KR102178265B1 - Seismic reinforcement device and method of existing concrete wall - Google Patents

Abstract

The present invention relates to a seismic reinforcement device for an existing concrete wall and a seismic reinforcement method thereof, which can additionally impart seismic performance to an existing concrete wall having low seismic performance. A seismic reinforcement device for an existing concrete wall according to a first embodiment of the present invention comprises: a plate-shaped steel flat bar (10) having a fastening hole (11) formed on the surface thereof; an anchor (20) which is inserted into the existing concrete wall along the fastening hole of the steel flat bar (10) to fix the steel flat bar (10); a carabiner (30) installed at the end of the anchor (20) fixing the steel flat bar (10); a side support (40) for fixing both ends of the steel flat bar (10) positioned vertically or horizontally; a wire rope (50) which has one end fixed to the carabiner (30) exposed to the outside of the outermost steel flat bar (10) on one side, passes through carabiners of the adjacent steel flat bars (10), and has the other end fixed to the carabiner (30) exposed to the outside of the outermost steel flat bar (10) on the other side; and a turnbuckle (60) connected to the end of the wire rope (50) and the outermost carabiner (30) to maintain the tension of the wire rope (50) above a predetermined level.

Description

Seismic reinforcement device and method of existing concrete wall}

The present invention relates to a seismic reinforcement device and a seismic reinforcement method for an existing concrete wall that can additionally impart seismic performance to an existing concrete wall having low seismic performance.

According to the current building law, seismic design is required to withstand an earthquake of 5.5 to 6.5 on the Richter scale if it is more than 3 stories or 1,000 m2, but the seismic design was not reflected in the previous buildings.

On the other hand, most buildings in Korea are ramen-type structures supported by columns and beams, and most of the walls are composed of masonry walls, which are non-bearing walls. Therefore, in order to improve the seismic performance, the method of replacing the non-bearing wall with a bearing wall that can withstand external forces is a more effective method than the method of expanding or reinforcing the cross section of a column or beam member. to be.

However, the existing technology of replacing the non-bearing wall with the bearing wall has to remove the existing wall, so it is not eco-friendly because a large amount of construction waste is generated during the construction process, and there is a high possibility that the construction period may be delayed due to the demolition process.

Registered Patent No. 10-1089322 (2011.11.28.)

The problem to be solved by the present invention is to provide a seismic reinforcement method and seismic reinforcement of an existing concrete wall capable of additionally imparting seismic performance to an existing concrete wall having low seismic performance.

Another problem of the present invention is the seismic reinforcement device and the seismic reinforcement method of the existing concrete wall in a dry method without using reinforcing concrete or a wet method using reinforcing concrete depending on the location of the existing concrete wall with low seismic performance. To provide.

A seismic reinforcement device for an existing concrete wall according to a first embodiment of the present invention includes a flat iron 10 having a fastening hole 11 formed on the surface in a plate shape; Anchor 20 which is inserted into the existing concrete wall along the fastening hole of the pyeongcheol 10 to fix the pyeongcheol 10; A binner 30 installed at the end of the anchor 20 for fixing the pyeongcheol 10; A side support 40 for fixing both ends of the pyeongcheol 10 positioned vertically or horizontally; After one end is fixed to the binner 30 exposed to the outside of the outermost pyeongcheol 10 and passed through the burner of the neighboring pyeongcheol 10, the other end is exposed to the outside of the pyeongcheol 10 on the other side. ) And a wire rope 50 fixed to; And a turnbuckle 60 connected to the end of the wire rope 50 and the outermost binner 30 to maintain the tension of the wire rope 50 above a certain level.

The seismic reinforcement method of the existing concrete wall according to the first embodiment of the present invention includes the steps of exposing the surface of the existing concrete wall 1; Attaching a plurality of flat irons (10) having fastening holes (11) formed on the surface in a plate shape at regular intervals vertically or horizontally using an anchor (20) to an existing concrete wall (1); Installing a binner 30 at the end of the anchor 20 to which the flat iron 10 is attached; Fixing and integrating both ends of the pyeongcheol (10) vertically or horizontally positioned on the side support (40); After fixing one end of the wire rope 50 to the binner 30 exposed to the outside of the flat iron 10 on one side and passing the burner of the neighboring flat iron 10, the other end of the wire rope 50 is connected to the other outermost. It characterized in that it comprises a; step of fixing the binner 30 exposed to the outside of the pyeongcheol 10.

