KR102238294B1 - the high performance Hybrid beam structure for seismic reinforcing and construction method thereof - Google Patents

Abstract

According to the present invention, provided is a high-performance hybrid beam structure for seismic reinforcement. The structure includes: a lower plate (100) installed in a lower part of a beam (10) of a building; a side plate (200) installed on a side of the beam (10), while having a lower part or bottom combined with the lower plate (100); and a floor plate (300) installed in a lower part of the lower plate (200), while combined with the bottom of the side plate (200). Moreover, provided is a construction method for a high-performance hybrid beam structure for seismic reinforcement. The method includes: a lower plate installation step (1) of combining the lower plate (100) with a lower part of the beam (10); a side plate installation step (2) of combining the lower plate (100) with the beam (10) and the lower plate (100); a floor plate installation step (3) of combining the floor plate (300) with the bottom of the side plate (200); and a mortar filling step (4) of filling an internal space surrounded by the lower plate (100), the lower plate (100) and the floor plate (300), with mortar (M). Therefore, the present invention is capable of economically securing seismic performance.

Description

{The high performance Hybrid beam structure for seismic reinforcing and construction method thereof}

The present invention is a high-performance hybrid beam structure for seismic reinforcement that can economically secure seismic performance by simply constructing a beam without significantly changing the structure of an existing building with a simple member and a simple construction method in response to the recent seismic reinforcement issue. And its construction method.

Recently, social demand for remodeling is increasing due to the aging of buildings.

When remodeling, it is necessary to solve the additional load that occurs due to weakening and expansion of structural performance due to the demolition of existing structural members, and a reinforcement method with improved seismic performance must be applied as the frequency of earthquakes in Korea increases.

Conventionally, a method of attaching a steel plate to an existing member or extending the cross section of a member, and a method of wrapping and reinforcing a fiber composite material such as FRP have been mainly used.

In the case of the method of reinforcing a member by wrapping a steel plate or a fiber composite material, problems such as deterioration and dropping of the external adhesive material occur over time.

In the case of the section extension method, there is a problem that the construction period is long due to the large number of on-site work and stress is concentrated in the joint.

Accordingly, the present inventor can reinforce the lower part of the beam through the lower plate, thereby improving the tensile strength, and the high-performance hybrid beam structure for seismic reinforcement of the present invention that contributes to the improvement of shear performance by reinforcing the side of the beam through the side plate. And to develop a construction method thereof.

In addition, in the present invention, unlike the conventional technology, the seismic reinforcing material is composed of a bottom, side, and bottom plate instead of an integrated shape, so that the size and shape of the beam are not limited, so that the ratio of prefab produced in the factory can be increased.

The seismic stiffener reinforced on the side and bottom of the beam in this way can effectively reduce the ratio of work on the site because there is no need to readjust the detailed dimensions at the site even if the member sizes measured in the form that each stiffener is assembled with bolts and anchors are different. ,

It is easy to assemble and construct and can improve the precision of construction.

In the present invention, a perforated stiffener is installed on the floor plate to serve as a tensile stiffener, and since it is disposed with a certain height in the longitudinal direction of the beam, it contributes to the improvement of shearing performance.

Accordingly, after installing the seismic reinforcement, the subsequent process of installing the tensile reinforcement and shear reinforcement inside is not required, so the construction is simple.

[Document 1] Korean Patent Registration No. 10-1186267'Hybrid Synthetic Beam', 2012.09.20 [Document 2] Republic of Korea Patent Registration No. 10-1991638'Steel composite beam in which a section steel is disposed on a pair of H-beams', 2019.06.14

The present invention is presented in order to solve all the problems of the prior art as described above. Its purpose is to provide a high-performance hybrid beam structure for seismic reinforcement and its construction method that can secure seismic performance economically by simply constructing the beam without significantly changing the structure of the existing building with a simple member and a simple construction method.

