KR20100013104A - Steel plate structure and steel plate concrete wall - Google Patents

Abstract

PURPOSE: A steel plate structure and a steel plate concrete wall are provided to effectively resist against lateral force or axial force applied to the wall. CONSTITUTION: A steel plate structure comprises a pair of steel plates(12), first structure members(14), and struts(16). One side surfaces of the steel plates are each other faced, and separated. One ends of the first structure members are protruded in one ends of the steel plates. The other ends of the first structure members are strongly adhered to one surface of the steel plates. The struts maintain a separation distance of the steel plates.

Description

Steel plate structure and steel plate concrete wall

The present invention relates to a steel plate structure and a steel plate concrete wall. More particularly, the present invention relates to a steel plate concrete wall formed by combining a plurality of steel plate structures for forming a wall by pouring concrete therein with a plurality of steel plate structures forming one unit module, and placing concrete therein.

In recent years, the higher the rigidity and the larger the structure, the higher the stiffness and the improved construction has emerged as a major problem.

Reinforced concrete structure, steel structure, and steel reinforced concrete structure, which have been widely used up to now, directly assemble formwork, reinforcing steel or steel frame, and cast concrete to construct the structure, which not only increases air but also decreases reliability in quality.

As an alternative to this, steel plate concrete structure (hereinafter referred to as 'SC structure'), which is capable of exerting excellent properties in terms of rigidity, strength, deformation performance, and construction by filling concrete inside the steel sheet, is being noted. .

The SC structure is to fill the concrete inside the two steel sheets, and to place the studs, tie bars, etc. so that the concrete and the steel behaves integrally to allow the steel sheet and concrete to behave in combination. In particular, the SC structure can shorten the air through modularization in the construction of large structures such as nuclear power plants.

In the SC structure, even if the concrete inside is destroyed by the load, the steel plate still restrains the concrete, thereby exerting a greater strength. In addition, the concrete is present in the interior of the steel sheet to prevent the deterioration of the concrete by the external environment can improve the durability of the structure.

1 shows a steel plate structure before concrete pouring according to the prior art. Hereinafter, the steel structure made of steel sheet or the like before the concrete is poured in the SC structural wall will be referred to as 'steel plate structure'.

The SC structural wall constructed using the steel sheet structure according to the prior art is a strut in the form of a steel rod to vertically arrange the steel plate 102 on both sides of the wall to be formed and to fix the two steel plates 102 ( After connecting the two steel plates 102 using the 106, the concrete is poured into the space defined by the two steel plates 102 to form an SC structural wall. At this time, in order to facilitate the attachment of the steel sheet 102 and concrete, a plurality of studs 104 are provided on the inner surface of the steel sheet 102.

In the case of forming a wall by modularizing the steel plate structure according to the prior art in the field, the welding of the steel sheets of the unit module 108 to each other for bonding between the unit modules 108, in addition to welding between the steel plates to improve the bonding strength In addition, they can be plated or connected using a coupler.

However, when using the steel plate structure according to the prior art to form the SC structural wall of a large structure, such as a high-rise building, nuclear power plant, there is a problem that the thickness of the wall of the SC structure can be increased and subject to spatial constraints.

In addition, the thickness of the steel sheet and concrete should be increased as the large load is to be supported, and if the thickness of the steel sheet is increased, there is a problem in that the post-heat treatment is performed due to an increase in thermal deformation during welding between steel sheets. In particular, in the case of nuclear power plants constructed in nuclear power plants, it must effectively resist the axial force due to its own weight and the lateral force due to earthquakes. The shear strength of concrete inside the steel is small, and the steel sheet must resist the remaining shear stress. Accordingly, there is a problem in that the thickness of the steel sheet needs to be increased in order to resist the shear stress caused by the lateral force caused by the earthquake.

In addition, when modularizing the steel plate structure according to the prior art to form a wall by assembling it in the field, the plate or coupler for joining between the unit modules are exposed to the outer surface of the steel sheet to hinder the aesthetics and construction by the occurrence of secondary work There is a problem of increasing the period.