A seismic reinforcement device for an existing concrete wall according to a second embodiment of the present invention includes a flat iron 10 having a fastening hole 11 formed on the surface in a plate shape; Anchor 20 which is inserted into the existing concrete wall along the fastening hole of the pyeongcheol 10 to fix the pyeongcheol 10; A binner 30 installed at the end of the anchor 20 for fixing the pyeongcheol 10; A side support 40 for fixing both ends of the pyeongcheol 10 positioned vertically or horizontally; After one end is fixed to the binner 30 exposed to the outside of the outermost pyeongcheol 10 and passed through the burner of the neighboring pyeongcheol 10, the other end is exposed to the outside of the pyeongcheol 10 on the other side. ) A wire rope 50 fixed to; and; A horizontal support 70 fixed to the binner 30 exposed to the outside of the fastening hole 11 at both ends in a'C' shape; A vertical support 80 fixed to the horizontal support 70 with a straight reinforcing bar; The outer cover 90 fixed to the side support 40 on one side fixed to both ends of the flat iron 10 while being formed in a plate shape of'C' and surrounding the horizontal support 70 and the vertical support 80 Wow; Pyeongcheol (10), anchor (20), binner (30), side support (40), wire rope (50), turnbuckle (60), horizontal support (70), vertical support (80), outer cover ( When 90) is installed, reinforcing concrete 100 is poured into the interior of the outer cover 90; characterized in that it includes.

In addition, the seismic reinforcement method of the existing concrete wall according to the second embodiment of the present invention includes the steps of exposing the surface of the existing concrete wall (1); Attaching a plurality of flat irons (10) having fastening holes (11) formed on the surface in a plate shape at regular intervals vertically or horizontally using an anchor (20) to an existing concrete wall (1); Installing a binner 30 at the end of the anchor 20 to which the flat iron 10 is attached; Fixing and integrating both ends of the pyeongcheol (10) vertically or horizontally positioned on the side support (40); After fixing one end of the wire rope 50 to the binner 30 exposed to the outside of the flat iron 10 on one side and passing the burner of the neighboring flat iron 10, the other end of the wire rope 50 is connected to the other outermost. Fixing the binner 30 exposed to the outside of the pyeongcheol 10; Connecting the outermost binner 30 and the wire rope 50 with a turnbuckle 60 to fix the wire rope 50 to maintain tension; Fixing both ends of the horizontal support 70 of the'C' shape to the ends of the anchors 20 exposed to the outside of the fastening hole 11; A step of vertically fixing the vertical support 80, which is a straight reinforcing bar, to the horizontal support 70; Installing both ends of the outer cover 90 of the'C' shape to surround the horizontal support 70 at both ends of the pyeongcheol 10 attached to the existing concrete wall 1; It characterized in that it comprises a; step of pouring the concrete 100 for reinforcement inside the outer cover (90).

According to the present invention, there is an effect of improving seismic performance by selectively using a dry method that does not use reinforcement concrete or a wet method that uses reinforcement concrete according to the location and strength of the existing concrete wall.

1 is an exploded perspective view of a seismic reinforcement device for an existing concrete wall according to a first embodiment.
Figure 2 is an assembly state diagram of Figure 1;
Figure 3 is an installation state diagram of Figure 1;
4 is an exploded perspective view of a seismic reinforcement device for an existing concrete wall according to a second embodiment.
Figure 5 is an installation state diagram of Figure 4;
Figure 6 is another installation state of Figure 5.

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

As shown in Figures 1 to 3, the seismic reinforcement device of the existing concrete wall according to the first embodiment of the present invention is flat iron 10, anchor 20, binner 30, side support 40, wire It includes a rope 50 and a turnbuckle 60. The seismic reinforcement device of the first embodiment can perform seismic reinforcement on an existing concrete wall in a dry manner without using concrete.

