KR102422489B1 - Shear reinforcing method of concrete structure using engineering plastics angle and tensile force of steel pipe - Google Patents

Abstract

The present invention is a dry method of mechanically closely assembling, and shear reinforcement is made to reduce the work step and fatigue caused by the worker, and even unskilled people can work easily, thereby guaranteeing the reliability of the work. A shear reinforcement method for concrete structures using engineering plastic angles and tensile force of steel rods to be increased is provided.
The shear reinforcement method of the concrete structure using the tensile force of the engineering plastic angle and the steel bar according to an appropriate embodiment of the present invention is an engineering plastic angle that is positioned close to the edge of the RC column for reinforcement of shear performance, and the outer edge of the engineering plastic angle Attaching a square tube-coupled angle unit consisting of a square tube for fastening steel rods installed in a pair to a steel rod end-joining hole at regular intervals to the corner of the RC column using a resin adhesive; A steel bar having a length corresponding to the width of the cross-section of the RC column and having a male threaded part formed at the end is provided, and both ends of the steel bar are inserted through the end coupling holes of the steel bars for fastening the steel bars on the side of the corner unit side of the square pipe coupling type opposite to each other a step of placing it; It is characterized in that it is constructed including; the step of introducing a tensile force to the steel bar by fastening and tightening the respective fastening nuts to the male threaded parts on both ends of the steel bar.

Description

Shear reinforcing method of concrete structure using engineering plastics angle and tensile force of steel pipe

The present invention relates to a shear reinforcement method of a concrete structure, and in particular, shear reinforcement is achieved by a dry method of mechanically closely assembling, so that the operation stage and fatigue caused by the operation are reduced, and even an unskilled person can work easily, thereby guaranteeing the reliability of the operation It relates to a shear reinforcement method of a concrete structure using the tensile force of an engineering plastic angle and a steel bar to increase the sectional strength by sharing the shear force.

The conventional method for improving the seismic performance of pillars in a piloti building is largely divided into two methods: the conventional method and the use of other steel frames and damping devices. Existing conventional methods include section extension, aramid and carbon fiber reinforcement, and steel plate reinforcement. This conventional construction method has a problem in that the construction method is wet construction (reinforced concrete pouring, etc.), and the number of processes is increased and the construction method is complicated.

For example, the steel sheet bonding method is difficult to construct, has problems with corrosion and fire resistance performance, and because anchor bolts are used, the aesthetics is not good in the case of an exposed finish. There are disadvantages. Since the carbon fiber reinforcement method is a method of attaching a wallpaper-shaped carbon fiber sheet to the surface of a multi-layered column, the worker's work step and fatigue are increased. , there is a disadvantage that, if sufficient adhesion is not made, foreign substances and moisture are injected into the adhesion surface, so that the reinforcement effect does not appear at all. Therefore, there is a need for a method that does not require the skill of a worker and can simply and easily construct shear reinforcement only by attaching and assembling.

In the case of other security methods using steel frame reinforcement and damping devices, the on-site work process and time were reduced due to factory production, but there were still difficulties in installing the steel frame reinforcement and damping devices on site. not good either There is also a problem that the construction cost is high compared to the conventional construction method.

As the background technology of the present invention, Korean Patent Registration No. 10-2134400, 'a device and method for reinforcing pillars of a piloti building is known. This is a simple reinforcement device and reinforcement method that wraps around the perimeter of an existing column using a coupler having a thread. However, this background technology has a disadvantage in that the operator's convenience in construction is lowered because the guidelines for each member are not clear.

Another technology that is the background of the present invention is Korean Patent Laid-Open Publication No. 10-2020-0008685, which proposes a 'concrete column seismic reinforcement method'. This has the steps of installing a corner support of the length of the reinforcement section in the corner of the concrete column, installing a steel material in the through hole of the corner support, and confirming the target fastening torque value after the first fastening of the fastening member. The background art is to prevent the concentration of external forces on the corners of the concrete pillars, but cannot prevent seismic destruction or damage occurring in the central portion of the pillars. In addition, when the fastening member is fastened, it cannot have a uniform fastening axial force, so professional construction technology is required.

Korean Patent Registration No. 10-2134400 Korean Patent Publication No. 10-2020-0008685

The present invention is a dry method of mechanically closely assembling, and shear reinforcement is made to reduce the work step and fatigue caused by the worker, and even unskilled people can work easily, thereby guaranteeing the reliability of the work. An object of the present invention is to provide a shear reinforcement method of a concrete structure using the tensile force of the engineering plastic angle and steel bar to be increased.