In addition, when the concrete is poured into the steel sheet structure according to the prior art, the two steel plates are connected only by the steel rod-shaped struts, there is a fear that the steel sheet is deformed due to the side pressure of the concrete not hardened.

The present invention has a structural member capable of supporting the load in addition to the steel sheet and concrete, and can reduce the thickness of the steel plate concrete wall and the thickness of the steel sheet, and can effectively resist the axial or lateral force acting on the wall To provide a concrete wall.

In addition, when the steel plate structure is made of one unit module and joined to each other in the field to form a wall, it is possible to facilitate the joining between the unit modules, and the steel plate structure and steel plate concrete wall that can disperse structurally weak joints To provide.

According to an aspect of the present invention, as a steel plate structure for forming a wall by placing concrete therein, a pair of steel plates, one surface is spaced apart from each other, one end protrudes outward from one end of the steel sheet and the other end of the steel sheet A steel sheet structure including a first structural member rigidly welded to one surface of the steel sheet in a gravity direction so as to be spaced inward from the other end and a strut for maintaining a separation distance between the pair of steel sheets.

The first structural member forms a pair, and the pair of first structural members may be rigidly joined to one surface of the pair of steel plates facing each other, and the strut may be interposed and coupled between the pair of first structural members. have. In this case, the first structural member and the strut may be H-beams.

In addition, one end may be spaced inwardly from one end of the steel sheet, and the other end may further include a second structural member that is rigidly welded to one surface of the steel sheet in a gravity direction so as to protrude outward from the other end of the steel sheet.

The first structural member and the second structural member may be hardened adjacent to each other on at least one surface of the pair of steel sheets. In this case, the first structural member and the second structural member each form a pair, and the pair of first structural members and the pair of second structural members may be respectively hardened on one surface of the pair of steel plates facing each other. The strut may be interposed and coupled between the pair of first structural members and the pair of second structural members, respectively.

The first structural member, the second structural member and the strut may be H-beams.

On the other hand, it may further include a stud (stud) protruding on one surface of the steel sheet.

In addition, according to another aspect of the present invention, in the wall formed by combining a plurality of steel plate structure constituting one unit module, and cast concrete therein, a pair of steel plate structure, one surface is spaced apart from each other facing each other The strut which maintains the separation distance of the first structural member and the pair of steel sheets in one direction of the steel plate in one direction of the steel plate so as to project outward from one end of the steel plate and the other end is spaced inward from the other end of the steel plate ( struts), wherein the first structural members of the steel plate structure arranged up and down are provided with a steel plate concrete wall, characterized in that the ends are rigidly joined to each other.

In addition, the steel sheet structure according to the present invention, one end may be further spaced inward from the one end of the steel plate and the other end may further include a second structural member that is in contact with the one side of the steel sheet in the direction of gravity so as to project outward from the other end of the steel sheet. . In this case, end portions of the second structural members of the steel plate structure, which are disposed up and down, may be in contact with each other.

The first structural member and the second structural member may be hardened adjacent to each other on at least one surface of the pair of steel sheets.

Each of the first structural member and the second structural member constitutes a pair, and the pair of first structural members and the pair of second structural members may be respectively hardened to one surface of the pair of steel plates facing each other, and the struts May be interposed and coupled between the pair of first structural members and the pair of second structural members, respectively.

The first structural member, the second structural member and the strut may be H-beams.

On the other hand, it may further include a stud (stud) protruding on one surface of the steel sheet.

In addition to the steel plate and concrete, a structural member capable of supporting the load can be provided to reduce the overall thickness of the steel plate concrete wall, thereby effectively utilizing space.

In addition, the thickness of the steel sheet can be reduced, so that the welding characteristics of the steel sheet can be improved and the size of the unit module can be increased.

It can also effectively resist axial or lateral forces acting on the steel plate concrete wall.

In addition, when the steel plate structure is made of one unit module, the joining between the unit modules can be facilitated, and the member force of the structural member is transferred directly between the unit modules, thereby increasing the rigidity of the wall.

