KR102076130B1 - Shear Reinforcing Device At the Connection Between Flat Plate Slab and Steel Column - Google Patents

Abstract

The present invention provides a shear reinforcing structure for a connection unit of a steel frame column and a concrete flat slab, capable of facilitating site work of a connection unit of a steel frame column and a concrete flat slab and efficiently transferring shear stress. According to the embodiment of the present invention, the shear reinforcing structure for a connection unit of a steel frame column and a concrete flat slab includes: the steel frame column (10); a slab (20) forming a floor plate by being bonded to the steel frame column (10); and a shear reinforcing member (40) installed in the connection unit between the steel frame column (10) and the slab (20) and forming a load path transferring a shear force of a gravity direction based on the load of the slab (20) to the steel frame column (10). The shear reinforcing member (40) includes: a shear support unit (200) fixed to the outer surface of the steel frame column (10); a reinforcing unit (100) horizontally extended and coupled by being inserted into the shear support unit (200); and a height determining unit (300) horizontally coupled to a front end of the reinforcing unit (100) and enabling the reinforcing unit (100) to be hung on the shear support unit (200) when the reinforcing unit (100) is inserted into the shear support unit (200) to perform temporary assembly of the reinforcing unit (100) by determining a height or a position of the reinforcing unit (100).

Description

Shear Reinforcing Device At the Connection Between Flat Plate Slab and Steel Column}

The present invention relates to a shear reinforcing structure of a concrete flat plate slab and a steel column joint to cope with the shear stress generated at the joint between the concrete flat plate slab and the steel column.

In recent years, in connecting a column and a base plate member, attention has been paid to a flat plate structure having good workability and cost-saving effect, that is, a method of directly transferring a load of a bottom plate slab to a column without a beam. .

However, the slab and column joints of flat plate structure are vulnerable to shearing force, especially Punching shear, and in most cases, reinforced concrete columns are used to secure the integrity of the joints and to transfer the shearing force. The reality is that the case is very hard to find.

On the other hand, steel pillars have advantages such as shortening of air and ease of construction of large spaces compared to reinforced concrete columns.However, it is difficult to secure the integrity of the joint between the steel pillars manufactured in the factory and the concrete slab cast in the field. It is not well adopted.

However, in some cases, the shear reinforcement structure is installed on the upper part of the steel column, but in this case, the shear reinforcing structure is manufactured and attached to the steel column at the factory, and then transported and installed on the site. In addition, the transportation cost increases during transportation, and there is a high possibility of deformation of the product due to vibration and shock.

In addition, since the weight of the steel column structure increases, it is necessary to add a large amount of heavy equipment and manpower, thereby increasing the construction cost.

Korean Unexamined Patent Publication No. 10-2011-0083449 (2011.07.20)

Therefore, the present invention was devised to solve the above-mentioned conventional problems, and an object of the present invention is easy to field construction at the junction between the steel column and the concrete flat plate slab and the concrete flat plate slab and steel frame capable of efficient shear stress transmission It is to provide a shear reinforcing structure of the column joint.

In addition, another object of the present invention is to reduce the volume and weight during transportation and installation by minimizing the portion attached to the steel poles that are manufactured in the factory, and additionally provide the performance corresponding to the shear moment as well as the minor moment of the slab generated from the column support To provide shear reinforcement structures for concrete flat slab and steel column joints.

Therefore, the present invention may include the following examples in order to achieve the above object.

Embodiment of the present invention is a steel pillar provided with a welding coupler to which the tensile reinforcing bars are connected, a slab joined to the steel pillar to form a bottom plate, a plurality of hollow bodies embedded in the slab, between the steel pillar and the slab A shear reinforcement member provided at the joint to form a load path for transmitting the shear force in the gravity direction due to the slab load to the steel column, the shear reinforcement member extending horizontally with the shear support fixed to the outer surface of the steel column The reinforcement part which is fastened to the shear support part and the height determination part and the reinforcement part which are fastened in the transverse direction at the front end of the reinforcement part, and the reinforcement part is locked to the shear support part when the reinforcement part is fitted to the shear support part to determine and reassemble the height or position of the reinforcement part. It includes a bending stress resistance plate fixed to the upper surface and the steel column to resist the bending stress of the reinforcement part, The portion comprises a horizontally extending extension bar, a cross section at the tip of the extension bar, an end plate projecting downwardly compared to the extension bar, and a plurality of fittings fixed to be spaced apart from one surface of the end plate so that the upper end of the shear support plate can be retracted. It extends horizontally from the upper surface of the plate, the end plate and the fitting plate to be welded to the end plate at one end surface, and welded to the upper side of the fitting plate at the lower surface to prevent lateral flow of the fitting plate and at the same time due to the load of the slab. Extends and is fixed between the lower surface of the extension bar on the opposite side of the upper support plate and the downwardly protruding end plate to form a path for transmitting a shear force to the steel column to form a path for transmitting the shear force applied to the extension bar to the end plate; At least one of a lower support plate for supporting a bending moment at the bottom of the bar, wherein the fitting plate extends so as to slope outward from the bottom; A guide plate and a guide hole connected to the guide line are formed to protrude from the tip of the fitting plate, and when the extension bar is lowered by the guide line, it is in close contact with the outer surface of the steel column and includes a leveling plate that supports the extension bar to form a vertical state. It is possible to provide a shear reinforcing structure of the concrete flat plate slab and the steel column joint characterized in that the.

