KR101930268B1 - Seismic reinforcing method for wall of apartment structure - Google Patents

Abstract

The present invention relates to a seismic strengthening method for improving the seismic performance of a partition wall for an apartment structure, and more particularly, to a seismic strengthening method for improving the seismic performance of a partition wall of an apartment structure, (A) a step of providing a panel-shaped wall having a rectangular structure; (B) A steel structure body of H-shaped steel is disposed on the outer surface of the panel-shaped wall to form an outer side reinforcement, and a panel-shaped wall is inserted into and fixed to the inner side groove of the H- Increasing the internal force; (C) fixing a plurality of turnbuckles to the inner side end, the front side and the rear side of the steel structure made of the H-shaped steel, respectively; (D) supporting the front and rear portions of the panel-type wall by connecting and fixing the wire rope between the turnbuckles and increasing the strength against the vibration energy applied to the front and rear of the panel-type wall; (E) increasing the strength against vibration energy by providing a pulley rotatably installed at the four corners of the outer grooved portion of the H-shaped steel, which is the steel structure, by connecting a wire rope to the pulley so as to strengthen the coupling force between steel structures; (F) inserting a panel-type wall to which a steel structure as a result of step (E) is bonded, on an inner space formed between two columns and a bottom slab and an upper beam; (G) disposing a foam insulating material such as a rubber foam or a styrofoam foam on the front and back surfaces of the panel-shaped wall to which the steel structure is bonded, and fastening the same to the steel structure; (H) finishing the mortar with an outer surface on which the cushioning insulating material is disposed.
According to the present invention, by applying a method using a steel structure of an H-shaped steel, a turnbuckle, a wire rope, or the like to a wall forming the partition wall of an apartment structure, it is possible to provide a solid durability against the wall itself, It is possible to improve the seismic performance by exerting a shear force due to shear deformation corresponding to the vibration energy applied to the wall side at the time of occurrence, and it is possible to provide an endurance that can endure regardless of the direction of the seismic wave.

Description

[0001] SEISMIC REINFORCING METHOD FOR WALL OF APARTMENT STRUCTURE [0002] FIELD OF THE INVENTION [0003]

The present invention relates to a seismic strengthening method for a wall of an apartment structure, and more particularly, to an earthquake-proof reinforcement method for an earthquake-proof performance for securing and improving the seismic performance of a wall forming a partition wall of a residential area in an apartment structure And to an earthquake-proof reinforcement method for a wall of an apartment structure for improvement.

In general, apartment houses that are designed to live together with a large number of generations living together, are a type of apartment house. Recently, apartments have been constructed in various forms according to the development of modern industry, development of new materials, rescue systems and construction methods, Construction of apartments is increasing.

Especially, in the domestic housing industry, the construction of new high - rise apartments is continuously increasing.

In this way, the modern society is realizing the super high-rise of apartments based on the metropolitan and new cities, and it is urgently required to strengthen the responsiveness of apartment structures to external forces such as earthquakes.

Particularly, there is a problem in structural stability, such as failure to cope with the concentration of load on a wall in a partition wall of an apartment structure or the wall being unable to withstand a load. Conventionally, there is a method of applying a seismic reinforcement to a wall of a partition wall The reinforcement method using a reinforcing plate or a reinforcing material is mainly used.

Korean Patent Publication No. 10-2012-0042237 Korean Patent Publication No. 10-1587881 Korean Patent Registration No. 10-1522390

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide an improved seismic performance improvement structure capable of securing and improving seismic performance of a wall forming a partition wall of a residential area, And to provide an earthquake-proof reinforcement method for a wall of an apartment structure.

The present invention relates to a wall structure of an apartment structure for improving the seismic performance of an earthquake-proof reinforcement with an easy and strong structure against a wall forming a partition wall of an apartment structure by using a steel structure of an H-shaped steel, a turnbuckle, And an object of the present invention is to provide a seismic retrofitting method for use.