The flat iron 10 has a plate shape and a fastening hole 11 is formed on the surface thereof. These pyeongcheol (10) is installed in the vertical or horizontal direction of the existing concrete wall (1) in a plurality at regular intervals on the existing concrete wall (1) exposed to the outside. This pyeongcheol 10 is able to prevent damage to the existing concrete wall to which the anchor 20 is attached.

The anchor 20 is inserted into an existing concrete wall along the fastening hole of the pyeongcheol 10 to fix the pyeongcheol 10. At this time, the anchor 20 is preferably a set anchor.

The binner 30 is installed at the end of the anchor 20 fixing the pyeongcheol 10. The binner 30 is formed in a circular shape so that the wire rope 50 to be described later can be easily installed.

The side support 40 is integrated by fixing both ends of the pyeongcheol 10 positioned vertically or horizontally. At this time, the side support 40 is preferably fixed to both ends of the flat iron 10 by welding with a straight reinforcing bar or a'b'-shaped steel plate. Even if a plurality of pyeongcheol 10 is fixed to the existing concrete wall by such side support 40, it is integrated and can withstand external force.

The wire rope 50 has one end fixed to the binner 30 exposed to the outside of the outermost flat iron 10 and passed through the burner of the neighboring flat iron 10, and then the other end is outside the outermost flat iron 10 on the other side. It is fixed to the exposed binner 30. At this time, the wire rope 50 is preferably installed in a'X' shape between the neighboring binners 30.

The turnbuckle 60 is connected to the end of the wire rope 50 and the outermost binner 30 to maintain the tension of the wire rope 50 above a certain level. Accordingly, it is possible to increase the tensile force and compression force of the wire rope 50 connected to the turnbuckle 60.

A seismic reinforcement method (dry reinforcement method) using the seismic reinforcement device for an existing concrete wall according to the first embodiment of the present invention will be described. The reinforcing method of the existing concrete wall according to the first embodiment of the present invention includes an existing concrete surface exposure step, a flat iron attachment step, a binner installation step, a side support fixing step, a wire rope installation step (S50), and a wire rope tension maintenance step. do.

In the step of exposing the existing concrete surface, the masonry wall, insulation, or painting material that has been accumulated on the outside of the existing concrete wall 1 is removed so that the surface of the existing concrete wall 1 is exposed. In this way, by exposing the surface of the existing concrete wall 1 to remove external foreign substances, it is possible to improve the adhesion performance with concrete to be poured for seismic reinforcement later. At this time, in the exposing step of the existing concrete surface (S10), it is preferable to further improve the adhesion performance by removing foreign substances, etc. on the existing concrete surface exposed to the outside and forming scratches or irregularities.

In the step of attaching pyeongcheol, a plurality of pyeongcheol 10 having the fastening hole 11 formed on the surface in the shape of a plate are attached to the existing concrete wall 1 at regular intervals vertically or horizontally using an anchor 20. At this time, the fastening holes 11 are formed at both ends of the flat iron 10, and the anchor 20 is preferably a set anchor 20. This pyeongcheol 10 is able to prevent damage to the existing concrete wall to which the anchor 20 is attached.

In the step of installing the binner, the binner 30 is installed at the end of the anchor 20 to which the flat iron 10 is attached. The binner 30 is formed in a circular shape so that the wire rope 50 to be described later can be easily installed.

In the step of fixing the side support, the both ends of the flat iron 10 positioned vertically or horizontally are integrated with the straight reinforcing bar or'b' shape side support 40. At this time, the side support 40 is preferably fixed to both ends of the flat iron 10 by welding. Even if a plurality of pyeongcheol 10 is fixed to the existing concrete wall by such side support 40, it is integrated and can withstand external force.

In the wire rope installation step, one end of the wire rope 50 is fixed to the binner 30 exposed to the outside of the outermost flat iron 10 and passed through the burner of the neighboring flat iron 10. The other end is fixed to the binner 30 exposed to the outside of the flat iron 10 at the outermost side of the other side. At this time, the wire rope 50 is preferably installed in a'X' shape on the neighboring pyeongcheol 10.