The present invention can be fastened by fitting the shear reinforcing structure constituting the junction of the steel column and the slab is completely fixed after the temporary assembly, the height can be easily adjusted according to the shape or design purpose of the structure to improve the workability. have.

In addition, the present invention can secure the shear performance by strengthening the integrity of the joint between the steel column and reinforced concrete flat plate slab, and secured structural safety through the sub-moment resistance of the shear reinforcement structure to increase the utilization of the technology.

1 is a side view showing a shear reinforcing structure of the concrete flat plate slab and steel pillar joint according to the present invention.
FIG. 2 is a plan view AA ′ of FIG. 1.
3 is a plan view BB ′ of FIG. 1.
4 is an elevation view CC ′ of FIG. 1.
5 is a view showing the construction site of the shear reinforcing structure of the concrete flat plate slab and steel pillar joint according to the present invention.
Figure 6 is a flow chart illustrating a construction method of the shear reinforcing structure of the concrete flat plate slab and steel pillar joint according to the present invention.
7 is an enlarged view illustrating the assembly process of FIG. 5.
8 is a front view of FIG. 7.
9 is a view showing an example of a steel frame pillar.
FIG. 10 is a diagram illustrating embodiments applied to a concrete-filled steel column (CFT) column.
11 is a view showing embodiments applied to the steel pillars are not filled with concrete.

While the present invention may be modified in various ways and may have various embodiments, specific embodiments will be illustrated in the drawings and described in detail. It is not intended to be exhaustive or to limit the invention to the specific embodiments, and to any and all alterations, equivalents, and substitutes included in the spirit and scope of the present invention for connecting and / or fixing structures extending in different directions. It should be understood as applicable.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, terms such as "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility or the possibility of addition of numbers, steps, operations, components, components, or combinations thereof.

In addition, in describing the present invention, when it is determined that the detailed description of the related known technology may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the shear reinforcing structure of the concrete flat plate slab and steel pillar joint according to the present invention.

1 is a side view showing a shear reinforcing structure of the concrete flat plate slab and steel column joint according to the invention, Figure 2 is a AA 'plan view of Figure 1, Figure 3 is a BB' plan view of Figure 1, Figure 4 CC 'elevation.

1 to 4, the present invention is a steel column 10, a slab 20 bonded to the steel column 10 to form a bottom plate or ceiling surface, and a plurality of embedded in the slab 20 Hollow bodies 30 (see FIG. 5), shear reinforcing members 40 which are fixed to the steel column 10 and transmit the shear force due to the load acting on the slab 20 to the steel column 10, and hollow A sieve 30 (see FIG. 5) and a tensile rebar 60 supporting the slab 20 are included.

Steel column 10 is any one of a square or circular steel pipe, H-beams and I-beams may be filled or not filled with concrete, an example of such a steel column 10 is shown in FIG. .

9 is a diagram illustrating an example of the steel frame column 10.

Referring to Figure 9, the steel column 10 is applied in the present invention is a steel pillar column 10 made of steel CFT column filled with concrete (see Fig. 9 (a) and (d)), Square pillars (see (b) of FIG. 9) that are not filled with concrete therein may be classified. Alternatively, the steel column 10 has a rectangular column (see (a) and (b) of FIG. 9), a circular steel pipe (see (d) and (e) of FIG. 9), and an H-beam column ( (C) of FIG. 9) or any other well-known pillar. In addition, the steel column 10 may be formed with a plurality of welding couplers 11 on the outer surface so that the tensile reinforcing bar 60 can be welded.

