KR20110049064A - Aseismic reinforcement equipment and the structure aseismic reinforcement method of construction for which this was used - Google Patents

Abstract

PURPOSE: A seismic reinforcement apparatus and a seismic reinforcement method using the same are provided to efficiently absorb seismic shock by installing the seismic reinforcement apparatus in the corner of a building. CONSTITUTION: A seismic reinforcement apparatus comprises upper and lower plates(100,110) and multiple thin steel plates(120). The upper and lower plates are formed in a right-angled triangular shape and are vertically separated from each other. The thin steel plates are horizontally or vertically arranged on the inner surface of the upper plate or the lower plate at uniform intervals. Fixing protrusions are formed on the sides of the upper and lower plates without the oblique sides.

Description

Earthquake-resistant reinforcement apparatus and the structure-seismic reinforcement method using the same {aseismic reinforcement equipment and the structure aseismic reinforcement method of construction for which this was used}

The present invention relates to an earthquake-resistant reinforcement device and a seismic reinforcement method using the same, and in particular, by installing an earthquake-resistant reinforcement device of a triangular bracket that can absorb shocks at each point of a building and improve the resistance to shock. The present invention relates to an apparatus and a seismic reinforcing method using the same.

As is well known, if the public structure is hypothesized through the design review at a lower level than the existing seismic design regulations or the currently applied seismic design regulations, seismic reinforcement works for improvement of seismic performance should be secured. do.

Recent damages caused by large earthquakes and small-scale earthquakes in neighboring countries have shown that domestic structures are not located in seismic safety zones. It is being promoted.

Conventionally, seismic reinforcement methods applied at home and abroad are used to install a seismic isolator at the part where the structure is in contact with the pillar so that the structure is separated from the foundation and the earthquake shock is not transmitted directly to the structure. Reinforcement method of installing reinforcement using steel material on inner edge part of slab of window part installed to be open and contacting pillar, and attaching shear reinforcement such as steel plate or carbon fiber to pillar of structure to prevent column from being destroyed by impact Construction is mainly applied.

In other words, the construction is mainly aimed at improving the seismic performance to increase the rigidity of the structure so as not to be destroyed from the impact caused by the earthquake, and the construction to increase the rigidity by attaching a reinforcing member made of steel is mainly performed. .

However, the construction stage is applied to manufacture the reinforcement in the factory and installed in the field, install the reinforcement made smaller than the inner size of the slab and pillar of the actual structure for the site installation, and integrating by injecting mortar into the lifting site Since the method is applied, there are many problems in the part where the structure and the reinforcing material are integrated to express the seismic performance.

In addition, there are many problems to be solved, such as the risk of concrete breakage at the edges due to the difference in stiffness between concrete structures to which impacts from earthquakes are transmitted and the reinforcement made of steel, and the occurrence of lifting due to the expansion and contraction of steel materials. do.

Therefore, the present invention has been made to solve the problems described above, by installing a seismic reinforcement device of the triangular bracket that can absorb the shock by each point of the building to the earthquake resistance to the earthquake shock resistance ability The purpose of the present invention is to provide a seismic reinforcing device and a seismic reinforcing method using the same.

The seismic reinforcing device according to the present invention for achieving the above object is made of a right triangle shape of a rubber material, the upper and lower plates are arranged in a spaced apart state; It is characterized by consisting of a thin steel sheet is attached to a plurality of narrow and long steel sheet with a predetermined interval on the inner surface of the upper plate or the lower plate.

In addition, the earthquake-resistant reinforcement method using the seismic reinforcing device according to the present invention for achieving the above object is made of a right angle triangle shape of rubber material in the corner portion of the building and the pillar of the building, The upper and lower plates are arranged in a spaced apart state; It is composed of a thin plate steel sheet is attached to a plurality of narrow and long steel plate with a constant interval on the inner surface of the upper plate or lower plate, the thin plate steel plate is fixed to the inner surface of the upper plate or lower plate in the transverse direction or longitudinal direction A steel plate provided with a reinforcement device, the steel plate being formed in a quadrangular shape at the end of the seismic reinforcement device and having a bolt hole having a constant diameter; A reinforcement bar having a plurality of vertically fixedly installed at regular intervals on the steel plate; It is characterized in that the formulation fixing device consisting of a slope formed so that the upper end of the steel sheet has a constant inclination upward, and inserting a stud anchor to the formulation fixing device to install the seismic reinforcing device fixed to the column and beam.

