KR102130843B1 - Seismic reinforcement concrete structure using steel braces with dampers - Google Patents

Abstract

A structure constructed by seismic reinforcement using a steel brace and a structure consisting of a beam installed at the top of an opening and two parallel sides connected to the beam, a horizontal frame installed horizontally at the bottom of the beam, and 2 vertically connected to the beam Reinforcing frames composed of left and right vertical frames, which are respectively installed in the longitudinal direction, and are installed inside the parallel side surfaces of the dogs; A first fixed steel plate and a second fixed steel plate symmetrically attached to a predetermined position spaced apart at equal intervals from the both ends of the horizontal frame; A third fixed steel plate and a fourth fixed steel plate symmetrically attached to a predetermined position of the same height, respectively, from one side end of the left and right vertical frames of the side surfaces; And a pair of the braces having a symmetrical structure, connecting one end of the brace to the first fixed steel plate and the second fixed steel plate, and the other end of the brace is connected to the third fixed steel plate and the fourth fixed steel plate, respectively. The brace is composed of a steel brace that is installed at a predetermined angle of inclination, wherein the first to fourth fixed steel plates include that the brace is attached to a certain position of the reinforcement frame that does not interfere with the opening, and the brace is It consists of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe, and minimizes the phenomenon that the window is obscured by the brace with the seismic enhancement function, minimizes the phenomenon that the field of view is obscured, and maintains light and visibility, and provides a structure in consideration of aesthetics.

Description

Seismic reinforced concrete structure using steel brace with damper{SEISMIC REINFORCEMENT CONCRETE STRUCTURE USING STEEL BRACES WITH DAMPERS}

The present invention is a concrete structure reinforced seismically by using a steel brace equipped with a damper, and more specifically, resistance to lateral loads such as seismic loads of structures with openings such as windows or doorways through a braced steel structure including a damper. To improve the seismic reinforced structure.

In Korea, as the risk of earthquakes gradually increases, the scope of seismic design and reinforcement standards for buildings have been strengthened, including the expansion of buildings subject to seismic design. Most small and medium-sized buildings, such as school buildings that were built before seismic design standards were introduced and have not been applied to seismic design, are very vulnerable to earthquakes.

In particular, the area around the wall opening of a reinforced concrete structure is a part in which stress is concentrated due to dry shrinkage, temperature change, external force, etc., and cracks are likely to occur. Became known.

Buildings to which seismic design is not applied are very vulnerable to vibrations caused by earthquakes because of the small energy dissipation capacity by external forces, which threatens structural safety. Therefore, in order to secure the insufficient seismic performance of building structures, an earthquake-resistant design that combines an earthquake-proof method to increase the rigidity of a building, a surface-vacuum method to reduce the floor transmission force, and a vibration-reduction method to control the behavior of the vulnerable parts is applied.

As a method of reinforcing seismic performance of existing buildings, there is a problem that the construction method is difficult and cost increases, such as separating the ground from the structure. The vibration suppression method is generally applied.

The vibration suppression method is a structural system designed to improve the seismic performance by inducing that most of the vibration energy is absorbed by installing a vibration damping device that mechanically controls the vibration of the structure due to the earthquake. In general, the vibration isolator operates depending on the deformation of the structure lateral force resistance system, and dissipates or absorbs a significant portion of the energy input to the structure by ground motion, thereby reducing the acceleration and displacement response of the entire structure.

Carbon-based dampers used in typical vibration damping methods include steel slit dampers and non-buckling brakes that can add stiffness and damping to existing structures, and hydraulic (oil) viscous dampers that increase deformation without changing the rigidity of existing structures. There is a damper. The vibration damping reinforcement method has the advantage of reducing the construction cost by reducing the reinforcement point compared to the general rigid reinforcement because the basic frame member can be reduced by dispersing the horizontal load through energy concentration and dissipation as a vibration damping device.

As a conventional seismic reinforcement method, a technique of reducing the response of a building by increasing the damping performance by applying a vibration damping device to the inside or outside of a building to increase the strength by installing a brace in connection with a beam and a pillar is applied.

As a method of reinforcing the frame, a conventional method of installing a steel frame bracing to resist horizontal forces is a method of increasing the rigidity and strengthening the seismic performance to withstand seismic energy by the structural member itself. The structure is simple and easy to manufacture and install. However, if the brace is installed at the location of a window or door, it has a disadvantage that it obstructs the field of view and harms the light and aesthetics.