That is, the steel pillars 10 of FIG. 9 are not limited to, for example, for illustrative purposes, and are illustrated with rectangular pillars, circular steel tube pillars, H-beam pillars and other known pillars, and concrete is not filled or not filled. Both pillars are applicable.

The tensile reinforcement bars 60 are fastened or welded to the welding coupler 11 welded to the steel column 10 as the upper tensile bar 61 and the lower tensile bar 62, or penetrate the steel column 10. Can be extended.

Shear reinforcement member 40 is a shear support 200 is fixed to the steel column 10, the reinforcement 100 is fastened by fitting to the shear support 200 to transfer the shear force and shear stress to the column, and shear In the support portion 200, the height determining portion 300 for temporarily assembling and reinforcing the reinforcement portion 100, the bending stress resistance plate 400 for resisting the bending stress of the reinforcement portion 100, and the punching shear region It may include a stud 500 to more uniformly distribute the shear force applied in the direction of gravity.

The reinforcement part 100 includes an extension bar 110 extending horizontally, a fitting plate 140 fitted to the shear support part 200 at the tip of the extension bar 110, and an upper support plate supporting the fitting plate 140. 120, and a leveling plate 160 protruding to align vertically, and a lower support plate 150 reinforcing between the extension bar 110 and the end plate 130.

The extension bar 110 is an upright plate 112 erected between an upper flange 111 extending in an upper surface, a lower flange 113 extending in a lower surface, an upper flange 111, and a lower flange 113. ) May be included.

The fitting plate 140 is formed of a plurality of spaced apart from each other in the front of the end plate (130). Here, the fitting plate 140 includes a guide end 142 and a height determining unit 300 extending to be inclined outward from the lower end so that one or more shear support plates 210 to be described later are drawn between the fitting plates 140. The hook hole 141 which communicates with and is fixed is formed. Here, the hook hole 141 is formed as a plurality of dogs aligned in the vertical direction.

The guide end 142 extends from the plurality of fitting plates 140 to be inclined in different directions, respectively. Therefore, the guide end 142 protrudes to be inclined to the outside of the fitting plate 140 to accommodate the front end of the shear support plate 210 when the fitting plate 140 is lowered.

 The upper support plate 120 extends horizontally from the upper side of the fitting plate 140 and is connected to the end plate 130 by welding at one end surface, and the fitting plate 140 is bonded by welding at the lower surface thereof. That is, the upper support plate 120 is fixed to extend horizontally from the upper surface of the end plate 130 and the fitting plate 140 to support the fitting plate 140 fixed by welding in the lower surface to prevent the lateral flow and At the same time, a load path for transmitting the shear stress due to the load of the slab 20 to the steel column 10 is formed.

The leveling plate 160 supports the extension bar 110 to achieve a vertical state after the extension bar 110 is lowered and / or subsequently fastened to the shear support 200. That is, the leveling plate 160 is a protrusion protruding from the tip of the fitting plate 140 and closely adheres to the steel column 10 so that the extension bar 110 is vertically aligned when the extension bar 110 is lowered by the guide line 610 which will be described later. While supporting the extension bar 110.

In addition, the leveling plate 160 is a projection plate protruding from the tip of the fitting plate 140 is formed with a guide hole 161 to which the guide line 610 is fastened. Guide hook 620 is fixed to the steel frame pillar 10 to support the guide line 610.

Guide line 610 is a wire for adjusting the direction and speed to fasten the reinforcement 100 to the shear support 200 installed on the steel column (10).

The leveling plate 160, the guide rack 620, and the guide line 610 as described above are coupled to the reinforcement part 100 by lowering the shear support part 200.

The height determining unit 300 is fastened to the fitting plate 140, for example, consisting of screws and bolts fixed in communication with any one of a plurality of hook holes 141 formed in the plurality of fitting plates 140. It is assembled with the shear support plate 210 in the state. That is, the fitting plate 140 is fastened to the shear supporting plate 210 in a state in which the height determining unit 300 is fastened and fixed to the hook hole 141. Therefore, the height determiner 300 may adjust the height of the fitting plate 140 fastened to the shear support plate 210.

In addition, the present invention may further include a fixing part (not shown) for fixing the shear support plate 210 and the fitting plate 140 in communication after the shear support plate 210 is sandwiched between the fitting plate 140. .

