KR101880494B1 - Core wall seismic reinforcement structure and construction method of the same - Google Patents

Abstract

The present invention provides a quakeproof reinforcing structure for a core wall body, and a construction method for the same. According to the present invention, a steel plate shear wall is connected to a steel column fixed to a core wall body for quakeproof reinforcement and constructability can be excellent based on facilitated steel plate shear wall assembly and installation. The quakeproof reinforcing structure for a core wall body according to a preferred embodiment of the present invention is a structure for seismically reinforcing a core wall body of an existing building, wherein a steel column made of an H beam by means of an anchor bolt at an outside wall surface corner part of the core wall body is vertically erected and mounted with respect to the foundation upper surface of the existing building and non-shrink mortar is placed in a vertical space having a quadrangular cross section between the steel column and the outside wall surface corner part of the core wall body. The steel plate shear wall is aligned and connected to the steel column with the exception of the open outside wall surface for each outside wall surface of the core wall body and a steel frame is positioned on the opening portion of the core wall body for bonding to the steel column.

Description

Technical Field [0001] The present invention relates to a core wall seismic reinforcement structure and a construction method thereof,

More particularly, the present invention relates to a seismic-strengthening structure for a core wall and a method of constructing the same, and more particularly to a seismic- To an earthquake-proof reinforcement structure of a wall and a construction method thereof.

In general, seismic retrofitting methods based on the characteristics of buildings and structures and the required performance of seismic resistance are applied by one or more of the following methods: cross section increase method, seismic wall extension method, brace installation method, and stiffener coating method. On the other hand, the staircase, elevator, pipe shaft, etc., which are common parts of the building, connect the upper and lower parts of the building as a common part. When an earthquake occurs, the horizontal seismic force (lateral force) is transmitted to the core through the slab. Therefore, in order for the core to withstand the horizontal seismic force, a proper earthquake-proof structure should be provided.

As a background of the present invention, Korean Patent Registration No. 10-0898389, 'Seismic strengthening core of a building and a construction method thereof' have been proposed. The present invention relates to a method of constructing an earthquake-proof reinforcement core for a building, the method comprising the steps of: displaying a cutting site; A core joint structure incision step; A strip grooving step; A strip home chipping step; A strip groove cleaning step; A curing agent application step; Mortar construction step; A strip attaching step; And a strip calking step. However, the background art has a disadvantage in that it is not easy to attach the high strength strip to the inner wall of the core without interruption, and the construction time is prolonged due to an increase in the number of holes.

Korean Patent Registration No. 10-0898389

An object of the present invention is to provide an earthquake-proofing structure of a core wall and a method of constructing the core wall by connecting a steel plate shear wall to a steel column fixed to the core wall and seismically reinforcing the steel plate, have.

A seismic reinforcing structure for a core wall according to a preferred embodiment of the present invention is a structure for seismically reinforcing a core wall of an existing building, wherein a steel frame made of an H beam using an anchor bolt at an outer wall edge portion of the core wall Wherein a pillar is set and fixed in a vertical direction with respect to a base upper surface of an existing building and an unshrunk mortar is installed in a vertical space of a square cross section formed between the steel column and the outer wall edge portion of the core wall, A front end wall of the steel plate is disposed in parallel to the steel column, except for an outer wall having an opening for each wall surface, and a steel beam is disposed above the opening of the core wall to be connected to the steel column.

According to another preferred embodiment of the present invention, an anti-seismic reinforcement structure for a core wall is a structure for seismically reinforcing a core wall of an existing building, wherein an outer periphery of the outer wall of the core wall is surrounded by an anchor bolt Shaped vertical wall formed between the steel column and the corner of the outer wall of the core wall is formed with a non-shrink mortar A steel plate front wall is disposed in parallel and connected to the steel column, except for an outer wall surface having an opening for each outer wall surface of the core wall, and a steel beam is positioned above the opening of the core wall to be joined to the steel column .

Further, the steel column may be continuously installed through the slab when the slab is present in the existing building.

The steel plate front end wall has a steel plate having a predetermined thickness, a joining side flange joined to both ends of the steel plate so as to be bolted to the H beam, and upper and lower reinforcing flanges .

Further, the steel plate front end wall is formed of a single steel plate having a predetermined thickness and connected to the bending steel plate by anchor bolts.

Further, the steel plate front end wall is further formed with front end wall openings penetrating the upper, lower, left, and right sides to transmit the force in the diagonal direction.

In addition, the steel plate front end wall is formed with a plurality of oblique grooves crossing in a diagonal direction for the purpose of aesthetics on the steel plate, and rhombic regions are arranged, and each rhombic region is formed with a through hole penetrating the center thereof.

