KR20090025496A - Structure for reinforcing earthquake-proof efficiency - Google Patents

Abstract

An earthquake-resistant performance reinforcing structure is provided that the earthquake-resistant performance can be easily controlled since construction is completed. An earthquake-resistant performance reinforcing structure comprises an upper beam(100) combined in two wall (W) uppers included in structure, a friction pad mounted between two sides in which slipping is generated, a frictional damping unit(200) damping the power changing angle between the upper part beam and the wall. The damping unit includes a first bracket fixed to one among the wall and upper part beam, and a second bracket combined in said the first bracket to the structure of being rotatable.

Description

Structure for reinforcing earthquake-proof efficiency

The present invention relates to an apparatus for reinforcing seismic performance of a structure, and more particularly, to a reinforcing structure configured to reinforce the seismic performance of the entire structure by reducing the upper bending displacement of the structure and damping the bending moment of the structure. It is about.

When constructing a structure with a reinforced concrete wall structure, there are many cases in which it is constructed in tunnel form for ease of construction. In this case, the bearing wall is constructed only in one of the front and rear directions or the left and right directions. Has a problem. That is, in the case of apartments constructed with the tunnel form, the walls between generations are constructed as bearing walls, but the walls inside one generation are constructed as non-bearing walls, so that the seismic performance in the direction in which generations are arranged is very weak.

However, the new method of building concrete shear walls is a wet method, which not only has a long construction period and requires a large work space, but also increases the seismic load and increases the foundation reinforcement due to the increased weight of the structure. There is a problem. In addition, the method of expanding the steel member is a configuration that almost all the moments generated in the structure is applied to the steel frame, there is a problem that the construction cost is very high because it takes a lot of expensive steel frame compared to concrete.

In order to solve this problem, a seismic performance reinforcing structure has been proposed that is configured to damp the moment generated in the structure.

Hereinafter, with reference to the accompanying drawings will be described in detail a conventional seismic performance reinforcing structure.

1 is a side view of a conventional seismic performance reinforcing structure, Figure 2 is a side view showing the operation of the conventional seismic performance reinforcing structure when the moment is generated in the structure.

As shown in FIG. 1, the conventional seismic performance reinforcing structure includes a support pillar 20 that is erected to be spaced apart from an outer surface of the structure 10, and a gap between the structure 10 and the support pillar 20 increases and decreases. Damping device 30 to dissipate when the moment is applied to the structure 10, the vertical extension structure 40 which is constructed on the upper surface of the structure 10, and the structure 10 and the vertical extension structure 40 It is configured to include a friction layer 50 provided between).

When the moment is generated so that the top of the structure 10 is rotated clockwise in the state shown in Figure 1, the damping device 30 mounted on the right side of the structure 10, as shown in Figure 2 is compressed and the structure ( Since the damping device 30 mounted on the left side of 10 is tensioned, the moment applied to the structure 10 is partially dissipated by the damping device 30. That is, when the conventional seismic performance reinforcing structure is used, since the displacement amount of the structure 10 is reduced when the moment is generated in the structure 10, the effect of improving the seismic performance of the structure 10 can be obtained as a result.

In addition, as shown in FIG. 2, when the upper end of the structure 10 moves laterally, the friction layer 50 generates a friction force in a direction opposite to the direction in which the upper end of the structure 10 moves (arrow of FIG. 2). Displacement energy of the structure 10 is converted into friction energy of the friction layer 50 and dissipated. That is, the friction layer 50, like the damping device 30, reduces the amount of displacement of the structure 10, thereby serving to improve the seismic performance of the structure 10.

