KR20090079561A - Shear reinforcement device in the slab-column connection - Google Patents

Abstract

A shear reinforcement for a slab-column joint is provided to manufacture in a simple structure by bending a reinforcing bar, and to make installation easy. A shear reinforcement(100) for a slab-column joint is installed to a slab-column joint in a flat plate structure to increase resistance to punching shear failure of a slab, and comprises a connection(110) having the appointed length and width, and a reinforcement member installed to the connection at a certain interval to reinforce shear resistance, wherein the reinforcement member comprises a shear reinforcement portion(120) having one side fixed to the connection and the other side extended to the upper part, and an upper anchorage portion(130) formed integrally with the shear reinforcement portion and bent toward one side from the shear reinforcement portion.

Description

Shear reinforcement of slab and column joint {SHEAR REINFORCEMENT DEVICE IN THE SLAB-COLUMN CONNECTION}

The present invention relates to a shear reinforcement, and more particularly, a simple structure by bending the reinforcement of the shear reinforcement used to increase the resistance to the punching shear failure of the slab installed in the slab and column joint in a flat plate structure The present invention relates to a shear reinforcement of a slab and a column joint which can be manufactured with ease of installation.

In general, in a flat plate structure that is directly supported on a column without a beam, such as a flat slab or a flat plate, stress is excessively concentrated in the slab and the column joint, whereby the slab around the column is inclined from the bottom to be inclined and further holes are drilled. Form shear failure is likely to occur. This type of shear is called punching shear, and this shear failure is very brittle and can be fatal to the safety of the structure, so the flat plate structure must be designed to be sufficiently resistant to punching shear. .

To improve the shear performance of slab-column joints in flat plate structure, (i) increase the thickness of the slab over the entire plate, and (ii) increase the thickness of the slab adjacent to the column by using a fingerboard (trough panel). The method of increasing the column size, the method of using column heads for the column, and the method of reinforcing the slab around the column as the shear reinforcement. have.

The methods of (i) to (iii) of the above methods are inferior in economics and constructability, and entail constraints in the design process for the height of the floor, and especially in the case of loads such as earthquakes, it guarantees the deformation capacity in the inelastic region beyond the elastic limit. Since there is a problem in that it is not possible, the method of installing a conventional shear reinforcement to the slab is the situation that is used in the most realistic way.

1 illustrates a conventional method for installing such shear reinforcement in a slab. As shown in the drawing, a method for installing a shear reinforcement to a slab according to the prior art, according to the shape of the shear reinforcement to be installed, the stub method (see Fig. 1a), stud rail method (see Fig. 1b), shear head method ( 1C), a truss method (see FIG. 1D), and the like.

The stub method of Figure 1a is a method of reinforcing the stub to exhibit the shear strength by winding the stirrup on the upper and lower reinforcement of the slab. This method has the advantage of economical because it is used by bending the reinforcing bar in the field without special hardware, while it is difficult to maintain the slab coating thickness because it must be wrapped around the slab upper and lower reinforcement, and it is difficult to bond when installing. .

The stud rail method of FIG. 1B is a method most commonly used in foreign countries, and a shear reinforcement method of welding a stud vertically to a narrow and long plate to exert shear strength, and by welding a round plate to a stud head part, improves fixability to be. This method is easy to install, but there is a cumbersome manufacturing process such as welding, and the head of the stud for fixing also has a problem that requires a special production different from the ready-made.

The shear head method of Figure 1c is a method of manufacturing a shear head reinforcement composed of structural steel, such as H-beams I-beams in a full penetration welding to install in a symmetrical form in the slab cross-section so that it is continuous in the column cross-section, this method Effective but expensive, difficult in the welding process and difficult to handle heavy.

The truss method of Figure 1d is a shear reinforcement method of combining the reinforcing bar or steel wire into a basic truss shape and installed toward the pillar, this method is complicated to make a truss type, the shear reinforcement between the upper and lower reinforcement of the slab Since it is installed in the bad fixability as well as having a separate binding means on the lower rebar of the slab, there is a problem that is not easy to install on-site.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is installed in the slab and the column junction in a flat plate structure, the shear reinforcement for increasing the resistance to punching shear failure of the slab The present invention provides a shear reinforcement of a slab and a column joint, which can be easily installed while being bent in a hook shape and fixed to a rail at fixed intervals, thereby making a simple structure.

Another object of the present invention is to be installed so that the shear reinforcement is placed between the upper and lower reinforcement of the slab reinforcement while extending over the lower reinforcement of the slab reinforcement, and can improve the adhesion to the slab concrete, ensuring the coating thickness of the slab as designed It is to provide a shear reinforcement of the slab and column joint.