In the wire rope tension maintenance step, the outermost binner 30 and the wire rope 50 are connected with a turnbuckle 60 so that the tension of the wire rope 50 is maintained. By increasing the tensile force and compression force of the entire wire rope 50 by the turnbuckle 60, it is possible to reinforce the existing concrete wall.

According to the seismic reinforcement method of the existing concrete wall according to the first embodiment of the present invention, it is possible to improve the seismic resistance of the existing concrete wall even by a dry method that does not use reinforcing concrete.

On the other hand, as shown in Figures 4 to 6, the seismic reinforcing device of the existing concrete wall according to the second embodiment of the present invention is flat iron 10, anchor 20, binner 30, side support 40 , A wire rope 50, a turnbuckle 60, a horizontal support 70, a vertical support 80, an outer cover 90, and reinforcement concrete 100. Here, since the flat iron 10, the anchor 20, the binner 30, the side support 40, the wire rope 50, and the turnbuckle 60 are the same as in the first embodiment, a description thereof will be omitted. The seismic reinforcement device of the second embodiment can perform seismic reinforcement on an existing concrete wall in a wet manner using concrete.

The horizontal support 70 is fixed to the binner 30 exposed to the outside of the fastening hole 11 with both ends of the'C'-type reinforcing bar (10mm reinforcing bar). At this time, it is preferable to fix the horizontal support 70 to the binner 30 by welding. This horizontal support 70 is installed along the flat iron 10 to impart horizontal strength when the reinforcing concrete 100 is poured.

The vertical support 80 is fixed to the horizontal support 70 with a straight reinforcement (19mm reinforcement). At this time, the vertical support 80 is installed on the horizontal support 70 by welding or fixed with a wire. In particular, it is preferable that the vertical support 80 is installed so as to be in close contact with the inner surface of the corner in the horizontal support 70 of the'C' shape. Since the vertical support 80 is integrally fixed with the horizontal support 70, it is possible to prevent the horizontal support 70 from moving and maintain the vertical strength when the reinforcing concrete 100 is poured.

The outer cover (90) is formed in the shape of a'c' and is fixed to the side support (40) of one side fixed to both ends of the pyeongcheol (10) while surrounding the horizontal support (70) and the vertical support (80) do. At this time, the outer cover 90 may be a steel plate or a formwork. In the case of a steel plate, it may be fixed to both ends of the flat iron 10 by welding. In addition, the outer cover 90 may be installed to cover all of the pyeongcheol (10) is installed in a plurality of horizontal and vertical direction at regular intervals.

Reinforcing concrete 100 is a flat iron (10), anchor (20), binner (30), side support (40), wire rope (50), turnbuckle (60), horizontal support (70), vertical support to existing concrete (80), when the outer cover 90 is installed, it is poured into the inside of the outer cover 90. The poured reinforcement concrete 100 is prevented from being separated by being integrated with the existing concrete by the flat iron 10, and the flat iron 10, the horizontal support 70, the vertical support 80 of the reinforcing concrete 100 Since the strength can be maintained above a certain level, the seismic strength can be improved.

On the other hand, the present invention may further include a connection support 110 fixed to the horizontal support 70 adjacent to each other with a straight reinforcement. In the case of using such a connection support 110, if the outer cover 90 is installed on one side and the other side of the installed flat iron 10 adjacent to each other, and the reinforcing concrete 100 is poured, the reinforcing concrete 100 is placed in a wide range. ) Can be installed.

A seismic reinforcement method (wet reinforcement method) using the seismic reinforcement device for an existing concrete wall according to the second embodiment of the present invention will be described. The reinforcing method of the existing concrete wall according to the second embodiment of the present invention includes the step of exposing the existing concrete surface, attaching the flat iron, installing the binner, fixing the side support, installing the wire rope, maintaining the tension of the wire rope, and installing the horizontal support. , Vertical support installation step, exterior cover installation step, reinforcement concrete placement step, exterior cover removal step).