As the invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention. In the following description of the present invention, if it is determined that the detailed description of the related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

Hereinafter, embodiments of the steel sheet structure and the steel plate concrete wall according to the present invention will be described in detail with reference to the accompanying drawings, in the description with reference to the accompanying drawings, the same or corresponding components are given the same reference numerals and Duplicate explanations will be omitted.

2 is a perspective view of a steel plate structure according to a first embodiment of the present invention, Figure 3 is a side view showing a part of the steel plate structure according to the first embodiment of the present invention, Figure 4 is a first embodiment of the present invention It is a top view which shows a part of steel plate structure which concerns. 2 to 4, a steel plate structure 10, a steel plate 12, a first structural member 14, a strut 16, and a stud 18 are shown.

In this embodiment, the pair of steel sheets 12 having one surface spaced apart from each other and one end protrudes outward from one end of the steel sheet 12 and the other end is spaced inward from the other end of the steel sheet 12. Using the first structural member 14 and the strut 16 to maintain the separation distance of the pair of steel sheets 12 to the one surface of the gravitational direction as an essential component, the overall thickness of the steel plate concrete wall It is possible to reduce, thereby improving the welding properties of the steel sheet and to enlarge the size of the unit module. It can also effectively resist axial or lateral forces acting on the steel plate concrete wall.

The pair of steel sheets 12 are provided with one surface spaced apart from each other to form a constant space between the steel sheets 12. This space is then where the concrete is to be placed, the separation distance of the steel sheet 12 can be determined according to the load acting on the steel plate concrete wall.

The steel sheet 12 is integrated with the concrete after forming the steel plate concrete wall to resist the load. In addition, the steel sheet 12 constrains the concrete even if the concrete inside breaks due to the load, thereby increasing the strength of the steel plate concrete wall.

One end of the first structural member 14 protrudes outward from one end of the steel sheet 12, and the other end is spaced inward from the other end of the steel sheet 12, and gravity is applied to one surface of any one of the pair of steel sheets 12. In a direction. This first structural member 14 is resistant to the load acting on the steel plate concrete wall together with the steel plate 12 and the concrete.

The first structural member 14 is disposed in the direction of gravity and can resist axial forces acting on the steel plate concrete wall, and can resist lateral loads caused by earthquakes, wind, and the like. That is, the first structural member 14 is coupled to one surface of the steel plate in the longitudinal direction of the steel plate concrete wall to resist the axial load along with the concrete and the steel plate in the steel plate structure 10, and the steel plate concrete wall is rigidly welded to the foundation. It resists shear force in the lateral direction caused by an earthquake or the like. In addition to the stud 18 described later, it contributes to the integration of the steel plate 12 and concrete.

As a method of hardly contacting the steel plate 12 and the first structural member 14, the steel plate 12 and the first structural member 14 are hardened using high tension bolts or rivets, or the first structural member is connected to the steel plate 12. (14) is welded so as to be integral with the steel plate (12).

As the first structural member 14, various types of structural sections, such as a-beam, H-beam, I-beam, and T-beam, may be used. In this embodiment, using the H-shaped steel as the structural member 14, the flange of the H-shaped steel is joined to one surface of the steel sheet and presented in a rigid contact form.

The first structural member 14 is structurally rigid in contact with the steel plate 12 to prevent the deformation of the steel plate structure 10 due to eccentricity or torsion when the steel plate structure 10 is manufactured at the factory and transported to the site. Deformation of the steel plate structure 10 due to the lateral pressure of the concrete that is not hardened when concrete is poured into the structure 10 can be prevented.

The first structural member 14 may be hardened only to one steel plate 12 of the two steel sheets 12, or may be hardened to the two steel sheets 12, respectively.

As shown in FIG. 2, when the first structural members 14 are in close contact with the two steel sheets 12, the first structural members 14 may be disposed to face each other. The number of the first structural members 14 coupled to one surface of the steel sheet 12 determines an appropriate number corresponding to the load acting on the steel plate concrete wall. In FIG. 2, two first structural members 14 are rigidly joined to one of a pair of steel sheets, and two first structural members 14 are rigidly joined to one of a pair of steel sheets. It is shown.