Still another object of the present invention is to provide a shear reinforcement of a slab and column joint, which can be easily and simply installed without an on-site binding operation even after the slab reinforcement is not interfered with the slab reinforcement that is usually reinforcement.

The shear reinforcement of the slab and the column joint proposed by the present invention,

It is a shear reinforcement used to increase the resistance of the slab to punching shear failure by installing at the slab and column joint in flat plate structure, and it is fixed to maintain the gap between the connection part and the connection part to reinforce the shear strength. Including a reinforcing member,

The reinforcing member provides a shear reinforcement of the slab and the column joint consisting of a shear reinforcing portion one side end is fixed to the connecting portion and the other side is extended to the upper portion, and the upper fixing portion bent to one side while being integrally formed with the shear reinforcing portion. . The reinforcing member is made of rebar.

The shear reinforcement of the slab and the column joint according to the present invention is a structure in which the reinforcing bar bent into hooks is welded to the connection part of the slab reinforcement used to increase the resistance of the slab to punching shear failure in the flat plate structure. It does not need a special manufacturing process, such as the conventional studrail can be produced simply and easily.

In addition, since the shear reinforcement is used to reinforce the hooked reinforcement can be expected to improve the adhesion to the slab concrete, it can be constructed as a slab having a designed coating thickness. Furthermore, the shear reinforcement of the present invention can be easily installed without the on-site binding work even after the slab reinforcement is not interfered with the slab reinforcement is usually reinforcement.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail.

2a and 2b is a perspective view and a side view showing a shear reinforcement of the slab and the column joint according to the present invention, Figures 3a to 3d is a view for explaining a state in which the shear reinforcement of Figure 2 is installed in the slab and column joint. .

As shown, the shear reinforcement 100 of the slab and the column joint of the present invention is used to increase the resistance to punching shear failure of the slab by installing in the slab and the column junction in a flat plate structure, the present invention The shear reinforcement 100 of the connection portion 110 having a predetermined length and width, and a reinforcement member made to be fixed to maintain the spacing to the connection portion 110 to reinforce the shear strength.

The connecting portion 110 may be made of a metal plate having a predetermined strength, and the reinforcing member fixed thereto has a structure in which one side end is fixed to the connecting portion 110 by welding or the like by bending one side of the rebar.

The reinforcing member is bent at a predetermined angle (A) to one side of the rebar having a predetermined length in the form of a hook and the bent rebar is fixed to the connecting portion 110 by welding or the like.

The reinforcing member provided in the present invention is one end is fixed to the connecting portion 110 and the other side is a shear reinforcement portion 120 and the shear reinforcement portion 120 is formed integrally with the shear reinforcement portion 120 from the upper side from the shear reinforcement portion 120 The upper fixing part 130 is bent to one side.

The bent angle A of the upper fixing part 130 is bent at an angle where the upper fixing part 130 may be formed in a hook shape. The bent angle of the upper fixing part 130 is preferably maintained at an angle of 90 degrees to 135 degrees. This is because the shear reinforcement 100 is installed between the upper and lower reinforcing bars of the slab, when the bent angle of the upper fixing part 130 is bent at 90 degrees or less or 135 degrees or more, the fixability is bad as well as the upper and lower rebars. When fastening, separate fastening means should be used.

These reinforcing members maintain a predetermined interval and a plurality of fixed to the connection portion 110 is installed.

The diameter of the reinforcing bar applied to the reinforcing member constituting the shear reinforcement 100 is about D13 ~ D19 easy to bend, and the spacing between the shear reinforcement portion 120 does not exceed the slab spacing spacing Bending rebar about 60 ~ 100mm is used.

In the embodiment of Figure 2, the interval between the upper fixing portion 130 is 80mm, the diameter of the reinforcing bar is used D16 and the connecting plate 110 is a shear reinforcement applying a width of 50mm to 9mm.

The upper fixing part 130 is located at the upper part of the shear reinforcement 100 and is positioned at the same level as the upper reinforcing bars R1 across the upper slab upper bars R1 at the upper part of the slab. That is, when the upper reinforcement (R1) of the slab is reinforcement in one direction, the upper fixing portion 130 is placed on the slab upper reinforcement (R1) to be located at the same level, the upper reinforcement (R1) of the slab is reinforced in two directions If the upper fixing part 130 is fixed to the reinforcing bar in the lower of the two-way reinforcement, the upper fixing part 130 is to be located at the same level as the reinforcing bar in the upper direction of the two-way reinforcement. However, the shear reinforcing body 100 of the present invention is not a problem in ensuring the coating thickness of the designed slab because the upper fixing portion 130 is installed at the same position across the upper reinforcing bar (R1) of the slab.

The length of the upper fixing part 130 is determined in consideration of the reinforcement spacing of the slab, and most preferably selected in an increment of 15 mm in consideration of the reinforcement spacing within the range of 60 ~ 100mm.