However, in the conventional seismic performance reinforcing structure shown in Figs. 1 and 2, the support column must be installed higher than the height of the structure from the ground, and a separate vertical load resistance system must be installed to support the support column and the vertically expanded structure. In the case of this high-rise, there is a problem that it is difficult to apply. In addition, since the conventional seismic performance reinforcing structure does not utilize the seismic performance of the existing structure, the seismic reinforcing amount is greatly increased, and the effect of the seismic performance reinforcing is almost eliminated when the existing structure and the newly installed structure move at the same period. There is a problem that it is difficult to control the magnitude of the force to reduce the displacement, that is, seismic performance after construction.

The present invention has been proposed to solve the above problems, the size is small and the structure is simple, can be easily applied to high-rise structure, the seismic performance can be easily adjusted after the construction is completed, It is an object of the present invention to provide a seismic reinforcing structure that can effectively reinforce seismic performance regardless.

Seismic performance reinforcing structure according to the present invention,

It is configured to include a top beam that is fixedly coupled to connect the two wall upper sides included in one structure.

Seismic performance reinforcing structure according to the present invention,

Two or more pillars having a lower end coupled to an upper end of different ones of two or more walls included in one structure and extending in the longitudinal direction of the walls; And

An upper beam having both ends coupled to two different pillars;

It is configured to include.

The upper beam is provided at the top and bottom of the pillar, respectively.

Seismic performance reinforcing structure according to the present invention,

An upper beam in which both sides are rotatably coupled to two wall upper sides included in one structure; And

Friction type damping means for attenuating a force for changing an angle between the wall and the upper beam, including a friction pad mounted between two surfaces at which a sliding occurs when the angle between the wall and the upper beam is changed;

It is configured to include.

The friction damping means,

A first bracket having one side fixedly coupled to any one of the wall and the upper beam; And

A second bracket having one side coupled to the other side of the first bracket in a rotatable structure and the other side fixedly coupled to the other of the wall and the upper beam;

More,

The friction pad is mounted between a portion where the first bracket and the second bracket overlap.

Seismic performance reinforcing structure according to the present invention,

Two or more pillars having a lower end coupled to an upper end of different ones of two or more walls included in one structure and extending in the longitudinal direction of the walls;

An upper beam to which both sides are rotatably coupled to two different pillars; And

Friction type damping means for attenuating a force for changing an angle between the wall and the upper beam, including a friction pad mounted between two surfaces at which a sliding occurs when the angle between the pillar and the upper beam is changed;

It is configured to include.

The upper beam is provided at the top and bottom of the pillar, respectively.

The friction damping means,

A first bracket having one side fixedly coupled to any one of the pillar and the upper beam; And

A second bracket having one side coupled to the other side of the first bracket in a rotatable structure and the other side fixedly coupled to the other of the pillar and the upper beam;

More,

The friction pad is mounted between a portion where the first bracket and the second bracket overlap.

It further includes a reinforcing member for increasing the bending rigidity of the wall.

The reinforcing member is applied to a steel plate or a steel beam coupled to both sides of the wall.

The reinforcement member is applied to the concrete reinforcement wall is constructed to cover at least one surface of both sides of the wall.

The reinforcement member includes a concrete reinforcement wall constructed to cover at least one surface of both surfaces of the wall, and a steel plate coupled to a surface exposed to the outside of both surfaces of the wall and both surfaces of the concrete reinforcement wall. .

The left and right ends are bent to cover the upper surface and the upper surface of both sides of the wall, further comprising a bending member coupled to the wall,

The lower end is coupled to the upper surface of the bending member.

The bending member is coupled to the wall by an anchor bolt fastened to penetrate the upper portion of the wall and the left and right ends of the bending member.

The upper beam may be applied to a steel beam or precast concrete plate having a bent longitudinal section.

By using the seismic performance reinforcing structure according to the present invention, it is possible to effectively reinforce the seismic performance of the structure by reducing the maximum bending displacement amount of the structure, small size and simple structure can be easily applied to high-rise structure, friction pad By adjusting the frictional force of the structure, the seismic performance can be easily changed after the construction of the structure is completed, and the seismic performance can be effectively reinforced regardless of the displacement period of the structure.

