KR102319576B1 - Strengthening Steel Structure of Reinforced Concrete Buildings - Google Patents

Abstract

The present invention relates to a seismic reinforcement structure for a building, capable of increasing seismic performance of a building, which comprises: a first fixing bracket having a first installation hole formed therein; a second fixing bracket having a second installation hole formed therein; a first side surface bracket having a first guide groove formed therein; a second side bracket having a second guide groove formed therein; an installation bar installed to connect the first and second fixing brackets; and a plurality of connection bars.

Description

Seismic Reinforcement Structure for Buildings {Strengthening Steel Structure of Reinforced Concrete Buildings}

The present invention relates to an earthquake-resistant reinforcing structure for a building, and in more detail, it is installed to connect a pillar and a beam of a building, and prevents the building from shaking or being damaged even when shaking occurs at the connection part of the pillar and the beam, thereby preventing the building from being shaken or damaged. It relates to a seismic reinforcing structure for buildings designed to improve performance.

Earthquake resistance refers to the ability of a building to withstand earthquakes in the event of a natural disaster such as an earthquake.

Such seismic resistance refers to the strength that can withstand earthquakes. In recent years, construction has been carried out so that seismic design is made during the construction process of buildings, or earthquake-resistant reinforcement structures are installed on columns, beams, and walls of buildings where construction has been made. to improve the seismic performance of

This may increase the seismic performance of a building by using a lot of aggregates or reinforcing bars that can increase the seismic performance in the process of constructing a building. is being used by applying .

For example, in the prior art, in order to increase the seismic performance of a building, an earthquake-resistant reinforcement structure of a building installed at a portion connecting a column and a beam of the building has been proposed as in the document (1).

This seismic reinforcement structure is connected to the pillars and beams of the building so that the connection between the pillars and the beams is made solidly, thereby increasing the earthquake resistance performance of the building.

However, conventional seismic reinforcing structures such as document (1) had a problem in that it was difficult to make easy connection and use depending on the shape or installation location of the pillars and beams, even when trying to connect the pillars and beams of the building. If the shape or position of the pillars and beams to be installed is changed, the earthquake-resistant reinforcement structure cannot be installed, or there is a problem in that it has to be re-manufactured and installed according to the shape of the pillars and beams.

In addition, the conventional seismic reinforcement structures such as document (1) have some advantages in that the connection part of the column and the beam is made firmly so that the building can withstand shaking such as an earthquake, but the state of combining the column and the beam, Depending on the type of installation, it was difficult to install and use the seismic reinforcement structure in the direction to increase the seismic performance. There was a problem that the function could not be achieved.

(1) Republic of Korea Patent Registration No. 10-1862038 (2018.05.23)

The present invention has been devised to solve the above-described problems, and the objects of the present invention are as follows.

First, it is connected to the pillars and beams constituting the building to increase the earthquake-resistant performance of the building.

Second, even when the type of combination of pillars and beams to be installed or the type of installation is changed, it responds flexibly to the positions of pillars and beams and enables stable installation and use.

Third, it is installed in the direction to increase the seismic performance according to the combination position of the column and the beam to be installed, so that the seismic reinforcement of the building can be achieved.

Fourth, it is possible to prevent unnecessary maintenance and repair costs from increasing by enabling stable use without the risk of damage even when shaking occurs in the building.

Fifth, even when excessive vibration occurs in the building, it is configured to respond flexibly to such vibration, so that the earthquake-resistant reinforcement structure can be maintained stable without the problem of damage.

In order to achieve the above object, the present invention, in the earthquake-resistant reinforcement structure connected to the pillars and beams of a building, is installed to surround the upper front surface of the pillar centered on the beam, and a plurality of first couplings are provided on the front surface corresponding to the pillar. A ball is formed, and a first fixing bracket having a first installation hole to which a bolt is coupled is formed on both sides corresponding to the pillar, and is installed to surround the lower front surface of the pillar centered on the beam so as to be spaced apart from the first fixing bracket, A plurality of second coupling holes are formed on the front surface corresponding to the pillars, and second fixing brackets having second installation holes to which bolts are coupled are formed on both sides corresponding to the pillars, and to surround one side of the beam centered on the pillars. Installed, a plurality of first through-holes to which bolts are fastened are formed on an upper surface corresponding to the beam, a first side bracket having a first guide groove formed on one front side corresponding to the beam, and the first side bracket being spaced apart from the first side bracket A second side bracket that is installed to surround the other side of the beam centered on the column, a plurality of second through-holes to which bolts are fastened are formed on an upper surface corresponding to the beam, and a second guide groove is formed on one front side corresponding to the beam And, a plurality of first fastening holes corresponding to the first coupling holes are formed at the upper end, an upper coupling bar having a first guide hole formed in the longitudinal center portion, and a plurality of second fastening holes corresponding to the second coupling holes are formed at the bottom, An installation bar composed of a lower coupling bar having a second guide hole formed in the longitudinal center portion, an elastic member connecting the upper coupling bar and the lower coupling bar, and installed to connect the first fixing bracket and the second bracket, and a long connection inside A ball is formed in a bar shape, and one end is connected to the first guide groove through a bolt fastened to the connection hole and the other end is installed to be connected to the first guide hole or the second guide hole, and one end to the second guide groove. This connection and the other end may be configured to include a plurality of connecting bars that are installed to be connected to the first guide hole or the second guide hole.