According to another aspect of the present invention, there is provided a method of seismically reinforcing a core wall, the method comprising the steps of: vertically fixing a steel column made of an H beam using an anchor bolt for each outer corner of the core wall; Casting a non-shrinkage mortar in a vertical space of a square cross-section formed between the steel column and an outer wall edge portion of the core wall; Placing a steel plate front wall to each of the steel column pillars except an outer wall surface having an opening for each outer wall surface of the core wall; And placing a steel beam on an upper portion of the opening of the core wall and joining the steel beam to the steel column.

According to another aspect of the present invention, there is provided a method of seismically reinforcing a core wall, the method comprising: vertically fixing a steel column formed of a bended steel sheet using an anchor bolt to each outer edge corner portion of the core wall; Casting a shrink-free mortar in a vertical space of an L-shaped cross-section formed between the steel column and an outer wall edge portion of the core wall; Placing a steel plate front wall to each of the steel column pillars except an outer wall surface having an opening for each outer wall surface of the core wall; And placing a steel beam on an upper portion of the opening of the core wall and joining the steel beam to the steel column.

The seismic retrofitting structure of the core wall and the construction method thereof according to the present invention connect the steel plate shear wall to the steel column fixed to the corner portion of the core wall so that the shear wall of the steel plate resists in the plane direction when the horizontal seismic force is generated. In addition, the steel plate front wall is connected to the steel column by a bolt fastening, so that it has an advantage of excellent workability.

In addition, when the steel column is made of a bended steel plate in which the steel plate is bent, the installation location and the number of the steel column can be reduced compared with the steel column made of the H beam, so that the installation can be relatively easy and the construction cost can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
1 is a perspective view showing an anti-seismic structure of a core wall according to an embodiment of the present invention;
Figure 2 is a front view of Figure 1;
Figure 3 is a side view of Figure 2;
Fig. 4 is a plan view of the laminate of Fig.
FIG. 5A is a perspective view of a steel plate shear wall according to an embodiment of the present invention. FIG.
5B is a perspective view of a steel plate shear wall according to another embodiment of the present invention.
6A is a perspective view of a through hole formed in a core-side slab of an existing building for installing a steel column to which the present invention is applied.
FIG. 6B is a state in which a steel column made of an H beam is installed on the core wall shown in FIG. 6A. FIG.
7 is a front view showing an anti-seismic reinforcement structure of a core wall according to another embodiment of the present invention.
8 is a plan sectional view of Fig.
9 is a plan view showing a core wall in an existing building.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

≪ Embodiment 1 >

The present invention is intended to reinforce the earthquake resistance of the core wall 12 as shown in the plan view of the existing building 10 shown in Fig. The existing building 10 includes a pillar 101, a beam 102 and a wall 103 including a core wall 12. In this embodiment, the core wall 12 for reinforcing the earthquake-proof is not necessarily disposed at the center, but may be disposed at a side or other position.

As shown in FIGS. 1 to 4, a steel column 20 made of an H beam (H-shaped steel) is fixed to each corner of the outer wall of the core wall 12. The steel column 20 is erected perpendicularly to the upper surface of the foundation 101 of the existing building 10. The steel column 20 is anchored to the outer wall edge of the core wall 12 using anchor bolts 22. Therefore, the steel columns 20 are located on both side edges of the outer wall surface of the core wall 12, and two steel columns 20 are provided. At this time, it is preferable that the steel column 20 is made of an H beam so that the end of the flange is positioned in contact with the outer wall surface of the core wall 12 and installed in the direction of the strong axis. The anchor bolts 22 are fixed to the core wall 12 at predetermined intervals in the longitudinal direction of the steel column 20 as shown in the front view of FIG. Of course, when the slab 11 is installed in the middle of the existing building 10, the steel column 20 is passed through the through hole 11a penetrating the slab 11 as shown in Figs. 6A and 6B, Respectively. That is, the steel column 20 is installed through the through hole 11a formed in the slab 11. At this time, the installation of the anchor bolts 22 is omitted in the part of the steel column 20 corresponding to the slab 11.

Shrinkage mortar 202 is placed in a vertical space of a square cross section formed between the H beam constituting the steel column 20 and the outer wall edge portion of the core wall 12 to reinforce the steel column 20 .

