KR102157288B1 - Fixing module for seismic strengthening of masonry building and seismic strengthening method using it - Google Patents

Abstract

A seismic reinforcement method for masonry buildings that provides a fixed module that can be settled while applying a tensile force to the reinforcement, improves the seismic performance of the masonry building using this, and prevents partial dropout due to earthquakes, and facilitates construction by modularizing the reinforcement Is initiated.
The present invention provides a fixing module for seismic reinforcement of a masonry building, including a reinforcement member, a first fixing member fixing one end of the stiffener, and a second fixing member fixing the opposite end of the stiffener.

Description

Fixing module for seismic strengthening of masonry building and seismic strengthening method using it}

The present invention relates to a fixed module for seismic reinforcement of a masonry building and a seismic reinforcement method using the same.

Existing structural or non-structural masonry or ALC blocks integrate each block with mortar and other adhesives to transmit vertical loads and form an external exterior material and internal space, but these structures respond to lateral displacement and vibration of the structure due to earthquakes. It is difficult to do, and in general, vertical reinforcing bars are inserted into holes in the block or auxiliary hardware is attached to the outside in order to reinforce lateral resistance, but there is a high possibility of conduction by earthquakes because the rebar is not fixed in the structure. There is a disadvantage that it is difficult to effectively respond to lateral displacement because it is not integrated with

Related technologies are described in Korean Patent Application Publication No. 10-2012-0114080 and Korean Patent Registration No. 10-1079318.

However, in the case of Korean Patent Laid-Open No. 10-2012-0114080 and Korean Patent No. 10-1079318, the seismic performance of the structure is improved and partial drop-out is prevented, and the reinforcing material is modularized by using a fixing device that fixes the reinforcement while applying a tensile force. Therefore, a reinforcement technology that is easy to install is not disclosed, and a technology that allows the reinforcement material and the masonry wall to be in close contact without forming a hole in the masonry wall as in the present invention, and to adjust the number of installations of reinforcing materials and fixing devices suitable for the reinforcing area is introduced. Not doing.

An object of the present invention is to provide a fixed module for seismic reinforcement of a masonry building, which can improve seismic performance of a masonry building and prevent partial dropout due to an earthquake, and is easy to construct, and a seismic reinforcement method using the same.

In order to solve the above problems, the present invention provides a fixing module for seismic reinforcement of a masonry building comprising a stiffener, a first fixing member for fixing one end of the stiffener, and a second fixing member fixing the opposite end of the stiffener. to provide.

Alternatively, the reinforcing material may be a fixed module for seismic reinforcement of a masonry building, characterized in that at least one selected from the group consisting of glass fiber, carbon fiber, and aramid fiber.

Alternatively, each of the fixing members may be made of facing plates, and the facing plates may be a fixing module for seismic reinforcement of a masonry building, characterized in that they can be compressed.

Alternatively, each of the fixing members is made of a plate facing each other, the facing plate can be compressed with a bolt and a nut, and a fixing module for seismic reinforcement of a masonry building, characterized in that the facing surface of the plate is roughened. Can be

Alternatively, each of the fixing members is made of a plate facing each other, the facing plate may be compressed with a bolt and a nut, and an adhesive composition is applied to the facing surface of the plate. It may be a fixed module for.

Alternatively, each of the fixing members may be made of one plate, and the reinforcement may be a fixing module for seismic reinforcement of a masonry building, characterized in that the reinforcement is wound around the fixing member.

On the other hand, as another means for solving the above problems, the present invention provides a bracket installation step of installing brackets on the upper and lower beams of the masonry tank, the fixing module insertion step of inserting the fixing module of claims 1 to 6 into the bracket, and the bracket. It provides a seismic reinforcement method for a masonry building including a fixed module pressure step of applying pressure to the fixed module inserted in the upper or lower beam direction.

Alternatively, the bracket is a masonry building, characterized in that the bracket is fixed to the upper and lower beams by fixing bolts, and a support part that is in close contact with the upper or lower beam of the masonry tank, and a fixed module insertion part that is bent at one end of the support part to form an extension. It may be a seismic reinforcement method of

Alternatively, before the fixing module pressure step, it may be a seismic reinforcement method of a masonry building, further comprising a step of connecting one fixing member of the fixing module and the fixing member opposite of the adjacent fixing module with a wire rope.

Alternatively, the fixing module pressure step is to apply pressure to the fixing module inserted into the bracket by tightening the fixing bolts for fixing the bracket to the upper beam or the lower beam, and attaching the bracket to the upper or lower beam. It may be a reinforcement method.

Alternatively, the bracket is fixed to the upper and lower beams by fixing bolts, a support part that is in close contact with the upper or lower beams of the masonry tank, a fixed module insertion part formed extending by bending at one end of the support part, and one end of the fixed module insertion part It may be a seismic reinforcement method of a masonry building, characterized in that it consists of a pressure bolt installation portion bent and extended in

Alternatively, it may be a seismic reinforcement method for a masonry building, characterized in that pressure is applied to the fixed module by inserting a pressure bolt into the pressure bolt installation part and tightening the pressure bolt.