In addition, fixing holes are further formed on the front surfaces of the first side bracket and the second side bracket, and a reinforcing bar connected to the first side bracket and the second side bracket is further installed in the installation bar, and the reinforcing bar is the second side bracket. A first reinforcing bar is formed in a portion corresponding to the first fastening hole and coupled to surround the front surface of the upper coupling bar, a pair of second reinforcing bars installed to be connected to both sides of the first reinforcing bar, and the second It is connected to the reinforcing bar and the elastic wire, and a bolt hole corresponding to the fixing hole is formed at the end to include a pair of third reinforcing bars installed to connect the second reinforcing bar, the first side bracket, and the second side bracket. can

The present invention as described above can obtain the following effects.

First, it is possible to increase the seismic performance of the building by being connected to the columns and beams constituting the building.

Second, it is possible to achieve stable installation and use by flexibly responding to the position of the column and the beam even when the combination of the column and the beam to be installed or the installation form is changed.

Third, it is installed in a direction to increase the seismic performance according to the combination position of the column and the beam to be installed, so that the seismic reinforcement of the building can be achieved.

Fourth, it is possible to prevent unnecessary maintenance and repair costs from increasing by enabling stable use without the risk of damage even when shaking occurs in the building.

Fifth, even when excessive vibration is generated in the building, it is configured to respond flexibly to such vibration, thereby maintaining a stable earthquake-resistant reinforcement performance of the building without the problem of damage to the earthquake-resistant reinforcement structure.

1 is a perspective view showing a state in which the earthquake-resistant reinforcement structure for a building according to the present invention is coupled to a column and a beam.
2 is another perspective view showing a state in which the earthquake-resistant reinforcement structure for a building according to the present invention is coupled to a column and a beam.
3 is a front view showing a state in which the earthquake-resistant reinforcement structure for a building according to the present invention is installed on a column and a beam.
Figure 4 is another front view showing a state in which the earthquake-resistant reinforcement structure for a building according to the present invention is installed on a column and a beam.
5 is another front view showing a state in which the earthquake-resistant reinforcement structure for a building according to the present invention is installed on a column and a beam.
Figure 6 is a perspective view showing a reinforcing bar installation state of the earthquake-resistant reinforcing structure for a building according to the present invention.
7 is another perspective view showing a reinforcing bar installation state of the earthquake-resistant reinforcing structure for a building according to the present invention.
8 is a front view showing a state in which the earthquake-resistant reinforcement structure for a building according to the present invention is installed on a column and a beam.

The terms or words used in the present specification and claims are not to be construed as being limited in their ordinary or dictionary meanings, but 'the inventor may properly define the concept of the term in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of 'can be'.

In addition, the embodiments described in this specification and the configurations shown in the drawings are merely preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, so they can be substituted at the time of the present application It should be understood that there may be various equivalents and variations.