A steel plate front wall 30 or 30a is provided except for an outer wall surface having an opening 121 for each outer wall surface of the core wall 12. [ The steel plate shear walls 30 and 30a are arranged side by side at regular intervals from the outer wall surface of the core wall 12 and connected to steel column posts 20 and 20 on both sides. Therefore, in this embodiment, three steel plate front walls 30 are disposed around the outer wall surface of the core wall 12 in each layer, and are connected to the two steel columns 20 and 20, respectively. The connection between the steel plate shear walls 30 and 30a and the steel columns 20 and 20 is preferably formed by fastening the bolts B and the nuts N in consideration of workability.

The steel plate front end wall 30 of one form includes a steel plate 301 having a predetermined thickness as shown in FIG. 5A, a side flange 302 for joining to both ends of the steel plate 301 and bolted to the steel column 20 And upper and lower reinforcing flanges 303 and 304 joined to the upper and lower surfaces of the steel plate 301, respectively. The height of the steel plate 301 is about 1/2 of the height of the interlayer, but the present invention is not limited to this.

At this time, the steel plate front end wall 30 may further include a front end wall opening 301a penetrating the steel plate 301 in the upper, lower, left, and right sides to transmit the force in the diagonal direction.

As shown in FIG. 5B, the other steel plate shear walls 30 are formed with a plurality of oblique grooves 301a intersecting the steel plate 301 in the diagonal direction for the purpose of aesthetics, and rhombic regions are arranged, Hole 301c is formed in the through-hole 301c.

In this embodiment, the steel plate front end wall 30 having the front end wall opening 301a is positioned on the second floor and the steel plate front end wall 30 having the through hole 301c is positioned on the first floor. However, Any one of the steel plate shear walls 30 or 30a may be provided regardless of the shape.

A steel beam 40 is positioned above the opening 121 of the core wall 12. Both ends of the steel beam 40 are connected to the steel column 20. The steel beam 40 may be an H-beam, a channel-type beam, a box-type beam, or the like, made of a steel material. The connection between the steel beam 40 and the steel column 20 may be achieved by welding or bolting the L-shaped bracket.

The earthquake-proof reinforcement structure of the core wall body 12 having the above-described structure is constructed such that when a horizontal load is applied to the existing building 10 due to an earthquake or a wind load, the steel plate front wall 30 connected to the steel column 20 on the core wall body 12 side And the steel beam 40 resist the horizontal load, thereby exhibiting the seismic performance.

For example, when a seismic load is applied to the existing building 10 in the X direction in the plan view of Fig. 4, the pair of opposite steel plate front walls 30 and 30 or 30a and 30a resist in- Performance. When an earthquake load is applied to the existing building 10 in the Y direction, the steel wall shear wall 30 and the steel beam 40 resist the core wall 12 to exhibit seismic performance. At this time, the steel beam 40 exhibits the strength by the compression resistance and exhibits the seismic performance.

On the other hand, a construction method for providing an earthquake-proof reinforcement structure for a core wall in this embodiment will be described.

First, the steel column 20 made of the H beam is fixed in the vertical direction by using the anchor bolts 22 for each outer edge corner portion of the core wall 12. At this time, it is preferable that the steel column 20 is continuously installed through the slab 11 of the existing building 10 as shown in FIG. 6A.

Next, the non-shrinkage mortar 202 is laid in a vertical space of a square cross section formed between the steel column 20 and the outer wall edge portion of the core wall 12. The non-shrinkage mortar 202 combines the anchor bolts 22 and the steel column 20 to improve the compression and flexural stiffness of the core wall 12.

Next, the steel plate front wall 30 or 30a is disposed on each of the outer wall surfaces of the core wall body 12 except for the outer wall surface having the openings 121, and the bolts B are connected to the steel column 20. The steel plate front end wall 30 or 30a is connected to the steel column 20 by a bolt B, which is advantageous in workability.

Next, the steel beam 40 is placed on the upper portion of the opening 121 of the core wall 12 and connected to the steel column 20.

≪ Embodiment 2 >

7 and 8 in order to reinforce the core wall 12 of the existing building 10 according to the second embodiment of the present invention.

That is, as shown in FIGS. 7 and 8, a steel column 20a made of a bended steel sheet bent to surround an outer side of an edge of the core wall body 12 using an anchor bolt 22 at an outer wall edge portion of the core wall body 12, Shrinkage mortar 202 is placed in the L-shaped vertical space formed between the bending steel plate and the outer wall edge portion of the core wall 12 in the vertical direction with respect to the upper surface of the base 101 of the core wall 10 The steel plate front wall 30c is arranged in parallel to the steel column 20a except for the outer wall surface having the opening 121 for each outer wall surface of the core wall 12 and is connected to the steel column 20a by anchor bolts 22, The steel frame beam 40 is positioned above the opening 121 of the steel frame 20a and is connected to the steel column 20a.