In the step of exposing the existing concrete surface, the masonry wall, insulation, or painting material that has been accumulated on the outside of the existing concrete wall 1 is removed so that the surface of the existing concrete wall 1 is exposed. In this way, by exposing the surface of the existing concrete wall 1 to remove external foreign substances, it is possible to improve the adhesion performance with concrete to be poured for seismic reinforcement later. At this time, in the exposing step of the existing concrete surface (S10), it is preferable to further improve the adhesion performance by removing foreign substances, etc. on the surface of the existing concrete exposed to the outside and forming scratches or irregularities.

In the step of attaching pyeongcheol, a plurality of pyeongcheol 10 having the fastening hole 11 formed on the surface in the shape of a plate are attached to the existing concrete wall 1 at regular intervals vertically or horizontally using an anchor 20. At this time, the fastening holes 11 are formed at both ends of the flat iron 10, and the anchor 20 is preferably a set anchor 20. This pyeongcheol 10 is able to prevent damage to the existing concrete wall to which the anchor 20 is attached.

In the step of installing the binner, the binner 30 is installed at the end of the anchor 20 to which the flat iron 10 is attached. The binner 30 is formed in a circular shape so that the wire rope 50 to be described later can be easily installed.

In the step of fixing the side support, the both ends of the flat iron 10 positioned vertically or horizontally are integrated with the straight reinforcing bar or'b' shape side support 40. At this time, the side support 40 is preferably fixed to both ends of the flat iron 10 by welding. Even if a plurality of pyeongcheol 10 is fixed to the existing concrete wall by such side support 40, it is integrated and can withstand external force.

In the wire rope installation step, one end of the wire rope 50 is fixed to the binner 30 exposed to the outside of the outermost flat iron 10 and passed through the burner of the neighboring flat iron 10. The other end is fixed to the binner 30 exposed to the outside of the flat iron 10 at the outermost side of the other side. At this time, the wire rope 50 is preferably installed in a'X' shape on the neighboring pyeongcheol 10.

In the wire rope tension maintenance step, the outermost binner 30 and the wire rope 50 are connected with a turnbuckle 60 so that the tension of the wire rope 50 is maintained. By increasing the tensile force and compression force of the entire wire rope 50 by the turnbuckle 60, it is possible to reinforce the existing concrete wall.

In the step of installing the horizontal support, both ends of the horizontal support 70, which is a'C'-type reinforcing bar, are fixed to the ends of the anchor 20 exposed to the outside of the fastening hole 11. It is preferable that the horizontal support 70 is fixed to the end of the anchor 20 by welding. These horizontal supports 70 are installed at regular intervals along the flat iron 10 to maintain strength during the pouring of the reinforcing concrete 100 to be described later.

In the vertical support installation step, the vertical support 80, which is a straight reinforcing bar, is vertically fixed to the horizontal support 70. At this time, the vertical support 80 is installed on the horizontal support 70 by welding or fixed with a wire. In particular, it is preferable that the vertical support 80 is installed so as to be in close contact with the inner surface of the corner in the horizontal support 70 of the'C' shape. Since the vertical support 80 is integrally fixed with the horizontal support 70, it is possible to prevent the horizontal support 70 from moving, and maintain strength when pouring the reinforcing concrete 100 to be described later.

In the step of installing the outer cover, both ends of the outer cover 90 of the'C' shape are installed at both ends of the flat iron 10 attached to the existing concrete wall 1 so as to surround the horizontal support 70. The outer cover 90 may be made of an iron plate or a formwork may be used.

In the reinforcing concrete pouring step, reinforcing concrete 100 is poured into the inside of the outer cover 90. The poured reinforcement concrete 100 is located between the existing concrete wall 1 and the outer cover 90 and covers the flat iron 10, the horizontal support 70, and the vertical support 80, so that the reinforcement concrete 100 It is possible to maintain the strength of the stiffness above a certain level.

In the step of removing the outer cover, when curing of the poured reinforcing concrete 100 is completed, the outer cover 90 is removed to expose the reinforcing concrete 100. Accordingly, it is possible to additionally install a masonry wall, insulation or painting material on the surface of the concrete exposed to the outside.