Particularly, in order to improve the seismic performance, a reinforcement member such as a brace may be obliquely formed in an X-type or a K-type across the pillars and beam joints constituting the frame to increase the proof strength, but absorb energy when an earthquake occurs. Since there is no vibration damping performance, it may easily break or be damaged when an earthquake exceeds the design strength.

In addition, when only a damping damper is used, it is excellent in seismic reinforcing performance due to the characteristics of a damper that exhibits vibration damping performance in the event of an earthquake, but when the damper does not behave, it is difficult to expect a yield strength than the bracing system by the damper itself.

Moreover, in buildings where seismic design is not applied, since the pillar portion is brittlely destroyed by shear when an earthquake occurs, a reinforcement structure using a reinforcement method that can increase the load carrying capacity of the structure by increasing the cross section is required.

Korean Patent Publication No. 10-2013-0117204

The present invention is to provide a seismic-reinforced structure using a steel brace provided with a damper to improve the vibration damping effect and the proof strength by the earthquake as an invention devised to solve the problems of the prior art described above.

That is, by installing a damper as an energy absorbing device on the bracing steel pipe in a way to increase the strength with a reinforcing member such as a brace and to increase the damping ratio of the structure to improve the vibration damping performance of energy dissipation, minimize damage to the building and respond to earthquakes The purpose is to provide a seismic reinforcement structure that can effectively reduce the.

In addition, the present invention provides a structure that can be applied to a building such as a school that requires air shortening without significantly changing its appearance, and can easily maintain and repair a reinforcing member such as a brace including a damper.

In addition, there is a concern that space use is restricted and the view of the space and the aesthetics of the space may be harmed due to limitations in space usage by covering part of the openings, such as windows or doorways, inside and outside the structure, that is, the façade of the structure and the inside of the structure. It is to provide a minimal earthquake-resistant reinforcement structure.

In addition, it is to provide a structure that enhances the rigidity of the structure against earthquake resistance by integrally fabricating the vertical frame and the columnar section.

The problems of the present invention are not limited to the problems mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

Seismic reinforcing structure using a steel brace according to the present invention for achieving the above object, for a structure consisting of two parallel sides connected to the beam and the beam located on the top of the opening, it is installed in the horizontal direction at the bottom of the beam A reinforcing frame composed of a horizontal frame and left and right vertical frames, each extending in a longitudinal direction, and installed inside of two parallel side surfaces vertically connected to the beam; A first fixed steel plate and a second fixed steel plate symmetrically attached to a predetermined position spaced apart at equal intervals from the both ends of the horizontal frame; A third fixed steel plate and a fourth fixed steel plate symmetrically attached to a predetermined position of the same height, respectively, from one side end of the left and right vertical frames of the side surfaces; And a pair of the braces having a symmetrical structure, connecting one end of the brace to the first fixed steel plate and the second fixed steel plate, and the other end of the brace is connected to the third fixed steel plate and the fourth fixed steel plate, respectively. The brace is composed of a steel brace installed at a predetermined inclination angle, wherein the brace is composed of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe.

In the earthquake-resistant reinforcement structure using the steel brace according to the present invention, the third fixed steel plate and the fourth fixed steel plate may be installed at a position higher than the opening on the vertical frame.

Seismic reinforcement structure using a steel brace according to the present invention, for a structure consisting of two parallel sides connected to the beam and the beam located above the opening, the horizontal frame installed in the horizontal direction at the bottom of the beam, and the beam A reinforcing frame composed of left and right vertical frames which are installed to extend in the longitudinal direction, respectively, on two parallel side surfaces connected vertically; A first fixed steel plate and a second fixed steel plate symmetrically attached to a predetermined position spaced apart at equal intervals from the both ends of the horizontal frame; A third fixed steel plate and a fourth fixed steel plate symmetrically attached to lower end portions of the left and right vertical frames of the side surface; And a pair of the braces having a symmetrical structure, connecting one end of the brace to the first fixed steel plate and the second fixed steel plate, and the other end of the brace is connected to the third fixed steel plate and the fourth fixed steel plate, respectively. The brace is composed of a steel brace installed at a predetermined inclination angle, wherein the brace is composed of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe.

In the seismic reinforcement structure using the steel brace according to the present invention, one end of the brace is connected to the first fixed steel plate and the second fixed steel plate, and the other end of the brace is connected to the third fixed steel plate and the fourth fixed steel plate. The angle of inclination of the brace is adjusted by adjusting the positions of the first fixed steel plate and the second fixed steel plate on the horizontal frame so that the brace provided with the damper can be disposed at a certain position outside the opening so as not to cover the opening. It can be installed while adjusting.