The seismic performance reinforcing structure according to the present invention is configured to suppress a change in inclination between the upper part of the wall of the structure and the upper plate of the structure, so that the stress generated when the structure is deflected laterally is more evenly distributed throughout the structure and It is characterized by reducing the amount of bending displacement.

In addition, the seismic performance reinforcing structure according to the present invention has another feature in that the structure is configured to reduce the stress applied to the entire structure by converting and damping the moment when the moment is applied to the structure to bend to the friction force.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the seismic performance reinforcing structure according to the present invention in detail.

Figure 3 is a front view of the seismic performance reinforcing structure according to the present invention, Figure 4 shows a displacement difference between the structure to which the seismic performance reinforcing structure according to the present invention is applied and the structure is not applied when the moment is generated in the structure.

Seismic performance reinforcing structure according to the present invention is a structure that is installed in the structure 10 having two or more walls (W), the lower end is coupled to the upper end of the different wall (W) as shown in FIG. Two or more pillars 300 extending in the longitudinal direction of the (W), and the upper beam 100 and both sides rotatably coupled to the two different pillars 300, respectively, the wall (W) and the upper beam (100) It is configured to include a friction type damping means 200 for converting the damping force by changing the angle between, i.e., a portion of the moment generated in the structure 10 to a frictional force.

The pillar 300 and the upper beam 100 are subjected to a large load when the structure 10 is bent, and is preferably applied to the H-beam to increase the bending rigidity relative to the cross-sectional area. In addition, the pillar 300 may be coupled to every wall (W) or may be coupled to only some of the walls (W), the shock resistance of the structure 10 as the number of the pillar 300 and the upper beam 100 is increased As the reinforcing effect is increased, the number of pillars 300 and the upper beams 100 installed in one structure 10 may be changed according to various characteristics and purposes of the structure 10.

The embodiment shown in FIG. 3 is a case for extending to the upper side of the structure 10, the upper beam 100 that is the ceiling of the extension structure 10 is coupled to the top of the pillar 300, the pillar At the bottom of the 300 is another upper beam 100 to be the bottom of the extension structure 10 is coupled. Therefore, the flooring may be installed on the upper surface of the upper beam 100 coupled to the lower end of the pillar 300. Thus, when using the seismic performance reinforcing structure according to the present invention, there is an advantage that it is not necessary to construct a separate frame when remodeling to expand vertically.

When the general structure 10 is bent to one side, as shown in FIG. 4 (a), the more the wall W is inclined upward, the seismic performance reinforcing structure according to the present invention is a wall (W). Since the top of each wall (W) is constrained so that the top is not inclined, the structure 10 is not bent only in one direction. That is, when the moment is applied to the structure 10, the seismic performance reinforcement structure is installed in accordance with the present invention, as shown in Fig. 4 (b) is bent in the direction of the moment from the bottom to the interruption, but stopped From the top to the rather bend in the opposite direction of the moment direction.

As shown in (a) of FIG. 2, when the structure 10 is bent only in one direction, the upper bending displacement amount of the structure 10 becomes very large, and thus the structure 10 may be damaged. As shown in), if the upper and lower sides of the structure 10 are bent in different directions with respect to the interruption, the upper bending displacement amount is relatively small, thereby reducing the risk of breakage of the structure 10.

In addition, as shown in FIG. 4A, when the structure 10 is bent only in the right direction, only the compressive stress is intensively applied to the right side of the wall W, and only the tensile stress is applied to the left side of the wall W. FIG. Since it is applied intensively, there is a problem that the shearing concern of the structure 10 is increased. However, if the seismic performance reinforcing structure according to the present invention is installed, the opposite stress on the right side and the left side relative to the interruption of the wall (W) (compression stress on the upper right side, compressive stress on the lower right side, compressive stress on the upper left side) In the lower left side, the tensile stress) is applied to form symmetry, respectively, and thus there is an advantage that the shearing concern of the structure 10 is lowered. Thus, when the seismic performance reinforcing structure according to the present invention is installed, there is an effect that the stability when the structure 10 is bent to one side, that is, the seismic resistance of the structure 10 is enhanced.