In order to solve the above technical problem, the present invention includes a lower plate 100 installed under the beam 10 of a building;

A side plate 200 installed on the side of the beam 10 and having a lower or lower end coupled to the lower plate 200 to be installed;

A floor plate 300 installed under the lower plate 200 and coupled to a lower end of the side plate 200 to be installed;

It provides a high-performance hybrid beam structure for seismic reinforcement, characterized in that configured to include.

In addition, to construct the high-performance hybrid beam structure for seismic reinforcement,

(1) a lower plate installation step of coupling and installing the lower plate 100 under the beam 10;

(2) a side plate installation step of coupling and installing the lower plate 100 to the beam 10 and the lower plate 100;

(3) a floor plate installation step of coupling and installing the floor plate 300 to the bottom of the side plate 200;

(4) a mortar filling step of filling a mortar (M) in the inner space surrounded by the lower plate 100, the lower plate 100, and the floor plate 300;

It provides a construction method of a high-performance hybrid beam structure for seismic reinforcement, characterized in that configured to include.

First, according to the present invention, there is provided a high-performance hybrid beam structure for seismic reinforcement and a construction method thereof that can secure seismic performance economically by simply constructing the beam without significantly changing the structure of an existing building with a simple member and a simple construction method. .

Second, in the present invention, the lower part of the beam can be reinforced through the lower plate, so that tensile strength can be improved, and the side of the beam can be reinforced through the side plate, thereby contributing to the improvement of shear performance.

Third, according to the present invention, unlike the prior art, the seismic reinforcing material is composed of a bottom, side, and bottom plate rather than an integrated shape, so that the size and shape of the beam are not limited, so that the proportion of prefab produced in the factory can be increased.

Fourth, according to the present invention, the seismic stiffener reinforced on the side and bottom of the beam effectively reduces the ratio of work in the field, as there is no need to readjust the detailed dimensions in the field even if the size of the members measured in the form that each reinforcement is assembled with bolts and anchors are different. It can be reduced, and assembly and construction are easy, and the precision of construction can be improved.

Fifth, in the present invention, since the perforated reinforcement is installed on the floor plate to serve as a tensile reinforcement and is arranged to have a certain height in the longitudinal direction of the beam, it contributes to the improvement of shear performance. Accordingly, after installing the seismic reinforcement, the subsequent process of installing the tensile reinforcement and shear reinforcement inside is not required, so the construction is simple.

1 is a perspective view of a combination of a high-performance hybrid beam structure for seismic reinforcement of the present invention.
2 is a perspective view of a lower plate in the high-performance hybrid beam structure for seismic reinforcement of the present invention.
3 is a perspective view of a side plate in the high-performance hybrid beam structure for seismic reinforcement of the present invention.
Figure 4 is a perspective view of a floor plate in the high-performance hybrid beam structure for seismic reinforcement of the present invention.
5 to 7 are sequentially showing the installation scene of the lower plate in the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.
8 to 10 are sequentially showing the installation scene of the side plate in the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.
11 to 13 are sequentially showing the installation scenes of the floor plate in the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.
14 is a view showing a filling scene of mortar in the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.

Hereinafter, the present invention will be described in more detail through embodiments in which the concept of the present invention as described above is preferably implemented together with the accompanying drawings.

Ⅰ. High-performance hybrid beam structure for seismic reinforcement

1 is a perspective view of a combination of a high-performance hybrid beam structure for seismic reinforcement of the present invention.

The high-performance hybrid beam structure for seismic reinforcement of the present invention,

A lower plate 100 installed under the beam 10 of the building;

A side plate 200 installed on the side of the beam 10 and having a lower or lower end coupled to the lower plate 200 to be installed;

A floor plate 300 installed under the lower plate 200 and coupled to a lower end of the side plate 200 to be installed;

It characterized in that it is configured to include.

2 is a perspective view of a lower plate in the high-performance hybrid beam structure for seismic reinforcement of the present invention.

The lower plate 100 is shaped like a bent plate,

Upper surface 110; And,

A vertical surface 130 bent at an end of the upper surface 110;

Consisting of including,

The upper surface 110 is installed coupled to the lower portion of the beam 10,

It characterized in that the vertical surface 130 is installed in conjunction with the side plate 200.