As described above, the seismic reinforcing device and the earthquake-resistant reinforcing method using the same according to the present invention has the following effects.

First, the present invention is to install a seismic reinforcement device of the triangular bracket that can absorb the shock by each point of the building to the corner of the building to not only absorb the earthquake shock during the earthquake of the building and structure, but also improve the resistance capacity There are advantages to it.

Second, the present invention has the advantage of delaying the destruction of buildings and structures due to the earthquake shock during the earthquake of buildings and structures.

Hereinafter, with reference to the accompanying drawings and examples of the present invention will be described in detail.

[Seismic Reinforcement Device 1]

1 is a front view of the seismic reinforcing device 1 according to the present invention.

As shown in these drawings, the earthquake-resistant reinforcement device (A1) according to the present invention is made of a right triangle shape of a rubber material, the upper and lower plates (100, 110) arranged in a spaced apart state; The inner plate of the upper plate 100 or the lower plate 110 is composed of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plate with a predetermined interval.

That is, the seismic reinforcement device A1 according to the present invention is characterized in that the thin steel plate 120 is fixed between the upper and lower plates 100 and 110 having a right triangle shape of rubber material.

Here, the upper plate 100 and the lower plate 110 is formed in a right triangle shape as a whole to be installed in the corner portion of the building (S) formed by the pillar (C) and the beam (B), at the same time vibration caused by the earthquake It is formed of an elastic rubber material so that it can be easily absorbed.

In addition, the thin steel sheet 120 is installed by pressing a plurality of thin steel sheet 120 to the upper plate 100 or the lower plate 110 in the form of upper and lower strait or left light narrow, and the thin steel sheet 120 is the upper plate 100 Or fixed to the inner surface of the lower plate 110 in the transverse or longitudinal direction of the upper plate 100 or the lower plate 110.

As such, the reason why the thin steel sheet 120 is disposed in the upper plate 100 or the lower plate 110 is that when a plurality of thin steel sheets 120 are used vertically and horizontally rather than when a single thin steel sheet 120 is used and installed, This is because the vibration caused by the vibration can be easily absorbed and attenuated.

Hereinafter, the seismic reinforcement of buildings using the seismic reinforcing device according to the present invention having the configuration as described above will be described.

Figure 3 is an exemplary view showing a state where the seismic reinforcement device 1 according to the present invention is installed on the column and interpolation.

As shown in this figure, the earthquake-resistant reinforcement method using the seismic reinforcing device according to the present invention is a building (S) consisting of a column (C) and a beam (B), the pillar (C) of the building (S) Upper and lower plates (100, 110) made of a right-angled triangular shape of a rubber material formed in the corner portion formed by the beam (B) and spaced apart from each other; The inner plate of the upper plate 100 or the lower plate 110 is composed of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plates at regular intervals, the thin plate steel plate 120 of the upper plate or lower plate Steel plate provided with a seismic reinforcement device (A1) is fixed to the inner side in the transverse direction or longitudinal direction, made of a rectangular shape as a whole at the end of the seismic reinforcement device (A1), the bolt hole 220 having a constant diameter is formed 210; Reinforcing bar 230 fixed to a plurality of vertically installed at regular intervals on the steel plate 210; Installing the formulation fixing device 200 consisting of the inclined surface 240 formed so that the upper end of the steel plate 210 has a constant inclination upward, and inserts a stud anchor 300 in the formulation fixing device 200 to the seismic reinforcement The device A1 is fixed to the column C and the beam B.

4 is an exemplary view showing a state in which the seismic reinforcement device 1 according to the present invention is installed on a column and interpolation.