Since the first structural member 14 is structurally rigid in the gravitational direction to the steel plate 12, the rigidity with respect to the load is increased by the composite action of the steel plate 12, the concrete and the structural member 14. It is possible to form thick walls such as high-rise structures or nuclear power plants without increasing the thickness. Therefore, since the rigidity with respect to a larger load is increased without increasing the thickness of the steel sheet 12, the steel sheet structure 10 can be easily manufactured and installed by minimizing the thickness of the steel sheet 12. When assembling at the module size can be enlarged.

On the other hand, the first structural member 14 is in the form of a long steel, one end protrudes outward from one end of the steel plate 12 and the other end is in the direction of gravity on one surface of the steel plate 12 to be spaced inward from the other end of the steel sheet 12 It is intimate. When the steel plate structure 10 according to the present embodiment is manufactured in a factory as a unit module, and then bonded to each other in the field to form a wall, the bonding portion of the steel plate 12 and the bonding of the first structural member 14 To disperse the junction sites that can be structurally fragile by varying the site will be described in detail with reference to FIGS. 5 and 6.

The strut 16 maintains the separation distance of the steel plate 12 so that the pair of steel plates 12 secure a constant space. Both ends of the strut 16 may be coupled to the pair of steel sheets 12, and in the case where the first structural member 14 is zigzag coupled to the two steel sheets 12, the steel plate 12 and the first structural member 14 It is also possible to join both ends of the strut (16).

In addition, as shown in FIG. 2, when the first structural members 14 are disposed on two steel sheets 12 to face each other, the struts 16 may be coupled to the first structural members 14 facing each other. have.

The strut 16 should have proper rigidity in consideration of the thickness of the wall to maintain the separation distance of the steel sheet 12 and the transport of the steel sheet structure 10, and the like. In the case of large structures, the separation distance between the two steel sheets 12 is increased due to the increase in the thickness of the wall, so that a large rigid steel can be used as the strut 16.

In this embodiment, both the first structural member 14 and the strut 16 are made of H-shaped steel, and there is a factory manufacturing of the steel plate structure 10. First, the strut 16 is coupled to the first structural member 14 to form a frame. After forming, the steel plate 12 was bonded to the first structural member 14 to shorten the manufacturing process.

As the strut 16, various types of structural steel, such as steel bar, a-beam, c-beam, H-beam, I-beam, T-beam, can be used. In this embodiment, the form using the same H-shaped steel as the structural member 14 as the strut 16 is shown.

The stud 18 protrudes on one surface of the steel plate 12, and the steel plate 12 and concrete behave integrally to resist external loads by the composite action of the steel plate 12 and concrete. The stud 18 is uniformly disposed on one surface of the steel sheet 12 so that the concrete and the steel sheet 12 behave integrally over the entire area.

As described above, when the first structural member 14 is firmly contacted with one surface of the steel sheet 12, the first structural member 14 contributes to the integration of the concrete and the steel sheet 12. When the first structural member 14 uses a large surface area in contact with concrete such as H-beam, I-beam, or c-beam, it is possible to integrate the steel plate 12 and concrete with only the first structural member 14, so that the stud ( 14) may be omitted. Of course, in consideration of the degree of contribution of the first structural member 14 to the integration of the steel plate 12 and concrete, it is also possible to reduce the material cost by combining the studs 18 as necessary.

5 is a perspective view showing a coupling state between the steel plate structure according to the first embodiment of the present invention, Figure 6 is a view showing a coupling state between the structural members according to the first embodiment of the present invention. 5 and 6, a steel plate structure 10, a steel plate 12, a first structural member 14, a strut 16, a reinforcement plate 17, a stud 18, and a bolt 19 are shown. It is.

After the steel sheet structure 10 according to the present embodiment is manufactured in a factory using one unit module, it may be joined to each other in the field to form a wall. In addition, it is also possible to form the steel plate concrete wall by assembling the steel plate structure 10 of the unit module with each other to produce one large module and then lift it and install it in the final position and then cast concrete.