3 is a perspective view of a side plate in the high-performance hybrid beam structure for seismic reinforcement of the present invention.

The side plate 200 is a b-shaped plate material is bent,

Vertical member 210;

A horizontal member 230 bent at the bottom of the vertical member 210;

Consisting of including,

The vertical member 210 is characterized in that it is installed coupled to the side surface of the beam 10 and the vertical surface 130.

In addition, a slit 231 is formed in the horizontal member 230 so that the reinforcing member 310 of the floor plate 300 penetrates from the bottom and protrudes upward from the horizontal member 230 in the slit 231.

Figure 4 is a perspective view of a floor plate in the high-performance hybrid beam structure for seismic reinforcement of the present invention.

The floor plate 300,

It characterized in that it is installed coupled to the horizontal member (230).

A reinforcing material 310 protruding vertically is integrally manufactured on the top of the floor plate 300,

The reinforcing material 310 has a through hole 311 as shown in FIG. 4, and the mortar M is filled into the through hole 311 so that the mortar M on both sides of the reinforcing material 310 is integrally operated. .

And as shown in Figure 14,

The present invention is characterized in that a mortar (M) is filled in an inner space surrounded by the upper surface 110, the vertical surface 130, the horizontal member 230, and the floor plate 300.

Ⅱ. Construction method of high-performance hybrid beam structure for seismic reinforcement

5 to 14 are sequentially showing the construction process of the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.

The construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention,

To construct the high-performance hybrid beam structure for seismic reinforcement,

(1) a lower plate installation step of coupling and installing the lower plate 100 under the beam 10;

(2) a side plate installation step of coupling and installing the lower plate 100 to the beam 10 and the lower plate 100;

(3) a floor plate installation step of coupling and installing the floor plate 300 to the bottom of the side plate 200;

(4) a mortar filling step of filling a mortar (M) in the inner space surrounded by the lower plate 100, the lower plate 100, and the floor plate 300;

It characterized in that it is configured to include.

And another first embodiment of the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention,

To construct the high-performance hybrid beam structure for seismic reinforcement,

(1) a lower plate installation step of coupling and installing the upper surface 110 to the lower portion of the beam 10;

(2) a side plate first installation step of coupling and installing the vertical member 210 to the side of the beam 10;

(3) a side plate second installation step of coupling and installing the vertical member 210 to the vertical surface 130;

(4) a floor plate installation step of coupling and installing the floor plate 300 to the horizontal member 230;

(5) a mortar filling step of filling the mortar (M) in an inner space surrounded by the upper surface 110, the vertical surface 130, the horizontal member 230, and the floor plate 300;

It characterized in that it is configured to include.

In addition, another second embodiment of the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention,

To construct the high-performance hybrid beam structure for seismic reinforcement,

(1) a lower plate installation step of coupling and installing the upper surface 110 to the lower portion of the beam 10;

(2) a side plate first installation step of coupling and installing the vertical member 210 to the vertical surface 130;

(3) a side plate second installation step of coupling and installing the vertical member 210 to the side of the beam 10;

(4) a floor plate installation step of coupling and installing the floor plate 300 to the horizontal member 230;

(5) a mortar filling step of filling the mortar (M) in an inner space surrounded by the upper surface 110, the vertical surface 130, the horizontal member 230, and the floor plate 300;

It characterized in that it is configured to include.

Unlike the first embodiment, the second embodiment,

The order of the (2) side plate first installation step and (3) the side plate second installation step of the first embodiment has been changed.

5 to 7 are sequentially showing the installation scene of the lower plate in the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.

The (1) lower plate installation step;

As a step of coupling and installing the upper surface 110 to the lower portion of the beam 10,

After attaching the upper surface 110 to the lower portion of the beam 10 as shown in FIG. 5,

As shown in Fig. 6, the concrete under the beam 10 is drilled and a chemical anchor is installed.