In addition, the seismic performance reinforcing structure according to the present invention, because it is not installed on the side of the structure 10 is installed only on the upper portion of the structure 10, there is an advantage that can be easily applied to the high-rise structure (10).

In this embodiment, but only the case of manufacturing the upper beam 100 in H-shaped steel, but this is only one embodiment for securing a large moment of inertia relative to the cross-sectional area, the material and shape of the upper beam 100 is various Can be changed.

That is, the upper beam 100 may be applied to the 'c' shaped steel or L-shaped steel according to the characteristics or design conditions of the structure 10, the concrete member is expected to receive a large compressive stress in the longitudinal direction It can also be produced.

In addition, when the upper beam 100 is applied to the section steel, it is necessary to construct a separate bottom plate so that the upper beam 100 is embedded, in this way by placing concrete on the top of the structure 10 to construct the bottom plate The task is that the process is very complicated. In particular, when the structure 10 is a high-rise, there are many difficulties in carrying various construction equipment and materials to the upper portion of the structure 10 for the bottom plate construction. Therefore, the upper beam 100 may be applied to a precast concrete plate (Precast concrete plate) is produced in a flat shape in advance so that no separate bottom plate construction is required to be supplied to the site. Thus, when the upper beam 100 is applied to the precast concrete plate, the upper beam 100 does not have to construct a separate bottom plate because the upper beam 100 plays the role of the bottom plate, the cross-sectional area of the upper beam 100 This increase is because the moment of inertia is very large, there is an advantage that can reduce the thickness of the upper beam (100).

In addition, since the friction type damping means 200 is typically made of steel, it is difficult to couple the friction type damping means 200 to the upper beam 100 when the upper beam 100 is applied as a precast concrete plate. There may be. Therefore, when the upper beam 100 is applied to the precast concrete plate, the left and right ends of the upper beam 100, that is, the friction type damping means 200 is coupled to a portion by the fastening means such as anchor bolts separately The metal plate is integrally coupled, the friction damping means 200 may be configured to be coupled to the metal plate.

5 is a front view of the friction damping means 200 included in the seismic performance reinforcing structure according to the present invention, Figure 6 is a cross-sectional view of the friction damping means 200 cut along the line AA shown in FIG. 7 is a partial cross-sectional view showing a coupling structure between the seismic performance reinforcing structure and the wall (W) according to the present invention.

When the upper beam 100 is fixedly coupled to the column 300, the effect of reducing the maximum displacement amount of the wall (W) when the moment is applied to the structure 10 to bend the wall (W) is large, but the structure If the moment applied to the (10) is very large, there is a fear that the structure 10 is damaged by the compressive stress and tensile stress generated in the structure (10). Therefore, the upper beam 100 is preferably coupled to the pillar 300 by the friction-type damping means 200 so that the coupling angle with the pillar 300 can be changed when a moment or more moment is applied to a certain size. .

At this time, the friction type damping means 200, as shown in Figure 5 and 6, the first bracket 210 is fixedly coupled to one side to the pillar 300, and the first bracket in a structure capable of rotating one side The second bracket 220 is coupled to the other side of the 210 to the fastening bolt 230 and the other side is fixedly coupled to the upper beam 100, and the angle between the pillar 300 and the upper beam 100 is to be changed. The friction pad 240 is mounted between two surfaces at which a slip is generated, that is, between a portion where the first bracket 210 and the second bracket 220 overlap each other.