In addition, the present invention may further include a bending stress resistance plate 400 for reinforcing the upper portion to resist bending stress by reinforcing the shaking and rigidity of the fitting plate 140 and the height determining unit 300.

The bending stress resisting plate 400 is placed so as to span the upper flange 111 of the extension bar 110 in the upper support plate 120 and then welded to the steel column 10 and the upper flange 111 and the upper support plate 120. It is fixed. The bending stress resistance plate 400 serves to resist bending stress so that the fitting plate 140 coupled to the shear supporting plate 210 and the extension bar 110 extending from the fitting plate 140 are not bent.

The lower support plate 150 is connected between the end plate 130 extending in a shape bent from the lower flange 113 to resist bending stress between the lower flange 113 and the end plate 130. In addition, the lower support plate 150 serves to transmit the shear force transmitted through the extension bar to the end plate 130 and / or the fitting plate 140, and to support the shear force and the bending moment in the lower portion of the extension bar (110). Do this. Here, the lower support plate 150 is transported in a welded state between the lower flange 113 and the end plate 130 in the factory.

The shear support 200 includes a plurality of shear support plates 210 spaced apart from each other or fixed to be inserted into the fitting plate 140 is fixed upright to the steel column (10). The shear support plate 210 may be formed with an incision 211 cut out to be inclined from the upper end, an installation tool 212 in which the height determining part 300 is installed, and a plurality of through holes 213.

The cutting end 211 extends to the mounting fixture 212 to be inclined and inclined downward from the top. Therefore, the cutting end 211 may expose the mounting fixture 212 and guide the height determining unit 300 to be placed on the mounting fixture 212.

The installation tool 212 has a semi-opening shape so that the upper side is exposed by the cut end 211. That is, the mounting fixture 212 is provided with a height determining unit 300 fastened to the fitting plate 140. For example, the height determining unit 300 includes a rod extending horizontally as a fixing bolt, and the rod is lowered by the guide line 610 and placed on the installation tool 212.

The through hole 213 is formed to have a shape and a position coincident with the hook hole 141 of the fitting plate 140. Therefore, the fixing portion (not shown) is fastened by connecting the hook hole 141 and the through hole 213 of the fitting plate 140 and the shear supporting plate 210. The fixing part (not shown) may be applied or selectively applied here.

Therefore, the height determining unit 300 is caught by the mounting hole 212 of the shear support plate 210 so that the reinforcement unit 100 lowered from the upper side can be stopped in the state in which the shear support unit 200 is fitted inward. Since the fixing portion (not shown) is in communication with the fitting plate 140 and the shear supporting plate 210 to fix the fitting plate 140 and the shear supporting plate 210.

The studs 500 are fastened so that a plurality of them are aligned in the transverse direction in the upright plate 112 of the extension bar 110. Therefore, the stud 500 may further expand the area capable of receiving the load in the direction of gravity to distribute the load in the direction of gravity due to the load of the slab 20.

Hereinafter will be described in more detail the construction process of the present invention as described above.

5 is a view showing the construction site of the shear reinforcing structure of the concrete flat plate slab and steel pillar joint according to the present invention, Figure 6 is a flow chart showing a construction method of the present invention, Figure 7 is an enlarged assembly process of Figure 5 The figure is shown. 8 is a front view of FIG. 7.

5 to 8, the construction process according to the present invention is installed S100 step of the steel frame pillar 10, S200 step of installing the floor slab formwork 70, and S300 to install the temporary steel column 50 Step, S400 step of assembling the shear reinforcing member 40, S500 step of assembling the bending stress resistance plate 400, S600 step of installing the tensile reinforcing bar 60, hollow body 30 installation and concrete S700 step of pouring.

Step S100 is a step of transferring the steel pillars 10 and shear reinforcement member 40 manufactured at the factory to the site. Here, the shear support 200 may be manufactured and transported integrally with the steel column 10 in a factory, or assembled by welding in the field.

Step S200 is a step of installing the floor slab formwork 70, which is a space where workers' working spaces and hollow bodies are installed.

Step S300 is a step of supporting the floor slab formwork 70 as a temporary steel column 50 so that the steel column 10 can withstand the load of the worker or other materials.

Step S400 is a step of installing the shear reinforcement member 40. The operator connects the guide line 610 to the reinforcement part 100 after the temporary steel frame 50 is installed, and draws both ends with the guide hook 620 fixed or installed on the steel frame 10. And the operator lowers the reinforcement part 100 by adjusting both ends of the guide line 610. At this time, the fitting plate 140 is adjusted in position so that the upper end of the shear support plate 210 is inserted between the guide end 142 extended to the outside.