As shown in this figure, the earthquake-resistant reinforcement method using the seismic reinforcing device according to the present invention is a building (S) consisting of a column (C) and a beam (B), the pillar (C) of the building (S) Upper and lower plates (100, 110) made of a right-angled triangular shape of a rubber material formed in the corner portion formed by the beam (B) and spaced apart from each other; The inner plate of the upper plate 100 or the lower plate 110 is composed of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plates at regular intervals, the thin plate steel plate 120 is the top plate 100 Alternatively, the seismic reinforcement device A1 is installed on the inner surface of the lower plate 110 in the transverse direction or the longitudinal direction, and the inclined surface 410 and the inclined surface 410 having a predetermined inclination outside the seismic reinforcement device A1. ) Is provided with a band-shaped fixing device 400 consisting of a horizontal surface 420 integrally formed at the upper end of the upper surface and a vertical surface 430 vertically integrally formed at the lower end of the inclined surface 410. A steel plate 210 formed in a quadrangular shape at an end of 400 and having a bolt hole 220 having a constant diameter; Reinforcing bar 230 fixed to a plurality of vertically installed at regular intervals on the steel plate 210; Installing the formulation fixing device 200 consisting of the inclined surface 240 formed so that the upper end of the steel plate 210 has a constant inclination upward, and inserts a stud anchor 300 in the formulation fixing device 200 to the seismic reinforcement The device A1 is fixed to the column C and the beam B.

5 is an exemplary view showing a state in which the seismic reinforcement device 1 according to the present invention is installed on a column and interpolation.

As shown in this figure, the earthquake-resistant reinforcement method using the seismic reinforcing device according to the present invention is a building (S) consisting of a column (C) and a beam (B), the pillar (C) of the building (S) And the fixed beams 500 are installed on the beams B, respectively, and formed in a right-angled triangular shape made of rubber material at the corners formed by the pillars C and the beams B, and the upper and lower spaces are disposed to be spaced apart. Lower plates 100 and 110; The inner plate of the upper plate 100 or the lower plate 110 is composed of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plates at regular intervals, the thin plate steel plate 120 of the upper plate or lower plate A seismic reinforcement device (A1) is installed on the inner side in the transverse or longitudinal direction fixed, and has a constant inclination across the seismic reinforcement device (A1) and the fixed steel plate 500 of the column (C) and the beam (B) Strap-type fixing device 400 consisting of a horizontal surface 420 integrally formed at the upper end of the inclined surface 410 and the upper surface of the inclined surface 410 and a vertical surface 430 vertically integrally formed at the lower end of the inclined surface 410. A steel plate 210 installed by welding, and having a rectangular shape as a whole at an end portion of the outer side of the belt-shaped fixing device 400 and having a bolt hole 220 having a constant diameter; Reinforcing bar 230 fixed to a plurality of vertically installed at regular intervals on the steel plate 210; The upper end of the steel plate 210 is welded to install the formulation fixing device consisting of the inclined surface 240 formed to have a constant inclination upward.

6 is an exemplary view showing a state in which the seismic reinforcement device 1 according to the present invention is installed on a column and interpolation.

As shown in this figure, the seismic reinforcement method of the building using the seismic reinforcing device according to the present invention is a steel structure (S) consisting of a column (C) and a beam (B), the column (C) and beam (B) The upper and lower plates 100 and 110 are formed in a right triangle shape made of a rubber material and are spaced apart from each other. The inner plate of the upper plate 100 or the lower plate 110 is composed of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plates at regular intervals, the thin plate 120 is the upper plate 100 Alternatively, the seismic reinforcement device A1 is installed on the inner surface of the lower plate 110 in the transverse direction or the longitudinal direction, and the inclined surface 410 and the inclined surface 410 having a predetermined inclination outside the seismic reinforcement device A1. Column (C) and beam (B) of the belt-shaped fixing device consisting of a horizontal surface 420 is formed integrally with the upper end of the upper surface and a vertical surface 430 is formed vertically integrally with the lower end of the inclined surface (410) Fix it by welding).

[Seismic Reinforcement Device 2]

Figure 2 is a front view showing a seismic reinforcing device 2 according to the present invention.

As shown in these drawings, the seismic reinforcing device (A2) according to the present invention is made of a right triangle shape of a rubber material, the upper and lower plates (100, 110) arranged in a spaced apart state; A thin steel sheet 120 having a plurality of narrow and long steel sheets attached to the inner surface of the upper plate 100 or the lower plate 110 at a predetermined interval; The upper plate 100 and the lower plate 110 is composed of a fixing protrusion 130 protruding in a predetermined shape on the outside of the remaining two sides except the hypotenuse.