Therefore, when the wall (W) is bent with a force greater than the friction of the friction pad 240, the first bracket 210 and the second bracket 220 is rotated with respect to the fastening bolt 230, the Friction force is generated in the friction pad 240 inserted between the first bracket 210 and the second bracket 220. That is, when the seismic performance reinforcing structure according to the present invention is used, a part of the force bending the wall (W) is converted into the frictional force of the friction pad 240 and dissipated, so that the seismic performance of the structure 10 is improved. You get an effect.

At this time, the friction force of the friction pad 240 may be changed according to the tightening degree of the fastening bolt 230, the user can appropriately adjust the friction force of the friction pad 240 according to various environments and conditions.

At this time, when the wall (W) and the upper beam 100 is coupled in a direct rotatable structure, the friction-type damping means 200, the friction pad 240 without the first bracket 210 and the second bracket 220 ) Can be configured only. That is, the friction damping means 200 may be made of only the friction pad 240 is inserted into the overlapping portion of the wall (W) and the upper beam (100).

Referring to the structure that the pillar 300 is coupled to the wall (W) as follows.

In general, the wall (W) of the structure (10) is made of concrete, there is a lot of difficulty in directly connecting the column 300, which is a steel beam to the wall (W).

Therefore, at the upper end of the wall (W), the bending member 700 of the 'c'-shaped steel structure is further provided with the left and right ends bent to cover the upper surface and the upper both sides of the wall (W). The bending member 700 is coated with an adhesive 710 such as epoxy slewing on the inner side and attached to the upper end of the wall W, and then the upper side of the wall W and the left and right sides of the bending member 700. It is fixedly coupled to the wall (W) by the anchor bolt 500 fastened to penetrate the end.

At this time, since the bending member 700 is made of a metal material such as steel, the pillar 300 may be fixedly coupled to the bending member 700 by a coupling method such as welding. That is, when the bending member 700 is additionally provided at the upper end of the wall (W) as described above, even if the pillar 300 is not directly coupled to the wall (W) to be fixed integrally with the wall (W) It becomes possible.

8 and 9 are cross-sectional views showing a coupling structure of the concrete reinforcement wall 600 and the steel plate 400 for reinforcing the wall (W).

As shown in FIG. 4B, when the wall W is bent in an 'S' shape, the maximum displacement amount of the wall W decreases, but the magnitude of the stress applied to the wall W increases and the wall W Since the direction of stress applied to is reversed at the interruption, the wall W may be deformed or broken. Therefore, it is preferable that the reinforcing member for increasing the strength is additionally installed on the wall (W).

At this time, the reinforcing member, as shown in Figure 8 may be applied to the plate-shaped steel plate 400 is coupled to both sides of the wall (W), may be applied to the steel beam coupled to both sides of the wall (W). have.

In addition, to reinforce the wall (W) more robustly, the reinforcing member is a concrete reinforcement wall 600 is constructed to cover both sides of the wall (W), as shown in Figure 9, and the concrete reinforcement It may be composed of a steel plate 400 coupled to cover the outer surface of the wall 600. In this case, the concrete reinforcement wall 600 may be constructed only on one surface of both surfaces of the wall (W), in which case the steel sheet 400 of the outer surface of the wall (W) and the concrete reinforcement wall 600 It is coupled to the surface exposed to the outside of the outer surface.

In addition, when the steel sheet 400 is exposed to the outside, not only the appearance is not good, but also to perform additional plastering, the reinforcing member may be made of only the concrete reinforcing wall 600 without the steel sheet 400.

10 is a front view of a second embodiment of the seismic performance reinforcing structure according to the present invention, Figure 11 is a front view of a third embodiment of the seismic performance reinforcing structure according to the present invention, Figure 12 is a fourth embodiment of the seismic performance reinforcing structure according to the present invention The front view of the example.

The seismic performance reinforcing structure according to the present invention may be of a structure in which the upper beam 100 is fixedly coupled to the pillar 300 without the friction type damping means 200. That is, the seismic performance reinforcing structure according to the present invention, as shown in Figure 10, the lower end is coupled to the upper end of the different wall (W) of the two or more walls (W) included in one structure 10 said wall It may be configured to include two or more pillars 300 extending in the longitudinal direction of (W), and the upper beam 100 is fixedly coupled to two different pillars 300, respectively.