The joints between the structural materials in the structure are structurally fragile where stress is concentrated. Accordingly, one end of the first structural member 14 is projected outwardly from one end of the steel plate 12, and the other end is rigidly welded to one surface of the steel plate 12 in a gravity direction so as to be spaced inwardly from the other end of the steel plate 12. When the bonding between the unit modules, the bonding portion of the steel plate 12 and the bonding portion of the first structural member 14 may be different to disperse the bonding portion that may be structurally weak.

Referring to FIG. 5, one end of the first structural member 14 of the steel plate structure 10 disposed below protrudes from one end of the steel plate 12, and the first of the steel plate structure 10 disposed above. Since the other end of the first structural member 14 is spaced inward from the other end of the steel sheet 12, when the two steel sheet structures 10 are disposed up and down, one end of the first structural member 14 of the lower steel sheet structure 12 is disposed. It may be inserted into the upper steel plate structure 10 to be in contact with the other end of the first structural member 14 of the upper steel plate structure (10). Accordingly, the joint portions of the first structural members 14 are positioned at the inner side at the ends of the steel sheets 12 such that the joint portions of the steel sheets 12 and the joint portions of the first structural members 14 are different.

The first structural members 14 of the unit modules arranged up and down are integrally connected to transmit loads, so that the ends are rigidly joined to each other. In other words, the cross section of the lower end of the first structural member 14 of the unit module disposed on the upper end and the upper end of the first structural member 14 disposed on the lower side of the unit module to be in rigid contact with each other, thereby increasing the member force of the structural member 14 It can be delivered to the ground efficiently.

Coupling between the first structural member 14, as shown in Figure 6, the reinforcing plate 17 is padded on the joint portion of the first structural member 14 and then hardened with a high-tensile bolt 19 or rivet, or the joint portion Can be welded. Then, the protruding portion of the first structural member 14 protruding from the lower steel plate structure 10 is welded to one surface of the steel plate 12 of the upper steel plate structure 10 to be welded.

Bonding between the steel plate structures 10 arranged to the left and right may be welded to the left and right ends of the steel sheet 12 or padded with a reinforcing plate to be joined by a high tension bolt or rivet. In addition, a vertical connection member (not shown) may be coupled to the left and right ends of the steel sheet 12 in a gravity direction for horizontal coupling between the steel plate structures 10 constituting the unit module. Such a vertical connecting member may increase the cross-sectional area of the coupling cross section when joining unit modules, and when the joining between the unit modules is completed, it can resist the load acting on the steel plate concrete wall like the structural member described above.

7 is a perspective view of a steel plate structure according to a second embodiment of the present invention, Figure 8 is a perspective view showing a coupling state between the steel plate structure according to a second embodiment of the present invention. 7 and 8, a steel plate structure 10, a steel plate 12, a first structural member 14, a second structural member 15, a strut 16, and a stud 18 are shown.

The steel plate structure 10 according to the present embodiment includes a pair of steel plates 12 having one surface spaced apart from each other, one end protruding outward from one end of the steel plate 12, and the other end of the steel plate 12 at the other end of the steel plate 12. The first structural member 14 rigidly welded to one surface of the steel sheet 12 in a gravity direction so as to be spaced inwardly, and one end is spaced inward from one end of the steel plate 12, and the other end is moved outward from the other end of the steel plate 12. The strut 16 which maintains the separation distance of the second structural member 15 and the pair of steel sheets 12 which are rigidly welded to the one surface of the steel plate 12 in the gravity direction is an essential component.

Since the configuration other than the second structural member 15 is the same as the first embodiment described above, the second structural member 15 will be described.

When the steel sheet structure 10 according to the present embodiment is manufactured in a factory using one unit module, and then bonded to each other in the field to form a wall, the structural members (both on the coupling portion of the steel sheet 12) 14, 15, one end is spaced inwardly from one end of the steel sheet 12 and the other end is protruded outward from the other end of the steel sheet 12 in the direction of gravity The second structural member 15 may be further placed.