The present invention improves the seismic performance of a masonry building by using a fixing device that can be fixed while applying a tensile force to the reinforcing material, and prevents partial dropout due to earthquake. Can provide.

1 is a view showing a process of inserting a fixing module into a bracket.
2 is a view showing a state in which the insertion of the fixing module is completed in the bracket installed on the lower beam.
3 is a plan view of FIG. 2.
4 is a conceptual diagram illustrating a principle of applying a torque to a fixing bolt to apply a tensile force to a reinforcing material and a wire rope.
5 is a view showing a plate facing the fixing member.
6 is a front view and a side view of the fixing module installed in the masonry tank.
7 is a front view showing a process of inserting a fixing module into a bracket equipped with a pressure bolt.
8 is a conceptual diagram illustrating a principle of applying a torque to a pressure bolt to apply a tensile force to a reinforcing material and a wire rope.

In describing the present invention, when it is determined that a detailed description of a related known technology may obscure the subject matter of the present invention, a detailed description thereof will be omitted. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are assigned to similar parts throughout the specification, and detailed configuration directions of the present invention will be described with reference to the drawings. In addition, throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated.

The present invention provides a fixing module for seismic reinforcement of a masonry building comprising a reinforcement member, a first fixing member fixing one end of the stiffener, and a second fixing member fixing the opposite end of the stiffener. Installation becomes easy by providing a fixed module.

The reinforcing material may be a material having stiffness and flexibility capable of withstanding vertical and lateral loads during an earthquake, and preferably at least one selected from the group consisting of glass fiber, carbon fiber, and aramid fiber.

Each of the fixing members may be a fixing module for seismic reinforcement of a masonry tank, characterized in that the fixing member is made of two facing plates, and the facing plates are crimped. The reason why each fixing member is composed of two facing plates is that after inserting the reinforcing material between the facing plates, the facing plate can be crimped with a pressing member such as a bolt and a nut to be fixed to the fixing member.

Further, each surface of the facing plate may be roughened, or an adhesive composition may be applied to each surface of the facing plate. The reinforcement is strongly adsorbed to the fixing plate so that it does not fall out of the fixing member even in an impact such as an earthquake.

As a method of fixing the reinforcing member to the fixing member, the reinforcing member is wound around a fixing member made of a single plate to form a belt or chain-like shape, and the reinforcing agent portion in contact with the fixing member may be fixed with nails or adhesives.

On the other hand, as another means for solving the above problems, the present invention provides a bracket installation step of installing brackets on the upper and lower beams of the masonry tank, a fixing module insertion step of inserting the fixing module into the bracket, and a fixing module inserted into the bracket. It provides a seismic reinforcement method for a masonry building including a fixed module pressure step of applying pressure in the direction of an upper beam or a lower beam. By applying pressure to the fixed module inserted in the bracket in the direction of the upper or lower beam, the tensile force of the reinforcement is increased, so that it can withstand lateral and vertical loads such as earthquakes.

In addition, before the fixing module pressure step, further comprising a step of connecting one fixing member of the fixing module and the fixing member opposite to the adjacent fixing module with a wire rope, it is possible to better withstand the lateral load.

The fixed module pressure level can be selected from two types.

First, the bracket is fixed to the upper and lower beams by fixing bolts, and consists of a support part that is in close contact with the upper or lower beam of the masonry tank, and a fixed module insertion part that is bent and extended at one end of the support part. It may be a method of applying pressure to the fixing module inserted into the bracket by tightening the fixing for fixing the bracket to the beam and attaching the bracket to the upper or lower beam.

Second, the bracket is fixed to the upper and lower beams by anchors, a support part that is in close contact with the upper or lower beams of the masonry tank, a fixed module insertion part bent and extended at one end of the support part, and one end of the fixed module insertion part. It may be a method of applying pressure to the fixed module by fastening the pressure bolt by inserting the pressure bolt into the pressure bolt installation part and inserting the pressure bolt into the pressure bolt installation part.

Two methods can be selectively applied in consideration of site conditions.

First, the first method allows a maximum of 10 cm of clearance even if the height measurement of the reinforced wall is incorrect. If necessary, the fixing member and the upper or lower beam may be stabilized with grouting or steel support.

The second side method can be applied when the height of the wall is measured with an error of 2 cm, and there is no need for additional grouting or stabilization by steel support.

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

1 is a view showing a process of inserting a fixing module into a bracket 4 according to an embodiment of the present invention.

In addition to inserting the fixing module in which the reinforcing material 1 is installed into the bracket 4 as necessary, the reinforcing bracket 6 may also be provided on the upper beam or the lower beam to improve the stability of the fixing module.