In order to achieve the above object, an earthquake-proof reinforcement method for a wall of an apartment structure for improving seismic performance according to the present invention comprises vertically arranging vertically A method of reinforcing an earthquake-proof reinforcement for an inner wall of a building, the method comprising: (A) providing a panel-shaped wall having a rectangular structure; (B) A steel structure body of H-shaped steel is disposed on the outer surface of the panel-shaped wall to form an outer side reinforcement, and a panel-shaped wall is inserted into and fixed to the inner side groove of the H- Increasing the internal force; (C) fixing a plurality of turnbuckles to the inner side end, the front side and the rear side of the steel structure made of the H-shaped steel, respectively; (D) supporting the front and rear portions of the panel-type wall by connecting and fixing the wire rope between the turnbuckles and increasing the strength against the vibration energy applied to the front and rear of the panel-type wall; (E) increasing the strength against vibration energy by providing a pulley rotatably installed at the four corners of the outer grooved portion of the H-shaped steel, which is the steel structure, by connecting a wire rope to the pulley so as to strengthen the coupling force between steel structures; (F) inserting a panel-type wall to which a steel structure as a result of step (E) is bonded, on an inner space formed between two columns and a bottom slab and an upper beam; (G) disposing a foam insulating material such as a rubber foam or a styrofoam foam on the front and back surfaces of the panel-shaped wall to which the steel structure is bonded, and fastening the same to the steel structure; (H) finishing the mortar with an outer surface on which the cushioning insulating material is disposed.

In the step (E), a wire rope is wound around the pulley, and a turnbuckle is disposed at a midway point between the pulley and the pulley, and both end portions of the wire rope are passed through a turnbuckle So that a tight clamping force and tension can be maintained between the wire ropes.

Here, the panel-shaped wall may be embedded with an anti-seismic reinforcement made of steel plate or durable material arranged in an X-shape in the inside thereof.

(I) installing an earthquake damper on the floor slab so as to attenuate the influence of seismic waves transmitted to the panel-shaped wall by dissipating and dispersing vibration energy due to shear deformation with respect to the seismic waves, A first damper portion of a box-like body having a structure of a steel plate and disposed on a lower side and having an upper open structure; A box-shaped body disposed on the upper side of the first damper unit and having a lower open structure, the second damper unit being located outside the first damper unit and being formed of a steel plate; The compression springs are disposed alternately so as to dissipate and disperse seismic energy due to shear deformation in the action of a seismic wave, or they are arranged in a form of weaving a metal wire so as to be elastically supported by the first damper unit and resiliently supporting the second damper unit. A truss shear deforming member having a configuration in which trusses are arranged in a cubic truss structure; And a gel-like viscous oil filled in the first damper portion having the truss shear deformable member therein.

According to the present invention, it is possible to secure and improve the seismic performance of a wall forming a partition wall in an apartment structure as a common house, and it is possible to realize an improvement in seismic performance.

The present invention not only provides durability through the use of a steel structure of H-shaped steel, turnbuckle, wire rope, etc., but also exhibits a shear force due to shear deformation corresponding to the vibration energy on the wall side in the event of an external shock caused by a seismic wave, It is possible to improve the performance and to obtain the usefulness to be able to exert the endurance regardless of the formation direction of the seismic waves.

FIG. 1 is a schematic process flow chart showing a seismic strengthening method for a wall of an apartment structure for improving seismic performance according to an embodiment of the present invention.
2 is a structural view illustrating an anti-seismic reinforcement method for a wall structure of an apartment structure for improving seismic performance according to an embodiment of the present invention.
3 is a schematic side cross-sectional view illustrating an anti-seismic method for walls of an apartment structure for improving seismic performance according to an embodiment of the present invention.
FIG. 4 and FIG. 5 are structural diagrams showing an installation structure of an anti-earthquake damper in an anti-seismic reinforcement method for a wall of an apartment structure for improving seismic performance according to an embodiment of the present invention.
6 is a structural view showing an anti-seismic steel structure of a panel-type wall in an anti-seismic reinforcement method for a wall of an apartment structure for improving seismic performance according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The present invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.

As shown in Figs. 1 to 3, in the method of reinforcing seismic reinforcement for walls of an apartment structure for improving seismic performance according to an embodiment of the present invention, a bottom slab 2 (S10), a steel structure coupling step (S20), a turnbuckle fixing engagement step (S10), and a bolt connection step (S10) are performed to reinforce the earthquake against the wall (10) vertically arranged vertically to the upper beam (Step S30), a wire rope connection step S40, a pulley installation and wire rope connection step S50, a wall installation step S60, a cushioning insulation placement step S70, and a mortar finishing step S80 .

At this time, the two pillars 1, the bottom slab 2 and the upper beam 3 for the wall 10 can be divided into any one of the RC type, the SRC type, and the combination of the S type and the SRC type It is preferable to use a concrete material and a reinforcing material so as to provide safety, durability and vibration resistance to the frame itself to be installed.

For this purpose, the concrete material preferably has a material strength of 25 to 40 MPa, more preferably 35 to 40 MPa.

In the case of the reinforcing material, the material strength of the reinforcing bar satisfies 450 to 600 MPa when the material strength is 13 mm or less, 600 to 800 MPa when the material has a diameter of 16 mm or more, more preferably 550 to 600 MPa when the diameter is 13 mm or less, Use one that satisfies 700 to 800 MPa.