Seismic reinforcing structure using a steel brace according to the present invention, a concrete frame consisting of a concrete beam and two parallel pillars connected to the beam is horizontally installed at the bottom of the beam and connected vertically to the beam A reinforcing frame composed of left and right vertical frames extending in the longitudinal direction of the pillars inside the two parallel pillars; To increase the adhesion by chipping the surface of the pillar portion, install an adhesive reinforcement plate to cover the vertical frame and the pillar portion with a predetermined distance from the pillar portion and the vertical frame, and to penetrate the adhesive reinforcement plate and the vertical frame A plurality of anchor holes are drilled, and the anchor hole is fixed through the anchor hole with the anchor bolt to fix the adhesive reinforcement plate, and a mortar is poured into the adhesive reinforcement plate to increase the cross section; A connecting steel plate attached to cover at least a portion of the beam and at least a portion of the horizontal frame in the center of the beam and the horizontal frame of the concrete structure; A first fixed steel plate and a second fixed steel plate symmetrically connected to both ends of the connecting steel plate in a horizontal direction; A third fixed steel plate and a fourth fixed steel plate symmetrically attached to a predetermined position of the same height from one side end of the inner side facing the brace of the adhesive reinforcement plate surrounding the expanded column section; And a pair of the braces having a symmetrical structure, connecting one end of the brace to the first fixed steel plate and the second fixed steel plate, and the other end of the brace is connected to the third fixed steel plate and the fourth fixed steel plate, respectively. The brace is composed of a steel brace installed at a predetermined inclination angle, wherein the brace is composed of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe.

In the seismic reinforcement structure using the steel brace according to the present invention, the third fixed steel plate and the fourth fixed steel plate are longitudinally from the lower part on the inner side facing the brace of the adhesive reinforcement plate surrounding the column portion expanded in section 1/ It can be installed in two or more locations.

Seismic reinforcement structure using a steel brace according to the present invention, for a concrete structure consisting of a concrete beam and two parallel pillars connected to the beam, a horizontal frame installed in the horizontal direction at the bottom of the beam, and perpendicular to the beam A reinforcing frame composed of left and right vertical frames which are installed in the longitudinal direction of the pillar portions and are installed inside the two parallel pillar portions connected; To increase the adhesion by chipping the surface of the pillar portion, install an adhesive reinforcement plate to cover the vertical frame and the pillar portion with a predetermined distance from the pillar portion and the vertical frame, and to penetrate the adhesive reinforcement plate and the vertical frame A plurality of anchor holes are drilled, and the anchor hole is fixed through the anchor hole with the anchor bolt to fix the adhesive reinforcement plate, and a mortar is poured into the adhesive reinforcement plate to increase the cross section; A connecting steel plate attached to cover at least a portion of the beam and at least a portion of the horizontal frame in the center of the beam and the horizontal frame of the concrete structure; A first fixed steel plate and a second fixed steel plate symmetrically connected to the lower end of the connecting steel plate; A third fixed steel plate and a fourth fixed steel plate symmetrically attached to a lower end of an inner surface facing the brace of the adhesive reinforcement plate surrounding the expanded columnar section; And the pair of braces are symmetrical, and one end of the brace is connected to the first and second fixed steel plates, respectively, and the other end of the brace is connected to the third and fourth fixed steel plates, respectively, so that the braces are predetermined. It is composed of a steel brace installed at an angle of inclination, wherein the brace is composed of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe.

Seismic reinforcing structure using a steel brace according to the present invention, a concrete frame consisting of a concrete beam and two parallel pillars connected to the beam is horizontally installed at the bottom of the beam and connected vertically to the beam A reinforcing frame composed of left and right vertical frames extending in the longitudinal direction of the pillars inside the two parallel pillars; To increase the adhesion by chipping the surface of the pillar portion, install an adhesive reinforcement plate to cover the vertical frame and the pillar portion with a predetermined distance from the pillar portion and the vertical frame, and to penetrate the adhesive reinforcement plate and the vertical frame A plurality of anchor holes are drilled, and the anchor hole is fixed through the anchor hole with the anchor bolt to fix the adhesive reinforcement plate, and a mortar is poured into the adhesive reinforcement plate to increase the cross section; A first fixed steel plate and a second fixed steel plate symmetrically attached to a predetermined position spaced apart from each other at the same intervals from the opposite ends of the concrete structures; A third fixed steel plate and a fourth fixed steel plate symmetrically attached to one lower surface of the adhesive reinforcing plate surrounding the expanded column portion; And the pair of braces are symmetrical, and one end of the brace is connected to the first and second fixed steel plates, respectively, and the other end of the brace is connected to the third and fourth fixed steel plates, respectively, so that the braces are predetermined. It consists of a steel brace installed at an angle of inclination, wherein the brace consists of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe.