That is, the seismic reinforcement device (A2) according to the present invention is relatively similar to the seismic reinforcement device (A1) in terms of its shape, but for the installation of the fixing projections along the outer periphery of the upper plate 100 and the lower plate 110 ( 130 is formed, so that when the column (C) and the beam (B) is constructed, the fixing projections 130 of the seismic reinforcing device (A2) is embedded in the column (C) and the beam (B) by the concrete It features.

In addition, by pressing a plurality of thin plate steel sheet 120 to the upper plate 100 or the lower plate 110 in the form of upper and lower narrow or left light narrow, and the thin steel plate 120 of the upper plate 100 or lower plate 110 It is fixed to the inner surface of the upper plate 100 or the lower plate 110 in the transverse direction or longitudinal direction.

As such, the reason why the thin steel sheet 120 is disposed in the upper plate 100 or the lower plate 110 is that when a plurality of thin steel sheets 120 are used vertically and horizontally rather than when a single thin steel sheet 120 is used and installed, This is because the vibration caused by the vibration can be easily absorbed and attenuated.

Hereinafter, the seismic reinforcement of buildings using the seismic reinforcement device according to the present invention having the above-described configuration will be described.

7 is an exemplary view showing a state where the seismic reinforcement device 3 according to the present invention is embedded in a column and interpolation.

As shown in this figure, the seismic reinforcement method of the building using the seismic reinforcing device according to the present invention is a building (S) consisting of a column (C) and a beam (B), the pillar (C) and the beam of the building ( Upper and lower plates (100, 110) formed of a right-angled triangular shape made of rubber material and spaced apart from each other at a corner formed by the column (C) and the beam (B) at the time of construction of B); A thin steel sheet 120 having a plurality of steel plates having a narrow width and a long length in a transverse direction or a longitudinal direction at regular intervals on an inner surface of the upper plate 100 or the lower plate 110; The upper plate 100 and the lower plate 110 purchase a seismic reinforcement device (A2) consisting of a fixed protrusion 130 is formed to protrude in a predetermined shape on the outside of the other two sides except for the hypotenuse, the pillar (C) and Placing and curing concrete in the beam (B) to install a seismic reinforcement (A2).

1 is a front view showing a seismic reinforcing device 1 according to the present invention,

Figure 2 is a front view showing a seismic reinforcing device 2 according to the present invention,

3 to 6 is an exemplary view showing a state in which the seismic reinforcement device 1 is installed according to the present invention,

Figure 7 is an exemplary view showing a state in which the seismic reinforcement device 2 is installed according to the present invention.

Explanation of symbols on the main parts of the drawing

100: top plate 110: bottom plate

120: thin steel sheet 130: fixed projection

200: dosage form fixing device 210: steel sheet

220: bolt hole 230: reinforcement

240: slope 300: stud anchor

400: band fixing device 410: inclined surface

420: horizontal plane 430: vertical plane

500: fixed steel plate A1: seismic reinforcing device

A2: seismic enhancer B: beam

C: pillar F: framing

S: building or steel structure

Claims (8)