As such, when the friction damping means 200 is omitted, the effect of dissipating the force of bending the structure 10 may not be obtained. However, since the upper end of the wall W may be more firmly constrained, the maximum bending of the structure 10 may be achieved. Displacement can be reduced, there is an advantage that the coupling structure between the upper beam 100 and the pillar 300 is simplified.

In addition, when extension is not necessary to the upper side of the structure 10, the seismic performance reinforcing structure according to the present invention may be directly connected to the reinforcing wall (W) without the upper beam (100). That is, the seismic performance reinforcing structure according to the present invention, as shown in Figure 11, and the upper beam 100, both sides rotatably coupled to the upper side of the two walls (W) included in one structure 10 and When the angle between the wall (W) and the upper beam 100 is changed, the angle between the wall (W) and the upper beam 100 including a friction pad 240 is mounted between the two surfaces that are generated sliding It may be configured to include a friction type damping means 200 for damping the force to change the.

As such, when the pillar 300 is omitted, various processes for coupling the pillar 300 to the wall W may be omitted, and thus, the installation of the seismic reinforcing structure according to the present invention may be more easily performed.

At this time, when it is difficult to directly couple the friction type damping means 200 to the wall W, the bending member 700 is coupled to the upper end of the wall W, and the friction type damping means 200 is bent. It may be coupled to the member 700.

In addition, the seismic performance reinforcing structure according to the present invention, omitting both the friction-type damping means 200 and the pillar 300, may be composed of only the upper beam (100). That is, the upper beam 100 may be fixedly coupled so that both ends connect the upper side of the two walls (W) as shown in FIG.

As such, when the upper beam 100 is directly fixed to the wall (W), it is not possible to dissipate the bending force of the wall (W) nor to install a plurality of upper beams 100 to prevent the seismic performance of the structure (10) Although it can not be greatly reinforced, there is an advantage that the structure is very simple and easy to manufacture and install. Therefore, when it is not necessary to greatly reinforce the seismic performance of the structure 10, as shown in FIG. 12, the upper beam 100 can be directly fixed to the wall (W).

As mentioned above, although this invention was demonstrated in detail using the preferable embodiment, the scope of the present invention is not limited to a specific embodiment, Comprising: It should be interpreted by the attached Claim. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

1 is a side view of a conventional seismic performance reinforcing structure.

Figure 2 is a side view showing the operation of the conventional seismic performance reinforcement structure when the moment is generated in the structure.

3 is a front view of the seismic performance reinforcing structure according to the present invention.

4 shows a displacement difference between the structure to which the seismic performance reinforcing structure according to the present invention is applied and the structure to which the structure is not applied when a moment is generated in the structure.

5 is a front view of the friction type damping means included in the seismic performance reinforcing structure according to the present invention.

6 is a cross-sectional view of the friction type damping means included in the seismic performance reinforcing structure according to the present invention.

7 is a partial cross-sectional view showing a coupling structure between the seismic performance reinforcing structure and the wall according to the present invention.

8 and 9 are cross-sectional views showing a coupling structure of the concrete reinforcement wall and the steel plate for wall reinforcement.

10 is a front view of a second embodiment of the seismic performance reinforcing structure according to the present invention.

11 is a front view of a third embodiment of the seismic performance reinforcing structure according to the present invention.