The shear reinforcement method of a concrete structure using the tensile force of an engineering plastic angle and a steel bar according to an appropriate embodiment of the present invention,
The shear reinforcement method of the concrete structure using the tensile force of the engineering plastic angle and the steel bar according to an appropriate embodiment of the present invention is an engineering plastic angle that is positioned close to the edge of the RC column for reinforcement of shear performance, and the outer edge of the engineering plastic angle Attaching a square tube-coupled angle unit consisting of a square tube for fastening steel rods installed in a pair to a steel rod end-joining hole at regular intervals to the corner of the RC column using a resin adhesive; A steel bar having a length corresponding to the width of the cross-section of the RC column and having a male threaded part formed at the end is provided, and both ends of the steel bar are inserted through the end coupling holes of the steel bars for fastening the steel bars on the side of the corner unit side of the square pipe coupling type opposite to each other a step of placing it; introducing a tensile force to the steel bar by fastening and tightening the respective fastening nuts to the male threaded portions on both ends of the steel bar; Installing an engineering plastic angle support plate having a steel bar coupling groove on one surface to which the steel bar is coupled and disposed between the engineering plastic angle and the steel bar to increase the area of shear reinforcement and induce smooth stress flow; It is installed to have a certain distance between adjacent engineering plastic angles, but in order to share the shear force of the RC column, the engineering plastic angle support plate is installed with a certain overlapping section with the engineering plastic angle at both ends.

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According to the shear reinforcement method of the concrete structure using the tensile force of the engineering plastic angle and the steel bar of the present invention, the steel bar is fastened to the square tube-coupled angle unit attached to the concrete structure, and the tensile force generated in the steel bar is used to resist the shear force. Shear reinforcement is made by a dry method of mechanically closely assembling the Therefore, compared to the wet method using FRP, the operation stage and fatigue caused by the operator are reduced.

In addition, the steel bar is installed in the correct position by using the guide of the steel bar end coupling hole formed in the square pipe for fastening the steel bar, so that even non-skilled persons can easily and accurately assemble, thereby ensuring the reliability of the shear reinforcement work. .

In addition, by sharing the shear force through the steel bar and the engineering plastic angle support plate supported by the steel bar, it can have the effect of strengthening the cross-sectional strength.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a perspective view in which shear reinforcement is made in a concrete structure using an engineering plastic angle and tensile force of a steel bar according to the present invention.
Fig. 2 is a front view of Fig. 1;
Fig. 3 is a plan view of Fig. 2;
4 (A), (B), (C) are perspective views of a square tube coupling type angle unit, an engineering plastic angle support plate, and a steel bar respectively applied to the present invention.
Figure 5 is a construction flow chart for shear reinforcement in the concrete structure using the tensile force of the engineering plastic angle and steel bar according to the present invention.
Figure 6 is a perspective view in which shear reinforcement is made in the concrete structure by omitting the engineering plastic angle support plate applied to the present invention.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

According to the shear reinforcement method of the concrete structure of the present invention, as shown in FIGS. 1 to 3, the square tube-coupled angle unit 12, the square tube-coupled angle unit 12 respectively attached to the four corners of the RC column 100. After being connected at regular intervals, the steel bar 14, which is fastened to the fastening nut 16 and applied with a tensile force, is disposed between the square tube-coupled angle unit 12 and the steel bar 14 to support the square tube-coupled angle unit 12. It has a structure in which the engineering plastic angle support plate 18 is installed.

Here, the engineering plastic angle support plate 18 is attached to the engineering plastic angle 121 at regular intervals in the longitudinal direction to share the shear stress. As shown in FIG. 4, the square tube coupling type angle unit 12 is provided as a pair at the outer edge of the L-shaped engineering plastic angle 121 and the engineering plastic angle 121, and includes a steel bar end coupling hole 122a at regular intervals. It is made of a square tube 122 for fastening the steel bar having. The square pipe 122 for fastening the steel bar may be manufactured integrally with the engineering plastic angle 121 or may be separately manufactured and installed.

As an example of a concrete structure having such a shear reinforcement structure, the RC column 100 secures shear performance according to the high-strength physical properties of the engineering plastic angle 121 .

In addition, the steel bar 14 is installed to have a tensile force to further increase the binding force of the four sides of the RC column 100 through the engineering plastic angle 121 to maximize shear reinforcement.