Subsequently, as shown in FIG. 7, the upper surface 110 is coupled to the lower portion of the beam 10 by fastening a nut to the chemical anchor.

8 to 10 are sequentially showing the installation scene of the side plate in the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.

The (2) side plate first installation step,

As the step of installing and coupling the vertical member 210 to the vertical surface 130,

As shown in FIG. 8, the lower side of the vertical member 210 of the lower plate 200 and the vertical surface 130 of the lower plate 100 are coupled and installed using bolts and nuts.

The (3) side plate second installation step,

As the step of installing and coupling the vertical member 210 to the side of the beam 10,

As shown in Fig. 9, concrete is drilled on the side of the beam 10 and a chemical anchor is installed.

Subsequently, as shown in FIG. 10, by fastening a nut to the chemical anchor, the vertical member 210 is coupled to the side surface of the beam 10.

11 to 13 are sequentially showing the installation scenes of the floor plate in the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.

The (4) floor plate installation step,

As the step of installing and coupling the floor plate 300 to the horizontal member 230,

As shown in FIG. 11, the floor plate 300 is in close contact with the horizontal member 230, but the reinforcing member 310 of the floor plate 300 is formed in the horizontal member 230 with the slit 231 shown in FIG. After installing so as to penetrate and protrude above the horizontal member 230,

Fastening a bolt between the floor plate 300 and the horizontal member 230 as shown in Figure 12,

13, the bottom plate 300 and the horizontal member 230 are coupled by fastening a nut to the bolt.

14 is a view showing a filling scene of mortar in the construction method of the high-performance hybrid beam structure for seismic reinforcement of the present invention.

The (5) mortar filling step,

Filling the mortar (M) in the inner space surrounded by the upper surface 110, the vertical surface 130, the horizontal member 230 and the floor plate 300 as shown in FIG. 14,

At this time, the reinforcing material 310 is combined with the mortar M to behave integrally.

In addition, the reinforcing material 310 is formed with a through hole 311 as shown in FIG. 4, and the mortar M is filled into the through hole 311 to integrally move the mortar M on both sides of the reinforcing material 310 Let's do it.

The summary of the present invention is as follows.

Currently, for seismic reinforcement to existing beams, there is a disadvantage in that it undergoes a cumbersome process of making orders at the factory according to the size and shape of the beam, and re-adjusting detailed dimensions at the site.

As the present invention can be applied to the existing beam,

The integrated behavior is possible by combining the seismic stiffener to the existing beam through a chemical anchor and injecting mortar into the joint.

The seismic stiffener is composed of a lower plate, a side plate, and a floor plate.

First, place the lower plate on the existing beam and drill the concrete to construct a chemical anchor.

After placing the side plate on the side of the beam, bolt the lower plate and the side plate to fix the position, and then drill the concrete on the side of the beam to connect the side plate and the chemical anchor.

Finally, after placing the floor plate, fix it by bolting it to the lower end of the lower plate.

The floor plate is in the form of a perforated reinforcement with through-holes that serve as tension and shear reinforcement.

After installing the seismic stiffener, a separate subsequent process of placing the tensile reinforcement inside is not required, and since it is arranged with a certain height in the longitudinal direction of the beam, it contributes to the improvement of shear performance.

And the effects of the present invention are as follows.

First, according to the present invention, there is provided a high-performance hybrid beam structure for seismic reinforcement and a construction method thereof that can secure seismic performance economically by simply constructing the beam without significantly changing the structure of an existing building with a simple member and a simple construction method. .

Second, in the present invention, the lower part of the beam can be reinforced through the lower plate, so that tensile strength can be improved, and the side of the beam can be reinforced through the side plate, thereby contributing to the improvement of shear performance.

Third, according to the present invention, unlike the conventional technology, the seismic reinforcing material is composed of a bottom, side, and bottom plate instead of an integrated shape, so that there is no restriction on the size and shape of the beam, so that the ratio of the prefab produced in the factory can be increased.