It is preferable that the steel column 20a is continuously installed through the slab 11 when the existing building 10 has the slab 11. [ At this time, the steel plate front end wall 30c is formed of a single steel plate having a predetermined thickness and connected to the bending steel plate by anchor bolts 22. [ The steel plate front end wall 30c may have a shear wall opening 301a as in the above-described steel plate front end walls 30 and 30a or may have an oblique groove 301a and a through hole 301c.

Also in the method of applying the earthquake-proof reinforcement structure of the core wall according to the second embodiment, a steel column 20a made of a bended steel sheet is used in place of the steel column 20, and the steel column 20a and the core wall Shank mortar 202 is laid in a vertical space of an L-shaped cross-section formed between the outer wall edge portion of the inner wall surface of the inner wall surface of the inner wall surface of the inner wall surface of the inner wall surface of the inner wall surface of the outer wall surface.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

12: core wall
20,20a: Steel column
30, 30a, 30c: steel plate front wall

Claims (9)

In the structure for seismically reinforcing the core wall 12 of the existing building 10,
A steel column 20 made of an H beam is passed through each slab 11 of the existing building 10 by using an anchor bolt 22 at the corner portion of the outer wall of the core wall 12, Shrinkage mortar 202 is installed in a vertical space of a rectangular cross section formed between the steel column 20 and the outer wall edge portion of the core wall 12, A steel plate front wall 30 or 30a is disposed in parallel to the steel column 20 except for an outer wall having an opening 121 for each outer wall surface of the core wall 12, And a steel beam (40) is placed on the upper part of the opening (121) and joined to the steel column (20). In the structure for seismically reinforcing the core wall 12 of the existing building 10,
A steel column 20a made of a bended steel sheet bent to surround an outer edge of the corners using an anchor bolt 22 at the corner of the outer wall surface of the core wall 12 is installed on each floor slab 11 Shaped vertical space formed between the steel column 20a and the outer wall edge portion of the core wall 12 and extending in the vertical direction with respect to the upper surface of the base 101, The mortar 202 is installed and the steel plate front wall 30c is disposed in parallel to the steel column 20a except for the outer wall surface having the opening 121 for each outer wall surface of the core wall 12, Wherein an iron core beam (40) is positioned above the opening (121) of the core wall (12) and is joined to the steel column (20a). delete The method according to claim 1,
The steel plate front wall 30 or 30a
A joining side flange 302 joined to both ends of the steel plate 301 and bolted to the H beam so as to be joined to the upper and lower surfaces of the steel plate 301, And the upper and lower reinforcing flanges (303, 304). 3. The method of claim 2,
Wherein the steel plate front end wall (30c) is made of a single steel plate having a predetermined thickness and connected to the bending steel plate by anchor bolts (22). The method according to claim 4 or 5,
Wherein the steel plate front end walls (30, 30a, 30c) further have front end wall openings (301a) penetrating upward, downward, left, and right to transmit force in a diagonal direction. The method according to claim 4 or 5,
The steel plate front end walls 30, 30a and 30c are formed with a plurality of oblique grooves 301a intersecting in the diagonal direction for aesthetics in the steel plate 301, and rhombic regions are arranged. In each rhombic region, (301c) is formed on the inner wall of the core wall. A step of vertically fixing the steel column 20 made of an H beam through the slab of each layer by using an anchor bolt 22 for each outer side edge portion of the core wall 12;
Casting a non-shrinkage mortar (202) in a vertical space of a square cross-section formed between the steel column (20) and an outer wall edge portion of the core wall (12);
Placing a steel plate front wall (30) on each of the outer wall surfaces of the core wall body (12) except for an outer wall surface having an opening (121), and connecting the steel plate front wall (30) to the steel column post (20);
And placing the steel beam 40 on the upper portion of the opening 121 of the core wall 12 and joining the steel beam 40 to the steel column 20. [ A steel column 20a made of a bended steel sheet is fixed successively in the vertical direction through the slabs of each layer by using anchor bolts 22 on the outer side edge portions of the core wall 12;
Casting a non-shrinkage mortar (202) in a vertical space of an L-shaped cross section formed between the steel column (20a) and an outer wall edge portion of the core wall (12);
Placing each steel plate shear wall (30) on the outer wall of the core wall (12) except for an outer wall surface having an opening (121), and connecting the shear wall (30) to the steel column post (20a);
And a step of placing a steel beam 40 on the upper portion of the opening 121 of the core wall 12 and joining the steel beam 40 to the steel column 20a.

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