As shown in FIG. 7, one end of the first structural member 14 protrudes outward from one end of the steel plate 12, and the other end is disposed to be spaced inward from the other end of the steel plate 12, and the second structural member ( One end of the steel plate 15 is spaced inwardly from one end of the steel plate 12 and the other end is disposed to protrude outward from the other end of the steel plate 12, and the steel plate 12, the first structural member 14 and By varying the joint portion of the second structural member 15 it is possible to disperse the joint portion that can be structurally weak.

Referring to FIG. 8, one end of the first structural member 14 of the steel plate structure 10 disposed below protrudes from one end of the steel plate 12, and one end of the second structural member 15 is formed of a steel plate ( 12 is spaced inwardly from one end, and the other end of the first structural member 14 disposed on the upper side is spaced inwardly from the other end of the steel plate 12, and the other end of the second structural member 15 is steel plate 12. Since it protrudes outward from the other end of the), when the two steel plate structure 10 is disposed up and down, one end of the first structural member 14 of the lower steel plate structure 10 is inserted into the upper steel plate 12 structure In contact with the other end of the first structural member 14 of the upper steel plate structure (10). In addition, the other end of the second structural member 15 of the upper steel plate structure 10 is inserted into the lower steel plate structure 10 to be in contact with one end of the second structural member 15 of the lower steel plate structure 10. .

Therefore, the joining portion of the first structural member 14 is located at the upper portion and the joining portion of the second structural member 15 is positioned at the lower portion of the joining portion of the steel plate 12, which may be structurally weak. The site can be dispersed.

The second structural members 15 of the unit modules arranged up and down are integrally connected to transmit loads, so that the end portions are in rigid contact with each other. That is, the lower end portion of the second structural member 15 of the unit module disposed on the upper portion and the upper end portion of the second structural member 14 disposed on the lower portion are made to be in contact with each other after the cross sections coincide with each other, so that the member force of the structural member is effectively ground. To be delivered.

The first structural member 14 and the second structural member 15 may be in close contact with each other on at least one surface of the pair of steel sheets 12. Thus, by alternately disposing the first structural member 14 and the second structural member 15 on one of the pair of steel sheets 12, the load can be transmitted uniformly.

In this case, as shown in FIG. 7, the first structural member 14 and the second structural member 15 are paired with each other, so that the pair of first structural members 14 on the pair of steel sheets 12. ) And the second structural member 15 may be disposed to face each other, and the strut 16 may be coupled to the first structural member 14 and the second structural member 15 facing each other.

In the present embodiment, the first structural member 14, the second structural member 15, and the strut 16 are all made of H-shaped steel. 2 After the strut 16 is coupled to the structural member 15 to form a frame, the steel sheet 12 is joined to shorten the manufacturing process.

9 is a view showing a construction state of the steel plate concrete wall according to the third embodiment of the present invention. Referring to FIG. 9, a steel plate structure 10, concrete 30, and concrete supply unit 28 are shown.

The steel plate concrete wall according to the present embodiment is a wall formed by joining a plurality of steel plate structures constituting one unit module and placing concrete therein, and the steel plate structure is a pair of spaced surfaces facing each other. A strut which maintains a separation distance between the steel plate and the first structural member that is rigidly welded in one direction of the steel plate in the direction of gravity so that one end thereof protrudes outward from one end of the steel plate and the other end is spaced inward from the other end of the steel plate. A first structural member of the steel plate structure, which includes a strut and is disposed up and down, has its ends rigidly joined to each other. In this case, one end may be further spaced inwardly from one end of the steel plate and the other end may further include a second structural member that is rigidly welded in the direction of gravity to one surface of the steel plate so as to protrude outward from the other end of the steel plate. The second structural members may allow the ends to be in rigid contact with each other.

After manufacturing the required number of steel plate structure 10 constituting the unit module in the factory, transport it to the site, and assembled the steel plate structure 10 of the unit module with each other to produce one large module and then the concrete supply unit 28 The concrete 30 is poured through to form a steel plate concrete wall.

