KR101472811B1 - Seismic Steel Open Frame method - Google Patents

Abstract

The present invention relates to a seismic retrofitting method using an opened frame of a steel plate, including the steps of: cleaning and repairing the surfaces of columns and beams of a building and the existing walls positioned between the columns and the beams; installing anchors to the surfaces of the columns and the beams and the existing walls positioned between the columns and the beams; mounting a mounting plate assembly of a lattice shape to the surfaces of the columns and the beams of a building and the existing walls positioned between the columns and the beams; placing non-shrink mortar between the surfaces of the columns and the beams of a building and the existing walls positioned between the columns and the beams, and the mounting plate assembly; finishing and painting the mounting plate assembly fixed to the building after the mounting plate assembly is cured and painted by anti-corrosion painting. The seismic retrofitting method is carried out by use of the mounting plate assembly formed in the lattice shape, without demolishing the existing window and damaging to the structure, and it is possible to shorten the construction period and minimize the construction costs.

Description

Steel frame open frame seismic reinforcement method {Seismic Steel Open Frame method}

The present invention relates to a steel plate open frame seismic reinforcement method, and more particularly, to a steel plate open frame seismic reinforcement method that can reinforce seismic performance of an existing building as well as a new building.

Generally, when designing buildings such as multi-family homes, buildings, and apartments, earthquake-resistant design that can withstand earthquakes is accompanied. This earthquake - resistant design has been revised since the application of the earthquake - related regulations in the 1990 Building Code, and the 2005 earthquake - related regulations were revised and strengthened.

However, since the seismic design regulations are applied to newly constructed buildings, buildings constructed prior to the introduction of seismic design regulations are designed and constructed without consideration of earthquake effects, And seismic performance can not be exhibited properly.

Unexpected earthquakes in these buildings are expected to lead to economic and social losses from reconstruction as well as direct damage from collapse and damage. Especially, in the case of the national important facilities, if the damage occurs, the economic and social loss of the whole country becomes enormous.

Therefore, the National Emergency Management Agency (NEMA) compiles the earthquake-related regulations stipulated in the Natural Disaster Countermeasures Law, establishes the earthquake disaster countermeasures law, seismically reinforces the national critical facilities to meet the seismic design standards, It is necessary to carry out various studies on seismic strengthening methods for existing buildings and facilities.

Unlike the seismic design method applied to newly constructed buildings, the seismic reinforcement method requires reinforcement to existing buildings or facilities. Therefore consideration of usability, consideration of economical efficiency, and consideration of construction property are required. Considering the specificity of existing buildings and facilities There is a need to choose an appropriate method.

As seismic reinforcement methods for existing buildings and facilities, there are methods of increasing stiffness, increasing ductility, or increasing both stiffness and ductility. The commonly adopted method is to increase the ductility. There is a method of reinforcing the cross-sectional area of the existing building or facility using the same member, and a method of covering the reinforcing material.

Here, a coating method for reinforcing the strength of a column or a beam by using a steel sheet as an example of a method of coating a stiffener is shown in Figs. 1A and 1B.

1, in a conventional coating method using a steel plate 200 as a reinforcing material, a steel plate 200 surrounding a column 100 (or beam) of a building is fixed to the column 100 by an anchor bolt 300, The space between the steel plate 200 and the column 100 is filled with an epoxy grout material 400.

However, in the conventional coating method using the steel plate 200 as a reinforcing material, the epoxy grout material 400 is filled between the column 100 and the steel plate 200, There is a problem that the temperature is rapidly lowered.

In addition, in the conventional coating method using the steel plate 200 as a reinforcing material, an anchor bolt 300 for fixing the steel plate 200 to the column 100 is projected to the outside, When the finishing work is performed, there is a problem that the area of the column is increased and the internal area of the building is reduced.

Korean Patent Publication No. 2010-0098708 Korean Patent Publication No. 2010-0098854

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to enhance seismic performance while minimizing damage to a structure without demolishing existing windows using a combination of plate- .

In addition, it is an object of the present invention to improve the appearance while minimizing the finishing work by applying a chemical anchor in fixing the mounting plate combination.