For example, the worker connects the guide line 610 to the guide hole 161 of the leveling plate 160, and allows both ends of the guide line 610 to be drawn out to the guide hook 620. In addition, the worker pulls both ends of the guide line 610 drawn out through the guide hook 620, and the extension bar 110 is lowered in direction and speed so as to be fastened to the shear support part 200 fixed to the steel column 10. Adjust At this time, the extension bar 110 maintains the vertical state as the leveling plate 160 is lowered while maintaining the state in close contact with the pillar.

Therefore, the plurality of fitting plates 140 spaced apart from each other are lowered about one or more shear support plates 210 spaced apart from each other or positioned between the guide ends 142 so that the height determining unit 300 is cut out 211. It is lowered until it is caught or laid in the installation tool 212 exposed by the.

And the operator inserts a fixing portion (not shown) to communicate the hook hole 141 of the fitting plate 140 and the through hole 213 of the shear support plate 210 by shear support 200 and reinforcement 100 Fix each other.

Step S500 is a steel frame after the worker is positioned so that the bending stress resistance plate 400 over the upper support plate 120 and the upper flange 111 in a state in which the reinforcement part 100 and the shear support part 200 are mutually fastened A step of welding to the pillar 10 by welding.

The bending stress resistance plate 400 forms a load path that transmits the shear force due to the load of the slab 20 to the steel column 10 and simultaneously resists the bending stress of the slab 20 so that Prevents warping.

Step S600 is a step of connecting the tension bar to the welding coupler to prevent continuous collapse. That is, when the assembly process of the shear reinforcing member 40 as described above is completed, the upper tension reinforcing bar 61 and the lower tension bar 62 to the welding coupler 11 fixed to the outer surface of the steel column 10 Connect.

Step S700 is a step of sequentially installing the hollow body 30 on the upper surface of the bottom slab formwork 70, and pouring and curing concrete.

Therefore, the present invention can be fixed by using a fixing part (not shown) after pre-assembled a plurality of reinforcement part 100 horizontally extended to the shear support 200 is fixed to the steel column (10). The installation process of the shear reinforcement structure is very easy.

In addition, according to the present invention, since the reinforcement part 100 extending horizontally and the shear support part 200 fixed to the steel column 10 are assembled by the height determining part 300 and embedded in the slab, the slab ( It is possible to transmit the shear stress due to the gravity load applied to 20) and to support the minor moment of the slab generated around the steel column 10 so that the flat slab can be supported even without the beam.

In addition, the present invention is applicable to both the concrete-filled CFT column 10 and other steel frame column 10, it can be applied as various forms of embodiments. Such an embodiment of the present invention will be described with reference to FIGS. 10 and 11.

FIG. 10 is a view showing embodiments applied to a CFT column, and FIG. 11 is a view showing embodiments applied to a column not filled with concrete.

The present invention can be applied to the above-described shear reinforcement member 40 to the CFT column (see FIG. 10) filled with concrete and the steel frame column 10 (see FIG. 11) not filled with concrete. In this case, the present invention may apply only the stud 500 to the shear reinforcement member 40, or may add an elastic member 700 such as a spring or iron wire to the outside of the extension bar 110.

In addition, the steel column 10 may be applied to a square (square or other shape), a circular steel pipe, any one of H-shaped steel column or any other known steel column 10 as shown in FIG.

That is, both the steel pillars filled with concrete and the steel pillars not filled with concrete are applicable to the present invention, and are not limited to the shape of the steel pillars or the number of shear reinforcing members, and various applications are possible. For example, the square pillar may be provided with a pair of shear reinforcement members 40 spaced apart from each other on one surface, or only one shear reinforcement member 40 may be installed. Circular steel pipe columns may be provided with shear reinforcing members in four directions (front, rear, left and right), or may be provided as a plurality of radially.

Therefore, the present invention can be provided with a stud 500 to expand the area subjected to the shear force applied in the direction of gravity, to secure the integrity by using the elastic member 700 in the shear reinforcement member 40, the support force Can be reinforced.

For example, the elastic member 700 is welded to the outer surface of the column 10 or the shear support plate 210 as a wire or a spring after welding to extend the outer surface of the extension bar 110 in a spiral wrap. .

The elastic member 700 may be embedded in the slab 20 in which concrete is poured to ensure integrity, and reinforce a supporting force capable of supporting the load of the slab 20.