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

The present invention, in the earthquake-resistant reinforcement structure connected to the pillar (1) and the beam (2) of a building, is installed so as to surround the upper front surface of the pillar (1) centered on the beam (2), the pillar (1) A first fixing bracket ( 10) and the first fixing bracket 10 and is installed to surround the lower front surface of the column 1 centered on the beam 2 so as to be spaced apart from the first fixing bracket 10, and the front surface corresponding to the column 1 has a plurality of second A second fixing bracket 20 in which a coupling hole 21 is formed and a second installation hole 22 to which a bolt P is coupled is formed on both sides corresponding to the pillar 1, and the pillar 1 It is installed to surround one side of the beam (2) centered on the beam (2), and a plurality of first through holes (31) to which the bolt (P) is fastened is formed on the upper surface corresponding to the beam (2), and the beam (2) and A first side bracket 30 having a first guide groove 32 formed on one side of the corresponding front side, and the other side of the beam 2 centered on the pillar 1 so as to be spaced apart from the first side bracket 30 A plurality of second through-holes 41 to which the bolts P are fastened are formed on the upper surface corresponding to the beam 2, and a second guide groove 42 is formed on one front side corresponding to the beam 2 ) formed on the second side bracket 40, and a plurality of first fastening holes 51a corresponding to the first coupling holes 11 are formed at the upper end, and a first guide hole 51b is formed in the longitudinal center portion. The formed upper coupling bar 51 and a plurality of second coupling holes 52a corresponding to the second coupling holes 21 are formed at the bottom, and a lower coupling having a second guide hole 52b formed in the longitudinal center portion. It is composed of a bar 52 and an elastic member 53 connecting the upper coupling bar 51 and the lower coupling bar 52 to connect the first fixing bracket 10 and the second bracket 20 to each other. An installation bar 50 to be used and a bar shape having an elongated connection hole 61 formed therein, one end connected to the first guide groove 32 through a bolt P fastened to the connection hole 61 and the other end It is installed to be connected to the first guide hole 51b or the second guide hole 52b, one end is connected to the second guide groove 42, and the other end is the first guide hole 51b or the second guide hole (52b). 52b) and is configured to include a plurality of connecting bars 60 installed to be connected.

As shown in FIGS. 1 to 5 , the first fixing bracket 10 is installed to surround the upper front surface of the column 1 centered on the portion where the column 1 and the beam 2 are connected.

To this end, the first fixing bracket 10 is first fixed to surround the pillar 1 by fastening the bolt P with the first installation holes 12 formed on both sides corresponding to the pillar 1 . The bracket 10 is configured to be firmly installed.

In addition, as the first coupling hole 11 formed on the front surface corresponding to the pillar 1, the upper coupling bar 51 of the installation bar 50, which will be described in detail below, is coupled through the bolt P. .

And the second fixing bracket 20 is installed to surround the lower front surface of the pillar 1 centered on the beam 2 so as to be spaced apart from the first fixing bracket 10 as shown in FIGS. 1 to 5 . The bolts P are fastened to the second installation holes 22 formed on both sides corresponding to the pillar 1 to form a solidly installed state on the pillar 1 .

In this configuration, as shown in FIGS. 2 and 3 , the first fixing bracket 10 is coupled to the upper portion of the column 1 centered on the beam 2 , and the second fixing bracket 20 . It is configured to be coupled to the lower portion of the column (1) centered on the beam (2).

At this time, it is preferable that the first fixing bracket 10 and the second fixing bracket 20 be installed to be connected through an installation bar 50 which will be described in detail below.

In addition, the first fixing bracket 10 and the second fixing bracket 20 are made of a solid metal material, so that even when connected to the pillar 1, a solid coupling and installation position can be maintained.

In addition, as shown in FIGS. 1 to 5, the first side bracket 30 is installed to surround one side of the beam 2 centered on the pillar 1, and a first through hole formed in the upper surface. It is firmly coupled to the beam (2) by fastening the bolt (P) with (31).

And the first guide groove 32 formed on one side of the front side is configured such that one end of the connection bar 60, which will be described in detail below, is coupled through the bolt (P).

In addition, the second side bracket 40 is installed to surround the other side of the beam 2 centered on the pillar 1 so as to form a position opposite to the first side bracket 30, and the second side bracket 40 is formed on the upper surface. It is configured to be firmly installed in the beam (2) by fastening the bolt (P) with the two through-holes (41).

At this time, the second guide groove 42 formed on one side of the front side of the second side bracket 40 is configured such that one end of the connecting bar 60 , which will be described in detail below, is coupled through the bolt P.

As described above, the first fixing bracket 10 and the second fixing bracket 20 are installed to surround the upper and lower front surfaces of the pillar 1 centered on the beam 2, and the first side bracket (30) and the second side bracket (40) is configured to be installed so as to surround both sides of the front surface of the beam (2) centered on the pillar (1).

And in the case of forming the above combination, as shown in FIGS. 3 to 5, the installation bar 50, which will be described in detail below, is installed to connect the first fixing bracket 10 and the second fixing bracket 20, A plurality of connecting bars 60 are installed to be connected to the installation bar 50 in a state in which they are respectively connected to the first side bracket 30 and the second side bracket 40 .

To describe this configuration in more detail, the installation bar 50 has a plurality of first fastening holes 51a corresponding to the first coupling holes 11 formed at the top, as shown in FIGS. 1 to 5 , and the length An upper coupling bar 51 having a first guide hole 51b formed therein, and a plurality of second coupling holes 52a corresponding to the second coupling hole 21 are formed at the lower end of the central portion in the longitudinal direction. It consists of a lower coupling bar 52 having a second guide hole 52b formed therein, and an elastic member 53 connecting the upper coupling bar 51 and the lower coupling bar 52 to each other.