12 is a front view of a fourth embodiment of the seismic performance reinforcing structure according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: structure W: wall

100: upper beam 200: friction type damping means

210: first bracket 220: second bracket

230: fastening bolt 240: friction pad

300: pillar 400: steel sheet

500: anchor bolt 600: concrete reinforcement wall

700: bending member

Claims (15)

Earthquake-resistant reinforcement structure, characterized in that it comprises a top beam (100) fixedly coupled to connect the two walls (W) upper side included in one structure (10). At least two pillars 300 coupled to the upper ends of different walls W among two or more walls W included in one structure 10 and extending in the longitudinal direction of the walls W; And The upper beam 100 is coupled to each other two pillars 300, both ends; Seismic performance reinforcement structure, characterized in that configured to include. The method of claim 2, The upper beams 100 are seismic performance reinforcement structure, characterized in that each provided on the top and bottom of the column (300). An upper beam 100 in which both sides are rotatably coupled to the upper sides of two walls W included in one structure 10; And When the angle between the wall (W) and the upper beams 100 is changed, including a friction pad 240 mounted between the two surfaces that are sliding, the angle between the wall (W) and the upper beams 100 Friction type damping means for damping the force for changing the pressure; Seismic performance reinforcement structure, characterized in that configured to include. The method of claim 4, wherein The friction damping means 200, A first bracket 210 having one side fixedly coupled to any one of the wall (W) and the upper beam (100); And A second bracket 220 having one side coupled to the other side of the first bracket 210 in a rotatable structure and the other side fixedly coupled to the other of the wall W and the upper beam 100; More, The friction pad 240 is mounted between the first bracket 210 and the second bracket 220, the overlapping portion, characterized in that the seismic performance reinforced structure. Two or more pillars 300 extending in the longitudinal direction of the wall (W) is coupled to the lower end of the different walls (W) of the two or more walls (W) included in one structure (10); An upper beam 100 having both sides rotatably coupled to two different pillars 300; And An angle between the wall (W) and the upper beam 100, including a friction pad 240 is mounted between the two surfaces where the sliding occurs when the angle between the pillar 300 and the upper beam 100 is changed Friction type damping means for damping the force for changing the pressure; Seismic performance reinforcement structure, characterized in that configured to include. The method of claim 6, The upper beams 100 are seismic performance reinforcement structure, characterized in that each provided on the top and bottom of the column (300). The method of claim 6, The friction damping means 200, A first bracket 210 having one side fixedly coupled to any one of the pillar 300 and the upper beam 100; And A second bracket 220 having one side coupled to the other side of the first bracket 210 in a rotatable structure, and the other side fixedly coupled to the other one of the pillar 300 and the upper beam 100; More, The friction pad 240 is mounted between the first bracket 210 and the second bracket 220, the overlapping portion, characterized in that the seismic performance reinforced structure. The method according to any one of claims 1 to 8, Seismic performance reinforcing structure, characterized in that it further comprises a reinforcing member for increasing the strength of the wall (W). The method of claim 9, The reinforcement member is a steel plate 400 or an iron beam coupled to both sides of the wall (W), seismic performance reinforcement structure. The method of claim 9, The reinforcement member is a concrete reinforcement structure, characterized in that the concrete reinforcement wall 600 is constructed to cover at least one surface of both sides of the wall (W). The method of claim 9, The reinforcement member is a concrete reinforcement wall 600 which is constructed to cover at least one surface of both surfaces of the wall (W), the outer side of both surfaces of the wall (W) and both sides of the concrete reinforcement wall (600). Seismic performance reinforcement structure, characterized in that comprises a steel plate 400 coupled to the exposed surface. The method according to any one of claims 1 to 8, The seismic performance reinforcing structure, characterized in that it further comprises a bending member (700) coupled to the wall (W) is bent to the left and right ends to cover the top surface and the upper both sides of the wall (W). The method of claim 13, The bending member 700 is coupled to the wall (W) by the anchor bolt 500 is fastened so as to pass through the upper portion of the wall (W) and the left and right ends of the bending member (700). Performance reinforcement structure. The method according to any one of claims 1 to 8, The upper beam 100 is a seismic performance reinforcement structure, characterized in that the steel beam or precast concrete plate having a bent longitudinal section.

Images