Embodiments of the present invention described above are merely exemplary, and those skilled in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom.

10: steel column 11: welding coupler
12: concrete 20: slab
30: hollow body 40: shear reinforcement member
50: temporary steel pillars 60: tensile steel
70: floor slab formwork 100: reinforcement
110: extension bar 111: upper flange
112: upright plate 113: lower flange
120: upper support plate 130: end plate
140: fitting plate 141: hook hole
142: guide 150: lower support plate
160: leveling plate 161: guide hole
200: shear support portion 210: shear support plate
211: incision 212: mounting hole
213: through hole 300: height determining unit
400: bending stress resistance plate 500: stud
610: guide line 620: guide hanger
700: elastic member

Claims (9)

Steel column (10);
A slab 20 joined to the steel column 10 to form a bottom plate;
A plurality of hollow bodies 30 embedded in the slab 20;
A shear reinforcement member 40 provided at the junction between the steel column 10 and the slab 20 to form a load path for transferring the shear force in the direction of gravity due to the slab 20 load to the steel column 10; Including,
Shear reinforcement member 40
Shear support 200 is fixed to the outer surface of the steel column (10);
A reinforcement part 100 formed to extend horizontally and fastened to the shear support part 200 by fitting;
When the reinforcing part 100 is fastened in the transverse direction at the front end of the reinforcing part 100, the reinforcing part 100 is caught by the shear supporting part 200 when the reinforcing part 100 is fitted to the shear supporting part 200 to determine the height or position of the reinforcing part 100 to be preassembled. Height determining unit 300; And
And a bending stress resistance plate 400 fixed to the upper surface of the reinforcement part 100 and the steel column 10 to resist the bending stress of the reinforcement part 100.
Reinforcement part 100
An extension bar 110 extending horizontally;
An end plate 130 which forms a cross section at the tip of the extension bar 110 and protrudes downwardly compared to the extension bar 110;
A plurality of fitting plates 140 fixed to be spaced apart from one surface of the end plate 130 so that the upper end of the shear supporting plate 210 can be retracted;
It extends horizontally from the upper surface of the end plate 130 and the fitting plate 140 to be welded to the end plate 130 at one end surface, and welded to the upper side of the fitting plate 140 at the lower surface side of the fitting plate 140 An upper support plate 120 which prevents the flow of the gas and simultaneously forms a load path for transmitting the shear force due to the load of the slab 20 to the steel column 10; And
On the opposite side of the downwardly protruding end plate 130 is extended and fixed between the lower surface of the extension bar 110 to form a path for transmitting the shear force applied to the extension bar 110 to the end plate 130, the extension bar ( A lower support plate 150 supporting the bending moment at the lower portion of the 110; At least one of,
The fitting plate 140
An induction hole 161 to which the induction line 610 is connected is formed to protrude from the tip of the fitting plate 140, and when the extension bar 110 is lowered by the induction line 610 of the steel pillar 10. Shear reinforcement structure of the concrete flat plate slab and steel pillars junction comprising a; leveling plate 160 for supporting the extension bar 110 to form a vertical state while being in close contact with the outer surface.
The method of claim 1, wherein the shear support 200
And one or more spaced apart shear support plates 210 fixed to the outer surface of the steel column 10;
Shear support plate 210
Concrete slab slab including; Hemispherical mounting holes 212, the upper end is cut to place the height determination unit 300 is placed, and through-holes 213 are arranged to be spaced apart from the lower portion of the mounting holes 212; Shear reinforcement structure of steel column connection.
delete delete The method according to claim 1, Extension bar 110 is
An upper plate 111 horizontally extending from the upper side, a lower flange 113 extending horizontally from the lower side, and an upstanding plate 112 erected between the upper flange 111 and the lower flange 113, Shear reinforcement structure of concrete flat plate slab and steel column connection.
delete The method according to claim 1, the reinforcement part 100
Shear reinforcement structure of the concrete flat plate slab and steel column joints, characterized in that the steel wire or spring is installed to wrap on the outer surface is embedded in the slab (20).
The method according to claim 1, the reinforcement part 100
Shear reinforcement structure of the concrete flat plate slab and steel column joint further comprising a plurality of studs (500) fixed to the extension bar (110).
The method according to claim 1, the fitting plate 140 is
Shear reinforcement structure of the concrete flat plate slab and steel pillars junction further comprises a; guide end (142) extending to slope outward from the bottom.

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