The upper coupling bar 51 is installed on the front side of the first fixing bracket 10 through the bolt P fastened to the first fastening hole 51a, and even when such coupling is made, the first fixing bracket ( 10) is configured to be coupled while adjusting the position coupled to the first coupling hole 11 formed in the 10).

In addition, the lower coupling bar 52 is installed on the front surface of the second fixing bracket 20 through the bolt P fastened to the second fastening hole 52a, and is formed in the second fixing bracket 20 . It is configured to adjust the position coupled to the second coupling hole 21 and to achieve coupling.

In this configuration, that is, as shown in FIGS. 3 to 5 , even when the installation bar 50 is coupled to connect the first fixing bracket 10 and the second fixing bracket 20 installed on the pillar 1 , , is configured to adjust the coupling position of the installation bar 50 and to achieve easy coupling.

In addition, the upper coupling bar 51 and the lower coupling bar 52 are configured to be connected through an elastic member 53 , so that the first fixing bracket 10 and the second fixing bracket 20 are connected to the pillar (1). Even when the position is changed due to shaking, the connection between the upper coupling bar 51 and the lower coupling bar 52 is firmly maintained to achieve seismic reinforcement of the pillar 1 connected to the beam 2 will be.

In addition, the upper coupling bar 51 and the lower coupling bar 52 is configured to prevent the connection portion from being damaged due to the shaking and to achieve stable use.

And as shown in FIGS. 1 to 5 , the connecting bar 60 has a bar shape having an elongated connecting hole 61 formed therein, and the first through the bolt P fastened to the connecting hole 61 . One end is connected to the first guide groove (32) and the other end is installed to be connected to the first guide hole (51b) or the second guide hole (52b), one end is connected to the second guide groove (42), and the other end is connected to the second guide hole (42). It is configured to include a plurality of connecting bars 60 installed to be connected to the first guide hole (51b) or the second guide hole (52b).

As shown in FIGS. 3, 4, 5, and 8, the connecting bar 60 includes the first guide groove 32 of the first side bracket 30 and the second side bracket 40 In a state in which one end is connected to the two guide grooves 42, depending on the direction in which the earthquake-resistant reinforcement of the building is to be achieved, selective coupling to the upper coupling bar 51 or the lower coupling bar 52 of the installation bar 50 is performed. is composed

That is, as in FIG. 3 , when the connecting bar 60 is installed, the beam 2 can be installed and used to prevent the beam 2 from sagging or flowing around the pillar 1 , and FIG. And, as in FIG. 5, when the connecting bar 60 is installed, any one of the beams 2 connected to the column 1 can be installed and used to prevent sagging or flow.

In addition, the connecting bar 60 is installed by adjusting the position along the formation direction of the first guide groove 32 and the second guide groove 42 , and the upper coupling bar 51 or the lower coupling bar 52 . ), even when connected to the first guide hole 51b of the upper coupling bar 51 or the second guide hole 52b of the lower coupling bar 52, the installation is performed by adjusting the position. As a result, the installation position can be easily adjusted and used according to the direction in which the earthquake resistance of the building is to be achieved.

In addition, as shown in FIGS. 6 to 8 , fixing holes 30a and 40a are further formed on the front surfaces of the first side bracket 30 and the second side bracket 40 , and the installation bar 50 . is further provided with a reinforcing bar 70 connected to the first side bracket 30 and the second side bracket 40, and the reinforcing bar 70 corresponds to the first fastening hole 51a. A pair of first reinforcing bars 71 coupled to cover the front surface of the upper coupling bar 51 by having an insertion hole 71a formed in the region, and a pair installed to be connected to both sides of the first reinforcing bar 71 . The second reinforcing bar 72 and the second reinforcing bar 72 and the elastic wire 74 are connected to each other, and bolt holes 73a corresponding to the fixing holes 30a and 40a are formed at the ends. and a pair of third reinforcing bars 73 installed to connect the second reinforcing bar 72 , the first side bracket 30 and the second side bracket 40 .