The panel-type wall forming step S10 is for covering the space inside the vertical slab 2 from the vertically installed two columns 1 to the bottom slab 2 and the upper beam 3, And a step of providing the panel-type wall 10.

In this case, the panel-shaped wall 10 may be a partition wall instead of the bearing wall of the frame structure in an apartment structure, and may be a wall formed by using concrete instead of a masonry structure for brick or the like in the field.

Here, the panel-shaped wall 10 preferably has a material strength of 20 to 30 MPa so as to have an anti-vibration property against the material itself when it is formed into a concrete wall.

Here, as shown in FIG. 6, the panel-shaped wall 10 may be arranged in such a manner that a seismic stiffener 100 made of a steel plate or durable material arranged in an X-shape therein is embedded.

In the steel structure joining step S20, the steel structure 20 of the H-shaped steel is coupled to the outside of the panel-shaped wall 10 provided beforehand to cover the outer circumference of the panel-shaped wall 10, So that the strength can be increased by forming the side reinforcing portion.

At this time, the steel structure 20 is preferably formed of H-shaped steel, and the panel-shaped wall body 10 is inserted into and fixedly coupled to the inner side groove of the H-shaped steel. 10) and a supporting force against the surface of the substrate.

Here, the steel structures 20 may be welded to each other by welding or the like, and a bracket made of a steel structure or the like may be used for ease of engagement.

The turnbuckle fixing and coupling step S30 is a step in which a plurality of turnbuckles 30 are spaced apart and fixedly coupled to each other at the inner ends facing each other between steel structures 20 made of H-shaped steel.

At this time, the turnbuckles 30 are arranged in a two-row structure on the front and back sides of the steel structure 20, respectively, so that the wire ropes 40 can be connected to the front and rear sides, .

The wire rope connection step S40 is a step of connecting the wire rope 40 between the turnbutton 30 disposed on the front side and the back side using a plurality of turnbuckles 30 fixedly coupled to the steel structure 20 in a two- So that the front and back portions of the panel-type wall 10 can be supported through the wire rope 40 by fixing the connection and having a constant tension.

Here, by connecting the wire ropes 40, the shear force due to shear deformation can be imparted to the vibration energy applied to the front and rear of the panel-type wall 10 during an external impact such as a seismic wave, have.

The pulley installation and wire rope connection step S50 is a step of installing a pulley 50 on the four corner portions of the outer grooved portion of the steel structure 20 made of H-shaped steel joined to the edge of the panel- , And the wire rope (60) is wound around the pulleys (50) to strengthen the binding force between the steel structures (20).

At this time, a wire rope 60 is wound around the pulleys 50, and the turnbuckle 70 is disposed at a midway point between the pulley 50 and the pulley 50, It is preferable that the end portions are fixed to the turnbuckle 70 with respect to the rope 60 so that the tightening force between the wire ropes 60 can be maintained and a constant tension can be maintained to enhance the seismic performance.

The pulley 50 and the wire rope 60 provide fluidity while strengthening the coupling force between the steel structure 20 supporting the panel-type wall 10 and the steel structure 20 during external impact such as a seismic wave. To the steel structure 20 by providing a shearing force due to shear deformation to the vibration energy applied to the steel structure 20 and can support the installation state without being easily broken down.

The wall installation step S60 is a step of installing the panel-shaped wall body 10 to which the steel structure 20 is bonded until the step S50 is completed between the two pillars 1, the bottom slab 2, And is inserted and placed on the inner space formed in the step of FIG.

The step of arranging the cushioning insulation material (S70) may include a step of providing a cushioning function against the seismic waves on the side of the panel-shaped wall body 10 in which the steel structure 20 having the connection structure of the wire ropes 40 And a cushioning insulating material 80 for providing the cushioning material.

The cushioning and heat insulating material 80 is preferably disposed on the front and rear surfaces of the panel-shaped wall body 10 and can be formed of a rubber foam or a foamed foam. The cushioning and insulating material 80 is fastened to the wall 10 or the steel structure 20 It is preferable to fix it.

The mortar finishing step S80 is a step of finishing the mortar 90 by applying the mortar 90 to the outer surface of the cushioning heat insulating material 80 disposed on the front and back sides of the panel-shaped wall 10 to which the steel structure 20 is bonded.