By the seismic reinforcing method of the existing concrete wall according to the second embodiment of the present invention, the reinforcing concrete 100 additionally installed on the existing concrete wall 1 can be made to have improved strength without being separated.

As described above, although the present invention has been described by limited embodiments and drawings, the present invention is not limited thereto, and the technical idea and the following by those of ordinary skill in the art to which the present invention pertains. It goes without saying that various modifications and variations are possible within the equivalent range of the claims to be described in.

1: existing concrete wall 10: flat iron
11: fastening hole 20: anchor
30: binner 40: side support
50: wire rope 60: turnbuckle
70: horizontal support 80: vertical support
90: outer cover 100: reinforcement concrete
110: connection support

Claims (9)

delete delete delete A flat plate 10 having a fastening hole 11 formed on the surface thereof in a plate shape; Anchor 20 which is inserted into the existing concrete wall along the fastening hole of the pyeongcheol 10 to fix the pyeongcheol 10; A binner 30 installed at the end of the anchor 20 for fixing the pyeongcheol 10; A side support 40 for fixing both ends of the pyeongcheol 10 positioned vertically or horizontally; After one end is fixed to the binner 30 exposed to the outside of the outermost pyeongcheol 10 and passed through the burner of the neighboring pyeongcheol 10, the other end is exposed to the outside of the pyeongcheol 10 on the other side. ) A wire rope 50 fixed to; and; A horizontal support 70 fixed to the binner 30 exposed to the outside of the fastening hole 11 at both ends in a'C'shape; A vertical support 80 fixed to the horizontal support 70 with a straight reinforcing bar; The outer cover 90 fixed to the side support 40 on one side fixed to both ends of the flat iron 10 while being formed in a plate shape of'C' and surrounding the horizontal support 70 and the vertical support 80 Wow; Pyeongcheol (10), anchor (20), binner (30), side support (40), wire rope (50), turnbuckle (60), horizontal support (70), vertical support (80), outer cover ( When 90) is installed, the reinforcing concrete 100 is poured into the interior of the outer cover 90; a seismic reinforcement device for an existing concrete wall, comprising: a.
The seismic reinforcement device of an existing concrete wall according to claim 4, further comprising a connection support (110) fixed to the horizontal support (70) adjacent to each other with straight reinforcement.
The seismic reinforcement device of an existing concrete wall according to claim 4, wherein the vertical support (80) is installed so as to be in close contact with the inner surface of the corner from the horizontal support (70) of a'C' shape.
The seismic reinforcement device of an existing concrete wall according to claim 4, wherein the outer cover (90) is a steel plate or a formwork.
Exposing the surface of the existing concrete wall (1); Attaching a plurality of flat irons (10) having fastening holes (11) formed on the surface in a plate shape at regular intervals vertically or horizontally using an anchor (20) to an existing concrete wall (1); Installing a binner 30 at the end of the anchor 20 to which the flat iron 10 is attached; Fixing and integrating the both ends of the pyeongcheol (10) positioned vertically or horizontally on the side support (40); After fixing one end of the wire rope 50 to the binner 30 exposed to the outside of the flat iron 10 on one side and passing the burner of the neighboring flat iron 10, the other end of the wire rope 50 is connected to the other outermost. Fixing the binner 30 exposed to the outside of the pyeongcheol 10; Connecting the outermost binner 30 and the wire rope 50 with a turnbuckle 60 to fix the wire rope 50 to maintain tension; Fixing both ends of the horizontal support 70 of the'C' shape to the ends of the anchors 20 exposed to the outside of the fastening hole 11; Fixing the vertical support 80, which is a straight reinforcing bar, to the horizontal support 70; Installing both ends of the outer cover 90 of the'C' shape to surround the horizontal support 70 at both ends of the pyeongcheol 10 attached to the existing concrete wall 1; The seismic reinforcement method of an existing concrete wall comprising; pouring the reinforcing concrete 100 into the inside of the outer cover 90.
The seismic reinforcement method of an existing concrete wall according to claim 8, wherein scratches or irregularities are formed on the existing concrete surface exposed when the existing concrete surface is exposed.

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