A top and bottom plates 100 and 110 formed of a right-angled triangular shape of a rubber material and arranged in spaced apart state; Earthquake-resistant reinforcement device, characterized in that consisting of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plates with a predetermined interval on the inner surface of the upper plate 100 or lower plate 110. The method of claim 1, The thin steel sheet 120 is seismic reinforcement device, characterized in that fixed to the inner side of the upper plate 100 or lower plate 110 in the transverse direction or longitudinal direction. The method of claim 1, Seismic reinforcement device characterized in that the upper plate 100 and the lower plate 110 is formed of a fixing protrusion 130 protruding in a predetermined shape on the outside of the remaining two sides except the hypotenuse. In the building S consisting of the pillar C and the beam B, Upper and lower plates 100 and 110 formed of a right-angled triangular shape made of rubber material and spaced apart from each other by a corner portion formed by the pillar C and the beam B of the building S; The inner plate of the upper plate 100 or the lower plate 110 is composed of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plates at regular intervals, the thin plate steel plate 120 of the upper plate or lower plate Steel plate provided with a seismic reinforcement device (A1) is fixed to the inner side in the transverse direction or longitudinal direction, made of a rectangular shape as a whole at the end of the seismic reinforcement device (A1), the bolt hole 220 having a constant diameter is formed 210; Reinforcing bar 230 fixed to a plurality of vertically installed at regular intervals on the steel plate 210; Installing the formulation fixing device 200 consisting of the inclined surface 240 formed so that the upper end of the steel plate 210 has a constant inclination upward, and inserts a stud anchor 300 in the formulation fixing device 200 to the seismic reinforcement A seismic reinforcement method for buildings using seismic reinforcing devices, characterized in that the device (A1) is fixed to the column (C) and beam (B). The method of claim 4, wherein An inclined surface 410 having a predetermined inclination on the outside of the seismic reinforcement device A1 and a horizontal surface 420 integrally formed at the upper end of the inclined surface 410 and vertically integrally at the lower end of the inclined surface 410. Building seismic reinforcement method using a seismic reinforcement device, characterized in that the installation of the belt-shaped fixing device consisting of a vertical surface 430 is formed. In the building S consisting of the pillar C and the beam B, The fixed steel plate 500 is installed on the pillars C and the beams B of the building S, respectively, and is formed in a right triangle shape made of rubber material at the corners formed by the pillars C and the beams B. The upper and lower plates 100 and 110 are disposed to be spaced apart from each other; The inner plate of the upper plate 100 or the lower plate 110 is composed of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plates at regular intervals, the thin plate steel plate 120 of the upper plate or lower plate A seismic reinforcement device (A1) is installed on the inner side in the transverse or longitudinal direction fixed, and has a constant inclination across the seismic reinforcement device (A1) and the fixed steel plate 500 of the column (C) and the beam (B) Strap-type fixing device 400 consisting of a horizontal surface 420 integrally formed at the upper end of the inclined surface 410 and the upper surface of the inclined surface 410 and a vertical surface 430 vertically integrally formed at the lower end of the inclined surface 410. A steel plate 210 which is installed by welding, and is formed in a generally rectangular shape at an end of the outer side of the belt-shaped fixing device 400 and has a bolt hole 220 having a constant diameter; Reinforcing bar 230 fixed to a plurality of vertically installed at regular intervals on the steel plate 210; Earthquake-resistant reinforcement method using a seismic reinforcement device, characterized in that for installing the formulation fixing device 200 consisting of the inclined surface 240 formed so that the upper end of the steel plate 210 has a predetermined inclination upward. In the steel frame building (S) which consists of a pillar (C) and the beam (B), An upper and lower plates 100 and 110 formed of a right-angled triangular shape made of rubber material and spaced apart from each other by a corner portion formed by the pillars C and the beams B; The inner plate of the upper plate 100 or the lower plate 110 is composed of a thin plate steel plate 120 is attached to a plurality of narrow and long steel plates at regular intervals, the thin plate 120 is the upper plate 100 Alternatively, the seismic reinforcement device A1 is installed on the inner surface of the lower plate 110 in the transverse direction or the longitudinal direction, and the inclined surface 410 and the inclined surface having a constant inclination on the outside of the seismic reinforcement device A1 ( The column (C) and the beam (ring) of the belt-shaped fixing device 400 consisting of a horizontal surface 420 integrally formed at the upper end of the 410 and a vertical surface 430 integrally formed vertically at the lower end of the inclined surface 410. B) Seismic reinforcement method using a seismic reinforcement device characterized in that the welding by fixing to. In the building S consisting of the pillar C and the beam B, When the construction of the pillar (C) and beam (B) of the building is made of a rectangular triangle shape made of rubber material at the corner formed by the pillar (C) and the beam (B), the upper and lower spaces are arranged in a state spaced apart, Lower plates 100 and 110; A thin steel sheet 120 having a plurality of steel plates having a narrow width and a long length in a transverse direction or a longitudinal direction at regular intervals on an inner surface of the upper plate 100 or the lower plate 110; The upper plate 100 and the lower plate 110 purchase a seismic reinforcement device (A2) consisting of a fixed protrusion 130 is formed to protrude in a predetermined shape on the outside of the other two sides except for the hypotenuse, the pillar (C) and Earthquake-resistant reinforcement method using earthquake-resistant reinforcement device by installing and curing concrete in beam (B).

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