Fourth, according to the present invention, the seismic stiffener reinforced on the side and bottom of the beam effectively reduces the ratio of work in the field, as there is no need to readjust the detailed dimensions in the field even if the size of the members measured in the form that each reinforcement is assembled with bolts and anchors are different. It can be reduced, and assembly and construction are easy, and the precision of construction can be improved.

Fifth, in the present invention, since the perforated reinforcement is installed on the floor plate to serve as a tensile reinforcement and is arranged to have a certain height in the longitudinal direction of the beam, it contributes to the improvement of shear performance. Accordingly, after installing the seismic reinforcement, the subsequent process of installing the tensile reinforcement and shear reinforcement inside is not required, so the construction is simple.

The present invention has been described in connection with a preferred embodiment as mentioned above, but various modifications and variations can be made without departing from the gist of the present invention, and can be used in various fields.

Accordingly, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

M: mortar
10: look
100: lower plate
110: upper surface
130: vertical plane
200: side plate
210: vertical material
230: horizontal material
231: slit
300: floor plate
310: reinforcement
311: through hole

Claims (8)

delete A lower plate 100 installed under the beam 10 of the building;
A side plate 200 installed on the side of the beam 10 and having a lower or lower end coupled to the lower plate 200 to be installed;
A floor plate 300 installed under the lower plate 200 and coupled to a lower end of the side plate 200 to be installed;
It characterized in that it is configured to include,
The lower plate 100 is shaped like a bent plate,
Upper surface 110; And,
A vertical surface 130 bent at an end of the upper surface 110;
Consisting of including,
The upper surface 110 is installed coupled to the lower portion of the beam 10,
High-performance hybrid beam structure for seismic reinforcement, characterized in that the vertical surface 130 is installed in conjunction with the side plate 200.
In paragraph 2,
The side plate 200 is a b-shaped plate material is bent,
Vertical member 210;
A horizontal member 230 bent at the bottom of the vertical member 210;
Consisting of including,
The vertical member 210 is a high-performance hybrid beam structure for seismic reinforcement, characterized in that coupled to the side of the beam (10) and the vertical surface (130).
In paragraph 3,
The floor plate 300,
High-performance hybrid beam structure for seismic reinforcement, characterized in that coupled to the horizontal member 230 is installed.
In claim 4,
A high-performance hybrid beam structure for seismic reinforcement, characterized in that a mortar (M) is filled in the inner space surrounded by the upper surface 110, the vertical surface 130, the horizontal member 230 and the floor plate 300.
delete It is to construct the high-performance hybrid beam structure for seismic reinforcement of Clause 5,
(1) a lower plate installation step of coupling and installing the upper surface 110 to the lower portion of the beam 10;
(2) a side plate first installation step of coupling and installing the vertical member 210 to the side of the beam 10;
(3) a side plate second installation step of coupling and installing the vertical member 210 to the vertical surface 130;
(4) a floor plate installation step of coupling and installing the floor plate 300 to the horizontal member 230;
(5) a mortar filling step of filling the mortar (M) in an inner space surrounded by the upper surface 110, the vertical surface 130, the horizontal member 230, and the floor plate 300;
Construction method of a high-performance hybrid beam structure for seismic reinforcement, characterized in that configured to include.
It is to construct the high-performance hybrid beam structure for seismic reinforcement of Clause 5,
(1) a lower plate installation step of coupling and installing the upper surface 110 to the lower portion of the beam 10;
(2) a side plate first installation step of coupling and installing the vertical member 210 to the vertical surface 130;
(3) a side plate second installation step of coupling and installing the vertical member 210 to the side of the beam 10;
(4) a floor plate installation step of coupling and installing the floor plate 300 to the horizontal member 230;
(5) a mortar filling step of filling the mortar (M) in an inner space surrounded by the upper surface 110, the vertical surface 130, the horizontal member 230, and the floor plate 300;
Construction method of a high-performance hybrid beam structure for seismic reinforcement, characterized in that configured to include.

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