In this configuration, as shown in FIGS. 7 and 8, after the first reinforcing bar 71 is coupled to surround the front surface of the upper coupling bar 51, the second reinforcing bar 72 and the elastic wire 74 ), the third reinforcing bar 73 connected through the first side bracket 30 and the second side bracket 40 are installed to be connected through the bolt P, so that the first reinforcing bar 71 is installed on the pillar ( Even when the beam 2 on which the third reinforcing bar 73 is installed around 1) shakes, the seismic reinforcement of the pillar 1 and the beam 2 can be easily achieved through the configuration of the elastic wire 74. will become

As described above, the present invention is transmitted to the pillar (1) and the beam (2) even when the shaking occurs in the connection portion of the pillar (1) and the beam (2) due to the shaking of the building due to a natural disaster such as an earthquake By distributing the load and minimizing the shaking transmitted to the columns (1) and beams (2), it is possible to increase the earthquake-resistant performance of the building.

In addition, it is possible to achieve stable installation and use by flexibly responding to the position of the column and the beam even when the combination of the column and the beam to be installed or the installation form is changed.

Although the present invention has been shown and described with respect to specific embodiments, it is recognized in the art that various improvements and modifications may be made to the present invention without departing from the spirit or scope of the present invention as provided by the following claims. It will be apparent to those of ordinary skill in the art.

1: Column 2: Beam
10: Fixing bracket 11: Adhesive bar
11a: fastening projection 11b: reinforcing plate
12: connecting bar 12a: connecting protrusion
15: level 20: connection bracket
21: fixing protrusion 30: connecting link
31: fastening hole 32, 52: elastic member
40: fixing nut 50: reinforcement frame
51: connection hole 53: fixing bolt

Claims (2)

In the earthquake-resistant reinforcement structure connected to the pillar (1) and the beam (2) of the building,
It is installed to surround the upper front surface of the column 1 with the beam 2 as the center, and a plurality of first coupling holes 11 are formed on the front surface corresponding to the column 1, and the column 1 and A first fixing bracket (10) having a first installation hole (12) to which a bolt (P) is coupled is formed on both sides thereof;
It is installed to surround the lower front surface of the column 1 centered on the beam 2 so as to be spaced apart from the first fixing bracket 10, and a plurality of second coupling holes 21 on the front surface corresponding to the column 1 ) is formed, and a second fixing bracket 20 having a second installation hole 22 to which a bolt (P) is coupled is formed on both sides corresponding to the pillar (1);
It is installed to surround one side of the beam (2) centered on the pillar (1), and a plurality of first through holes (31) to which the bolt (P) is fastened is formed on the upper surface corresponding to the beam (2), A first side bracket 30 having a first guide groove 32 formed on one front side corresponding to the beam 2,
It is installed to surround the other side of the beam 2 centered on the pillar 1 so as to be spaced apart from the first side bracket 30 , and a plurality of bolts P are fastened to the upper surface corresponding to the beam 2 . A second side bracket 40 in which a second through hole 41 is formed and a second guide groove 42 is formed on one front side corresponding to the beam 2,
An upper coupling bar 51 having a plurality of first coupling holes 51a corresponding to the first coupling holes 11 formed at an upper end and a first guide hole 51b formed in a longitudinal center portion, and the second coupling hole 51a A plurality of second fastening holes 52a corresponding to the coupling hole 21 are formed at the lower end, and a lower coupling bar 52 having a second guide hole 52b formed in the longitudinal center portion thereof, and the upper coupling bar 51 . ) and an elastic member 53 connecting the lower coupling bar 52, and an installation bar 50 installed to connect the first fixing bracket 10 and the second bracket 20;
It has a bar shape in which an elongated connection hole 61 is formed inside, and one end is connected to the first guide groove 32 through a bolt P fastened to the connection hole 61, and the other end is the first guide hole. (51b) or installed to be connected to the second guide hole (52b), one end is connected to the second guide groove (42) and the other end is connected to the first guide hole (51b) or the second guide hole (52b) Including a plurality of connecting bars 60 to be installed,
Fixing holes 30a and 40a are further formed on the front surfaces of the first side bracket 30 and the second side bracket 40,
A reinforcing bar 70 connected to the first side bracket 30 and the second side bracket 40 is further installed in the installation bar 50,
The reinforcing bar 70 is
The first reinforcing bar 71 is formed in a portion corresponding to the first fastening hole (51a) and the insertion hole (71a) is coupled to surround the front surface of the upper coupling bar (51);
A pair of second reinforcing bars 72 installed to be connected to both sides of the first reinforcing bar 71,
The second reinforcing bar 72 and the second reinforcing bar 72 are connected through an elastic wire 74, and bolt holes 73a corresponding to the fixing holes 30a and 40a are formed at the ends of the second reinforcing bar 72 and the second reinforcing bar 72 and the second reinforcing bar 72. Seismic reinforcement structure for a building, characterized in that it includes a pair of third reinforcing bars (73) installed to connect the first side bracket (30) and the second side bracket (40). delete

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