When the steel plate structure 10 is manufactured in a factory, it is possible to secure a high quality steel plate structure 10 due to easy quality control, and by assembling it in the field, work on the site can be minimized to shorten the air.

Since other components are as described above, a description thereof will be omitted.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art to which the present invention pertains without departing from the spirit and scope of the present invention as set forth in the claims below It will be appreciated that modifications and variations can be made.

1 is a perspective view of a steel plate structure before concrete pouring according to the prior art.

2 is a perspective view of a steel plate structure according to the first embodiment of the present invention.

3 is a side view showing a part of a steel plate structure according to the first embodiment of the present invention.

4 is a plan view showing a part of a steel plate structure according to the first embodiment of the present invention.

5 is a perspective view showing a bonding state between the steel plate structure according to the first embodiment of the present invention.

6 is a view showing a coupling state between structural members according to the first embodiment of the present invention.

7 is a perspective view of a steel plate structure according to a second embodiment of the present invention.

8 is a perspective view showing a bonding state between the steel plate structure according to the second embodiment of the present invention.

9 is a view showing a construction state of the steel plate concrete wall according to the third embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10 steel plate structure 12 steel plate

14, 15: structural member 16: strut

17: gusset 18: stud

19: bolt 30: concrete

28: concrete supply

Claims (12)

Steel plate structure for forming walls by pouring concrete therein, A pair of steel plates whose one surface is spaced apart from each other; A first structural member protruded outwardly from one end of the steel plate, and the other end being rigidly welded to one surface of the steel plate in a gravity direction so as to be spaced inwardly from the other end of the steel plate; And Steel plate structure including a strut (strut) to maintain the separation distance of the pair of steel sheets. The method of claim 1, The first structural member forms a pair, and the pair of first structural members are rigidly joined to one surface of the pair of steel plates to face each other, The strut is a steel plate structure, characterized in that coupled between the pair of the first structural member. The method of claim 2, And the first structural member and the strut are H-shaped steel. The method of claim 1, One end is spaced inward from one end of the steel plate, the other end is a steel sheet structure further comprises a second structural member is in contact with the one side of the steel sheet in the direction of gravity so as to project outward from the other end of the steel sheet. The method of claim 4, wherein The first structural member and the second structural member, Steel plate structure, characterized in that the steel plate is adjacent to each other on at least one surface of the pair of steel sheets. The method of claim 5, The first structural member and the second structural member each form a pair, and the pair of first structural members and the pair of second structural members are respectively in contact with each other on one surface of the pair of steel sheets. Become, The strut is a steel plate structure, characterized in that coupled to each other interposed between the pair of first structural member and the pair of second structural member. The method of claim 6, And said first structural member, said second structural member and said strut are H-shaped steels. The method of claim 1, Steel plate structure further comprises a stud (stud) protruding on one surface of the steel sheet. In the wall formed by combining a plurality of steel plate structure constituting one unit module, and pouring concrete therein, The steel plate structure, A pair of steel plates whose one surface is spaced apart from each other; A first structural member protruded outwardly from one end of the steel plate, and the other end being rigidly welded to one surface of the steel plate in a gravity direction so as to be spaced inwardly from the other end of the steel plate; And A strut for maintaining a separation distance of the pair of steel sheets, Steel plate concrete wall, characterized in that the end of the first structural members of the steel plate structure arranged up and down are in contact with each other. The method of claim 9, One end is spaced inwardly from one end of the steel plate, the other end is a steel plate concrete wall further comprises a second structural member in contact with the one side of the steel sheet in the direction of gravity so as to project outward from the other end of the steel sheet. The method of claim 10, Steel plate concrete wall, characterized in that the second structural members of the steel plate structure arranged up and down are in contact with each other end. The method of claim 10, The first structural member and the second structural member, Steel plate concrete wall, characterized in that the steel sheet is adjacent to each other on at least one surface of the pair of steel sheets.

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