In order to accomplish the above object, there is provided a method of manufacturing a building, the method comprising the steps of: arranging a conventional wall positioned between a column of a building and a surface of the beam; An anchor installation step of installing an anchor on a wall existing between a column of the building and the surface of the beam after the base surface preparation step; A mounting plate fixing step of mounting a lattice-shaped mounting plate combination on a wall existing between the pillars of the building and the surface of the beam after the anchor installation step; Placing a non-shrinking mortar between the existing wall and the mounting plate combination located between and between the column and the beam of the building after the mounting plate securing step; And a finish painting step of applying a cushioning and anti-rust coating to a mounting plate combination fixed to a building after the mortar pouring step and then painting a combination of a mounting plate fixed to the building.

Further, the present invention is characterized in that a combination processing step is further included between the mounting plate fixing step and the mortar pouring step so as to prevent smooth coating and leakage of the mounting plate combination.

And an angle setting step of installing a pore angle between the existing wall and the combination of the mounting plate located between the surface of the column and the beam of the building after the mounting plate fixing step.

The mounting plate combination may further include upper and lower corner mounting plates mounted on upper and lower corner portions, a connecting mounting plate mounted between the upper and lower corner mounting plates, and a reinforcement plate .

The mounting plate combination may further include a lower corner mounting plate mounted on a lower corner portion, a back stiffening plate mounted on the upper portion of the lower corner mounting plate with an interval therebetween, and a connection mounting member mounted between the lower corner mounting plate and the back stiffening plate And a plate.

The mounting plate combination may include upper and lower corner mounting plates mounted on upper and lower corner portions, and a connecting mounting plate mounted between the upper and lower corner mounting plates.

According to the present invention, it is possible to reinforce the seismic performance while minimizing the damage of the structure without removing the existing window by using the mounting plate combination combined with the lattice shape, and to shorten the air and minimize the construction cost .

In addition, chemical anchors are applied to fix the mounting plate combination to minimize the finishing work while improving the aesthetic appearance, as well as reducing the construction cost and improving the efficiency of the internal space of the mounting plate and the space utilization .

1 is a plan view for explaining a coating method for reinforcing the strength of a column or a beam by using a steel plate as an example of a method of coating a stiffener.
2 is a sectional view for explaining a coating method for reinforcing the strength of a column or a beam using a steel plate as an example of a method of coating a stiffener.
3 is a sequential view showing a steel plate open frame seismic reinforcement method according to the present invention.
4 (a) and 4 (b) are sequential diagrams showing another embodiment of a steel plate open frame seismic reinforcement method according to the present invention.
5 to 7 are front views showing a mounting plate combination applied to the steel plate open frame seismic strengthening method according to the present invention.
8 to 10 are views showing an installation state according to a steel plate open frame seismic reinforcement method according to the present invention.

FIG. 3 is a sequence diagram showing a method for reinforcing a steel plate open frame seismic reinforcement according to the present invention. FIGS. 4 (a) and 4 (b) FIGS. 5 to 7 are front views showing a mounting plate combination applied to the steel plate open frame seismic strengthening method according to the present invention.

The steel plate open frame anti-seismic reinforcement method (S10) of the present invention comprises a base surface preparation step (S20) for arranging a surface, an anchor installation step (S30) for installing an anchor, a mounting plate fixing (Step S40), a mortar placing step S50 for placing a non-shrinkage mortar, and a finish painting step S60 for closing the mounting plate combination.

The ground surface preparation step (S20) is a step of arranging existing walls located between the pillars of the building and the surface of the beam.

That is, in the step of arranging the floor surface (S20), the floor plate and the beam surface of the building and the existing wall existing between the floor and the beam are subjected to crack repair and installation So that the problem of the city can be solved.

The anchor installation step S30 includes installing an anchor for installing and fixing the mounting plate combination 20 on the existing wall located between the pillars of the building and the surface of the beam through the base surface preparation step S20 to be.

In the present invention, a chemical anchor is applied to the anchor 30 constituting the mounting plate combination 20, and a non-protruding anchor and a protruding anchor are selectively used depending on environment, purpose, and the like.