In addition, the engineering plastic angle support plate 18 increases the shear reinforcement area while fixing the steel bar 14, and increases the shear reinforcement efficiency by smoothing the distribution and flow of shear stress. At this time, in order to share the shear force of the RC pillar 100, the engineering plastic angle support plate 18 is preferably installed with the engineering plastic angle 121 and a certain overlapping section (S) at both ends as shown in FIG. 3 .

As an example of a concrete structure for having such a shear reinforcement structure, the construction method of the RC column 100 will be sequentially described.

First, for the reinforcement of the shear performance of the RC pillar 100 shown in Fig. 5 (A), as shown in Fig. 5 (B), an engineering plastic angle 121 to be placed in close contact with the edge of the RC pillar 100, and, Installed in a pair on the outer edge of the engineering plastic angle 121, each pipe coupling type angle unit 12 consisting of a square pipe 122 for fastening steel bars having a steel bar end coupling hole 122a at regular intervals is applied with a resin adhesive (e.g., epoxy Adhesive) is used to attach to each corner of the RC pillar 100 .

At this time, it may be installed to have a certain gap G between the adjacent engineering plastic angles 121 and 121 . By leaving this gap (G), it is possible to reduce the cross-sectional width of the engineering plastic angle 121 to reduce the manufacturing cost of the square tube coupling type angle unit 12.

Then, as shown in FIG. 5 (c), it has a steel bar coupling groove 181 to which the steel bar 14 is coupled on one surface and is disposed between the engineering plastic angle 121 and the steel bar 14 to increase the area of shear reinforcement and An engineering plastic angle support plate 18 that induces a smooth stress flow is installed.

The engineering plastic angle support plate 18 may be attached to the engineering plastic angle 121 via an epoxy adhesive. The engineering plastic angle support plate 18 guides the installation position of the steel bar 14 to the steel bar coupling groove 181 . Therefore, it is possible to quickly install the steel bar 14 .

Next, the steel bar 14 shown in (c) of FIG. 4 having a length corresponding to the width of the cross-section of the RC column 100 as shown in FIG. and inserting both ends of the steel bar 14 into the opposite side square tube coupling type corner units 12 and 12 side steel bar fastening square pipes 122 and 122 through the steel bar end coupling holes 122a, respectively. put

At this time, the steel bar 14 is coupled to the steel bar coupling groove 181 of the engineering plastic angle support plate 18 to quickly secure the installation position.

Next, by fastening the fastening nuts 16 to the male threaded portions 141 at both ends of the steel bar 14 , a tensile force is generated on the steel bar 14 .

As described above, according to the shear reinforcement method of the concrete structure using the engineering plastic angle and the tensile force of the steel bar of the present invention, the dry method of mechanically closely assembling the worker's work step and the fatigue thereof are reduced, and even unskilled persons can work easily. The reliability of work can be guaranteed.

Meanwhile, the present invention may be constructed as shown in FIG. 6 by omitting the installation process of the engineering plastic angle support plate 18 . In this case, while the shear reinforcement is lower than that of FIG. 1 , the construction cost is reduced and the installation step of the operator can be reduced.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

12: Square tube-coupled angle unit
121: engineering plastic angle
122: square pipe for fastening steel bar
14: steel bar
18: engineering plastic angle support plate

Claims (4)

An engineering plastic angle 121 that is positioned close to the edge of the RC pillar 100 for shear performance reinforcement, and a pair of engineering plastic angles 121 installed at the outer edge of the steel bar end coupling hole 122a at regular intervals Attaching the square tube-coupled angle unit 12 made of a square tube for fastening steel rods 122 with a resin adhesive to the corner of the RC column 100;
The RC column 100 has a length corresponding to the width of the cross-section and has a steel bar 14 having a male threaded portion 141 formed at an end thereof, and both ends of the steel bar 14 are opposed to each other. (12) (12) side for fastening the steel rods 122, 122, respectively, the step of inserting through the steel rod end coupling hole (122a);
introducing a tensile force to the steel bar 14 by fastening and tightening the respective fastening nuts 16 to the male threaded portions 141 on both ends of the steel bar 14;
An engineering plastic angle support plate ( 18) installing;
It is installed to have a certain gap (G) between the adjacent engineering plastic angles 121 and 121, but in order to share the shear force of the RC column 100, the engineering plastic angle support plate 18 is an engineering plastic angle 121 at both ends. A shear reinforcement method of a concrete structure using the tensile force of an engineering plastic angle and a steel bar, characterized in that it is installed with a certain overlapping section (S) and a certain overlapping section (S). delete delete delete

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