In addition, vibration energy due to shear deformation of the floor slab (2) due to seismic waves is dissipated and dispersed at a location where the panel-type wall (10) is located, thereby attenuating the effect of the seismic wave transmitted to the panel- And an earthquake-proof damper installing step (S90) of installing an earthquake-proof damper (200) so that the earthquake-proof damper

The earthquake-proof damper 200 is installed on the lower surface of the panel-type wall 10 to exhibit a shear force. As shown in FIGS. 4 and 5, the damper 200 is a box- A first damper part 260 of the body and a box-like body disposed on the upper side of the first damper part 260 and having a lower open structure, the first damper part 260 being located outside the first damper part 260, 2 damper unit 270 and a second damper unit 270 disposed inside the first damper unit 260 to elastically support the second damper unit 270. The vibration energy is dissipated and dispersed by shear deformation in the action of a seismic wave A truss shear deforming member 280 arranged in a three-dimensional truss structure arranged in a crossing arrangement of compression springs or woven metal wires, a first damper unit 260 having the truss shear deformation member 280 therein, Gel form to be filled inside The viscous oil 290 of the first embodiment.

The first damper unit 260 and the second damper unit 270 protect the truss shear deformation member 280 and facilitate connection with the wall 10, (280) absorbs, extinguishes, disperses, and attenuates vibration energy due to shear deformation during operation of the seismic wave, and exerts a function of dissipating the vibration energy irrespective of the direction in which the seismic waves are formed. Is for protecting the truss shear deformation member 280 while absorbing and buffering the vibration energy generated by the support wave.

Accordingly, in the present invention, by applying the method using the steel structure of the H-shaped steel, the turnbuckle, the wire rope, etc. to the wall forming the partition wall of the apartment structure, it is possible to have a solid durability against the wall itself, It is possible to improve the seismic performance by exerting a shear force due to shear deformation in response to the vibration energy applied to the wall side in the event of an impact, and it is possible to provide an endurance that can endure regardless of the direction of the seismic waves.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. And the like can be made, and it will be within the technical scope of the present invention.

1: Column 2: Floor slab
3: upper beam 10: panel wall
20: steel structure 30, 70: turnbuckle
40,60: Wire rope 50: Pulley

Claims (4)

An earthquake-proof reinforcement method for a wall structure of an apartment structure for reinforcing an earthquake against a wall vertically arranged in a vertical direction between two pillars spaced apart from each other vertically to a floor slab and an upper beam,
(A) providing a panel-shaped wall having a rectangular structure;
(B) A steel structure body of H-shaped steel is disposed on the outer surface of the panel-shaped wall to form an outer side reinforcement, and a panel-shaped wall is inserted into and fixed to the inner side groove of the H- Increasing the internal force;
(C) fixing a plurality of turnbuckles to the inner side end, the front side and the rear side of the steel structure made of the H-shaped steel, respectively;
(D) supporting the front and rear portions of the panel-type wall by connecting and fixing the wire rope between the turnbuckles and increasing the strength against the vibration energy applied to the front and rear of the panel-type wall;
(E) increasing the strength against vibration energy by providing a pulley rotatably installed at the four corners of the outer grooved portion of the H-shaped steel, which is the steel structure, by connecting a wire rope to the pulley so as to strengthen the coupling force between steel structures;
(F) inserting a panel-type wall to which a steel structure as a result of step (E) is bonded, on an inner space formed between two columns and a bottom slab and an upper beam;
(G) disposing a foam insulating material such as a rubber foam or a styrofoam foam on the front and back surfaces of the panel-shaped wall to which the steel structure is bonded, and fastening the same to the steel structure;
(H) applying a mortar to the outer surface on which the cushioning insulation is disposed;
(I) disposing an earthquake damper in the floor slab so as to attenuate the influence of seismic waves transmitted to the panel-shaped wall by dissipating and dispersing vibration energy due to shear deformation with respect to seismic waves; / RTI >
The earthquake-
A first damper portion of a box-like body having a structure of a steel plate and disposed on the lower side and having an upper open structure; A box-shaped body disposed on the upper side of the first damper unit and having a lower open structure, the second damper unit being located outside the first damper unit and being formed of a steel plate; A compression spring is disposed in an alternate arrangement in a cubic truss structure so as to dissipate and disperse seismic energy due to shear deformation in the action of a seismic wave while being positioned inside the first damper portion so as to elastically support the second damper portion A truss shear deformable member having the truss shear deformable member; A viscous oil in gel form filled in the first damper portion having the truss shear deformable member therein; Wherein the seismic strengthening method for a wall of an apartment structure for improving seismic performance is provided. The method according to claim 1,
In the step (E)
The turnbuckle is disposed at the middle point between the pulley and the pulley, and the both ends are fixed to the turnbuckle with respect to the wire rope passing through any one of the pulleys, whereby the tightening force and the tension between the wire ropes Wherein said seismic strengthening method is a method for reinforcing seismic resistance of a wall structure of an apartment structure for improving seismic performance. delete delete

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