FIG. 2 is a view showing a state in which the fixing module is inserted into the bracket 4 installed on the lower beam, and FIG. 3 is a plan view of FIG. 2.

The bracket 4 is fixed to the upper or lower beam such as a slab or frame beam using a chemical anchor or fixing bolt 5. In addition, the wire rope insertion hole 8 is formed on one side of the fixing member 2.

4 is a conceptual diagram illustrating the principle of applying a torque to the fixing bolt 5 to apply a tensile force to the reinforcing material 1 and the wire rope 8. By applying a torque to the fixing bolt 5 and tightening it, the fixing bolt 5 enters the beam and the fixing member receives force toward the beam.

When pressure is applied by the method of FIG. 4, a maximum allowance of about 10 cm is allowed even if the height measurement of the reinforcement target wall is incorrect. If necessary, the fixing member and the upper or lower beam may be stabilized with grouting or steel support.

5 is a view showing the plates 201 and 202 facing each other of the fixing member 2.

It is shown that the gap between the facing plates 201 and 202 can be narrowed and compressed through bolts, washers and nuts installed on the plates 201 and 202.

6 is a front view and a side view of the fixing module installed in the masonry tank.

A total of six fixing modules were installed on both sides of the masonry tank, and one fixing member (2) of the fixing module and the fixing member (2) on the opposite side of the adjacent fixing module were connected with a wire rope. In the present invention, as in the case of FIG. 6, the number of fixed modules may be selected according to the level of seismic performance requirements. In addition, it is designed to add resistance in the diagonal direction by adding a wire rope in the oblique direction if necessary. In addition, the reinforcement material prevents the masonry material from falling off, and the wire rope has a mechanical mechanism that mainly resists lateral load.

7 is a front view showing a process of inserting a fixing module into a bracket equipped with a pressure bolt. The pressure bolt is applied to the fixed module by inserting the pressure bolt into the pressure bolt installation portion that is bent at one end of the fixed module insertion portion and formed to extend.

8 is a conceptual diagram illustrating a principle of applying a torque to a pressure bolt to apply a tensile force to a reinforcing material and a wire rope.

When pressure is applied by the method of FIG. 8, it can be applied when the height of the wall is measured with an error of 2 cm, and no additional grouting or stabilizing action by a steel support is required.

Referring to the following, the fiber net and the wire rope are integrated by being bitten by a fixing device. The fixing device is fixed using a chemical anchor or fixing bolt fixed to a slab or frame beam. The fiber net prevents the masonry from falling off, and the wire rope mainly has a mechanical mechanism that resists lateral load. The reinforcing materials that serve these two roles are manufactured as a single module in the factory, and since the work of installing the module after installing the anchor is performed only on the site, it can be easily constructed.

In the above, preferred embodiments of the present invention have been described in detail with reference to the drawings. The description of the present invention is for illustrative purposes only, and a person of ordinary skill in the art to which the present invention pertains will be able to understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention.

Accordingly, the scope of the present invention is indicated by the claims to be described later rather than the description of the invention, and all changes or modified forms derived from the meaning, scope and equivalent concepts of the claims are interpreted as being included in the scope of the present invention. Should be.

1: reinforcement
2: fixing member 21: first fixing member 22: second fixing member
201, 202: fixing plate
3: wire rope
4: Bracket 41: Support 42: Fixed module insertion part
5: Fixing bolt 6: Reinforcement bracket
7: Fixed plate compression bolt, nut, washer
8: wire rope insertion port
9: pressure bolt
10: pressure bolt installation part

Claims (12)

Bracket installation step of installing brackets on the upper and lower beams of the masonry tank;
A fixing module insertion step of inserting a fixing module into the bracket; And
A fixed module pressure step of applying pressure in a direction of an upper beam or a lower beam to the fixed module inserted into the bracket;
As a seismic reinforcement method of a masonry building including,
The fixing module is a reinforcing material; A first fixing member fixing one end of the reinforcing member; And a second fixing member for fixing the opposite end portion of the reinforcing member,
Each of the fixing members is made of a plate facing each other, the facing plate can be compressed with a bolt and a nut, the facing surface of the plate is formed roughly,
Before the fixing module pressure step, further comprising the step of connecting the first fixing member and the second fixing member by a wire rope,
The bracket includes a support portion fixed to the upper and lower beams by fixing bolts; A fixed module insertion portion bent and extended at one end of the support portion; And a pressure bolt installation part bent at one end of the fixing module insertion part to form an extension. The method of claim 1,
The reinforcing material is a seismic reinforcement method of a masonry building, characterized in that at least one selected from the group consisting of glass fiber, carbon fiber and aramid fiber. delete delete The method of claim 1,
Seismic reinforcement method of a masonry building, characterized in that the adhesive composition is applied to the opposite side of the plate. The method of claim 1,
Each of the fixing members is made of one plate, the reinforcing material is a seismic reinforcement method of a masonry building, characterized in that wound around the fixing member.

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