural part installed on the second steel plate side, and a second extension part extending in a right angle direction from the 2-1 structural part,
The third linkage body includes a 3-1 structural part installed on the third steel plate side, and a third extension part extending in a right angle direction from the 3-1 structural part,
The fourth linkage body includes a 4-1 structural part installed on the fourth steel plate side, and a fourth extension part extending in a right angle direction from the 4-1 structural part. A steel plate concrete structure manufacturing system for small module nuclear power plants,
Steel plate concrete assembly; and
Including a steel sheet concrete structure obtained through the combination of the steel sheet concrete assembly transported to the joining site,
The steel plate concrete assembly,
A 1-1 assembly including a first steel plate, a first interlocking body installed on the first steel plate, and a first reinforcing interlocking body installed on the first steel plate,
A 1-2 assembly including a second steel plate, a second interlocking body installed on the second steel plate, and a second reinforcing interlocking body installed on the second steel plate,
A 2-1 assembly including a third steel plate, a third interlocking body installed on the third steel plate, and a third reinforcing interlocking body installed on the third steel plate,
It includes a 2-2 assembly including a fourth steel plate, a fourth interlocking body installed on the fourth steel plate, and a fourth reinforcing interlocking body installed on the fourth steel plate,
The 1-1 assembly is coupled to the 1-2 assembly via the first linkage and the second linkage,
The 1-2 assembly is coupled to the 2-2 assembly via the second reinforcement linkage and the fourth reinforcement linkage,
The 2-2 assembly is coupled to the 2-1 assembly via the third linkage and the fourth linkage,
The 2-1 assembly is a steel plate concrete structure manufacturing system for a small module nuclear power plant, wherein the 1-1 assembly is coupled to the 1-1 assembly through the first reinforcing linkage and the third reinforcing linkage.