That is, in the anchor installation step (S30), a non-protruding keel anchor and a protruded chemical anchor are selected on the existing wall between the pillars of the building and the surface of the beam, It is.

The mounting plate fixing step S40 is a step of mounting the lattice-like mounting plate combination 20 on the existing wall between the pillars of the building and the surface of the building after the anchor installation step S30.

That is, in the fixing step S40, the mounting plate combination 20 is attached to the cable anchor 30 fixed to the existing wall located between the pillars of the building and the surface of the beam through the anchor installation step S30 And the mounting plates 21-2, 21-4, 22, and 23 are fixedly mounted.

At this time, it is disclosed that the outer surfaces of the mounting plates 21-2, 21-4, 22, and 23 constituting the mounting plate combination 20 can improve the appearance through the interior through the exterior material.

In addition, the mounting plate combination 20 fixed to the existing wall positioned between the pillars of the building and the surface of the beam can be formed in various combinations. In the present invention, as shown in FIGS. 5 to 7 .

The mounting plate combination 20 shown in FIG. 5, which is illustrated in FIG. 5, includes upper and lower corner mounting plates 20 and 20 at upper and lower corner portions of a conventional wall positioned between the pillars and beam surfaces of the building, A connection mounting plate 22 is mounted between the upper and lower corner mounting plates 21-2 and 21-4 and the upper corner mounting plate 21- 4 is mounted on the upper portion of the stiffener plate 23.

At this time, the connection mounting plates 22 mounted between the upper and lower corner mounting plates 21-2 and 21-4 may be composed of a plurality of numbers, and the corner mounting plates 21-2 and 21-4 And is formed in a rectangular shape for smooth operation and fixing.

6 shows the lower corner mounting plate 21 at the upper and lower corner portions of the existing wall located between the pillars of the building and the surface of the building where the problem of crack repair and installation is solved 4 is mounted on the upper corner mounting plate 21-4 and a reinforcing plate 23 is mounted on the upper portion of the lower corner mounting plate 21-4 and connected between the lower corner mounting plate 21-4 and the reinforcing plate 23 And the plate 22 is mounted.

At this time, the connection mounting plates 22 mounted between the lower corner mounting plate 21-4 and the steel plate 23 may be composed of a plurality of numbers, and the corner mounting plates 21-2 and 21-4 And is formed in a rectangular shape for smooth operation and fixing.

The mounting plate combination 20 of FIG. 7 shown in FIG. 7 is mounted on upper and lower corners of the existing wall located between the pillars and beam surfaces of the building where the problem of crack repair and installation is solved, Plates 21-2 and 21-4 are mounted and a connecting mounting plate 22 is mounted between the upper and lower corner mounting plates 21-2 and 21-4.

At this time, the connection mounting plates 22 mounted between the upper and lower corner mounting plates 21-2 and 21-4 may be composed of a plurality of numbers, and the corner mounting plates 21-2 and 21-4 And is formed in a rectangular shape for smooth operation and fixing.

In addition, after the mounting plate fixing step S40, it is possible to further include a combining processing step S70 as shown in FIG. 4 (a) so as to prevent smooth coating and leakage of the mounting plate combination 20 .

In other words, the combined processing step S70 may include removing the scratch on the mounting plate combination 20 after the mounting plate fixing step S40, smoothing the surface to be painted, A sealing process S74 for preventing leakage to the connecting portions of the mounting plates 21-2, 21-4, 22, and 23 constituting the mounting plate combination 20 So that the mounting plate combination 20 can be smoothly installed.

In addition, after the mounting plate fixing step S40, an angle installing step S80 for installing the porous angle 40 between the existing wall and the mounting plate combination 20 located between and between the column and the surface of the building . ≪ / RTI >

That is, the angle installation step S80 may be performed in such a manner as to improve the seismic performance after the mounting plate fixing step S40, as shown in Figs. 4 (b) and 10, And the mounting plate combination 20 are spaced apart from each other.

The mortar placing step S50 is a step of placing the non-shrinkage mortar 50 between the existing wall and the mounting plate combination 20 located between the pillars of the building and the surface of the beam after the mounting plate fixing step S40 .