Shear reinforcement portion 120 is a portion extending downward from the upper fixing portion 130, the shear force is disposed vertically or inclined with the upper and lower reinforcement (R1) (R2) of the slab acting on the junction of the slab and the column It is resistant to. When the upper fixing part 130 is fixed to the upper reinforcing bar R1 of the slab, the shear reinforcing part 120 is supported between the upper and lower reinforcing bars R1 and R2 of the slab by the support of the fixed upper fixing part 130. It is located in the stable to perform the role.

The shear reinforcing portion 120 is formed to be secured to the length that is arranged to the lower reinforcing bar (R2) of the slab can fully exhibit the role.

The connection portion 110 is a portion connecting the lower ends of the shear reinforcement portion 120 adjacent to each other. When the upper fixing part 130 is fixed to the upper reinforcing bar R1 of the slab, the connection unit 110 is located close to the lower reinforcing bar R2 of the slab. As a result, the lower reinforcing bar R2 of the slab is reinforced. It also serves as a tension member for the slab.

As described above, the installation process in the flat plate structure of the shear reinforcement 100 of the present invention including the upper fixing part 130, the shear reinforcing part 120 and the connecting part 110 is described with reference to FIGS. 3A to 3D. The explanation is as follows.

1.reinforcement

After the formwork is installed, the upper and lower reinforcing bars (R1) (R2) are placed on top of the slab. Since the slab upper and lower reinforcement (R1) (R2) reinforces in a conventional manner prior to the installation of the shear reinforcement (100) to be installed later, it is possible to easily perform the reinforcement work without interference of the shear reinforcement (100) Will be.

2. Shear reinforcement installation

The shear reinforcement 100 of the present invention is prepared and installed in the slab and the column joint, the upper fixing portion 130 is located between the upper reinforcing bar (R1) of the slab, the shear reinforcing portion 120 is the top of the slab , Install to be located between the lower reinforcement (R1) (R2). That is, the lower reinforcement (R2) of the slab is installed in the reinforcement state, the upper fixing portion 130 intersects with the upper slab upper reinforcement (R1) so that the lower connection portion 10 is located in the space between the upper slab upper reinforcement (R1) When the shear reinforcing body 100 of the present invention is disposed on the slab lower reinforcing bar (R2) and then the upper reinforcing bar (R1) is disposed, the upper fixing part 130 is fixed while being spread over the upper reinforcing bar R1 of the slab. The shear reinforcing part 120 is positioned between the upper and lower reinforcing bars R1 and R2 of the slab, and the lower connecting part 110 is located near the lower reinforcing bar R2 of the slab.

In this case, the shear reinforcement 100 may be installed side by side in a plurality of rows on each side of the column, and the number and installation directions of the shear reinforcement 100 may be different according to buildings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a plan view of a shear reinforcement in plan and side view for explaining a method for installing a shear reinforcement in a slab according to the prior art;

Figure 2a is a perspective view showing a shear reinforcement of the slab and column joint according to the present invention.

FIG. 2B is a side view of a portion of FIG. 2A; FIG.

Figure 3a is a view for explaining a state in which the shear reinforcement of the present invention is installed in the slab and the column joint, a perspective view of the upper reinforcing bar lifted up.

3B is a view for explaining a state in which the shear reinforcement body of the present invention is installed in the slab and the column joint portion, a plan view as seen from the state in which the lower reinforcing bar is removed.

Figure 3c is a view for explaining the state in which the shear reinforcement of the present invention is installed in the slab and the column joint, an enlarged perspective view as seen from the state removing the upper reinforcing bar.

Figure 3d is a view for explaining a state in which the shear reinforcement of the present invention is installed in the slab and the column joint portion, an enlarged perspective view of a state in which a part of the shear reinforcement of the present invention is cut.

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

100: shear reinforcement 110: connection portion

120: shear reinforcing portion 130: upper fixing portion

R1: Slab upper bar R2: Slab lower bar

Claims (3)

It is a shear reinforcement used to increase the resistance of the slab to punching shear failure by installing at the slab and column joint in flat plate structure, and it is fixed to maintain the gap between the connection part and the connection part to reinforce the shear strength. Including a reinforcing member, The reinforcing member is a shear reinforcement of the slab and the column junction consisting of a shear reinforcing portion one side end is fixed to the connecting portion and the other side is extended to the top, and the upper fixing portion bent to one side while being integral with the shear reinforcing portion. The method according to claim 1, Shear reinforcement of the slab and the column junction, characterized in that the bent angle of the upper fixing portion is between 90 degrees to 135 degrees. The method according to claim 2, Shear reinforcement of the slab and the column junction characterized in that the upper fixing portion is fixed while spanning the upper reinforcing bar.

Images