That is, the mortar pouring step S50 is performed between the existing wall and the mounting plate combination 20 located between the pillars of the building and the surface of the building as shown in FIGS. 7 to 10, So that the mounting plate combination 20 can be fixed separately from the anchor 30.

Herein, the non-shrinkage mortar (50) is constructed by selecting one of the known non-shrinkage mortars having high strength and high strength and no shrinkage mortar, and a detailed description thereof will be omitted.

The finishing coating step S60 is a step of finishing the mounting plate combination 20 mounted on the existing wall positioned between the pillars of the building and the surface of the building and placing the mortar S50.

The finish painting step S60 includes a curing process (S62) for curing and curing the mounting plate combination 20 to be fixed to the building, and a coating process (S64) for coating the mounting plate combination 20 .

That is, the finish painting step S60 is a step of coating the building board combination 20 on the building with curing and anticorrosion coating, and then painting the building board 20 in accordance with the environment and purpose.

The following description will be made with reference to an embodiment of the steel plate open frame seismic reinforcement method constructed as described above.

The problem of crack repair and installation is solved so that the mounting plate combination 20 composed of a plurality of mounting plates can be smoothly mounted on the existing wall located between the pillars of the building and the surface of the beam.

A non-protruding anchor 30 and a protruding anchor 30 are selectively mounted so that a mounting plate combination 20 can be installed and fixed to a conventional wall positioned between and between the column and the surface of the building.

Next, mounting plates (21-2, 21-4, 22-24) constituting the mounting plate combination (20) are fixed to the existing wall positioned between the pillars of the building and the surface of the beam and fixed to the wall by an anchor (30) 23, the mounting plate combination 20 removes scratches on the mounting plates 21-2, 21-4, 22, smoothes the surface to be painted, A sealing process is performed to prevent the leakage of the connection parts of the mounting plates 21-2, 21-4, 22 and 23 constituting the mounting plate combination 20 and the sanding process.

And a high strength non-shrinkage mortar 50 is laid between the existing wall and the mounting plate combination 20 located between the surface of the column and the beam of the building.

Next, after curing and rubbing the mounting plate combination 20 fixed to the existing wall positioned between the pillars of the building and the surface of the beam, the mounting plate combination 20 is painted according to the environment and purpose, The installation work of the open frame seismic reinforcement method is completed.

Here, it is found that the installation work procedure of the steel plate open frame seismic strengthening method can be performed differently from the above.

The steel frame open frame seismic reinforcement method installed in this way can improve the seismic performance by improving the strength, rigidity and ductility of the building while reducing the deformation of the existing structure due to the constraining effect of the inner steel plate when applied to existing buildings will be.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention. The present invention is not limited thereto.

S10: steel frame open frame seismic reinforcement method,
S20: Base Surface Cleanup Phase
S30: Anchor installation step,
S40: mounting plate fixing step,
S50: Mortar casting step,
S60: Finish painting step.

Claims (6)

A base surface cleaning step of arranging existing walls located between the pillars of the building and the surface of the beam;
An anchor installation step of installing an anchor on a wall existing between a column of the building and the surface of the beam after the base surface preparation step;
A mounting plate fixing step of mounting a lattice-shaped mounting plate combination on a wall existing between the pillars of the building and the surface of the beam after the anchor installation step;
Placing a non-shrinking mortar between the existing wall and the mounting plate combination located between and between the column and the beam of the building after the mounting plate securing step;
And a finish painting step of curing and rustproofing the mounting plate combination fixed to the building after the mortar pouring step and then coating the mounting plate combination fixed to the building,
Between the fixing step of the mounting plate and the step of putting the mortar, a combined product processing step to prevent smooth coating and leakage of the mounting plate combination; Wow
And an angle installation step of installing a pore angle between the existing wall and the combination of the mounting plate located between the surface of the column and the beam of the building after the mounting plate fixing step,
Wherein the mounting plate combination comprises upper and lower corner mounting plates mounted on upper and lower corner portions and a connecting mounting plate mounted between the upper and lower corner mounting plates. .
delete delete 2. The assembly of claim 1,
Wherein the upper corner mounting plate is provided with a reinforcement plate on the upper portion thereof. delete delete

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