In a seismic reinforcement structure using a steel brace according to the present invention, the inclination angle of the brace is adjusted by adjusting the positions of the beams of the concrete structures of the first fixed steel plate and the second fixed steel plate so that the brace is disposed outside the interior space of the concrete structure. It can be installed while adjusting the degree.

In the seismic reinforcement structure using the steel brace according to the present invention, the anchor bolt is fixed to the beam of the concrete structure by inserting an anchor bolt into the perforated part of the beam of the concrete structure and the top of the connection steel plate, and the horizontal By fixing the lower end of the connecting steel plate to the horizontal frame by fastening the through bolt and the corresponding nut through a bolt coupling hole penetrating the frame and the lower end of the connecting steel plate, the beams of the concrete structure and the upper and lower ends of the connecting steel plate are secured. It can be combined with different bolting methods.

In the earthquake-resistant reinforcement structure using the steel brace according to the present invention, the fixed steel plate may be fixedly attached to the reinforcement frame by anchor bolts.

In the earthquake-resistant reinforcement structure using the steel brace according to the present invention, the damper may include elastic, viscoelastic, friction, steel, oil, and viscous dampers.

In the earthquake-resistant reinforcement structure using the steel brace according to the present invention, the diameter of the damper is larger than the diameter of the bracing steel pipe, and a part of the bracing steel pipe may be inserted into and overlapped in a portion of the damper.

In a seismic reinforcement structure using a steel brace according to the present invention, one or more through-holes may be provided to adjust the length of the braces on both sides of the overlapping portion of the bracing steel pipe inserted into a part of the damper.

In the earthquake-resistant reinforcement structure using the steel brace according to the present invention, the through hole may be bolted through the through hole and a corresponding nut thereof may be fastened.

Seismic reinforced structure using a steel brace equipped with a damper according to the present invention has the following effects.

First, it can be applied to reinforce existing buildings that are not applied to earthquake-resistant reinforcement as well as new buildings, and it maintains space utilization, lighting, and visibility of existing buildings, and the design provides structures that take into consideration existing facilities and aesthetics without rejection. do.

Second, the seismic reinforcing structure according to the present invention is installed with a brace with a damper to secure strength by a brace when there is no vibration such as an earthquake or to improve the behavior of wind loads, and vibration is damped by a damper during an earthquake. It provides a stable structure with little transverse deformation to lateral load.

Third, the seismic reinforcing structure according to the present invention increases the compressive strength of the pillar through the cross-section extension of the concrete pillar portion, and also integrates the expanded cross-section with an adhesive reinforcement plate to integrate with the existing concrete pillars or walls to enable integral behavior with the structure. Therefore, when an earthquake occurs, the existing structure and the seismic reinforcement structure can be prevented from being separated from each other.

Fourth, the seismic reinforcing structure according to the present invention can simplify the construction by using a bolt-nut fastening method in which a damper is coupled in a brace equipped with a damper, and shorten air, and according to the height of the structure and the installation angle of the brace, It is a structure with excellent applicability that can be variably adjusted in length.

Fifth, the brace equipped with dampers assembled from separate members is an efficient method that can be easily replaced if it is damaged by an earthquake. It is easy to remove and replace with a bolt-nut assembly type during plastic deformation or destruction, making maintenance and repair easy. It is easy.

1 is a view showing a structure with a brace applied to the reinforcement frame of the building structure.
FIG. 2 is a view showing the structure installed on the top of the opening and the structure to which the brace including the damper is installed does not interfere with the opening as a first embodiment of the present invention, as viewed from the front.
3 is a perspective view of a structure according to the first embodiment of the present invention.
FIG. 4 is a view showing a structure showing a structure installed outside the opening in a form in which a brace including a damper does not interfere with the opening as a second embodiment of the present invention, and a view of the structure to which it is applied.
5 is a view showing a state in which a brace including a damper as a third embodiment of the present invention is applied to a structure including a columnar section, and a section of the columnar section, which is expanded in section.
6 is a perspective view of a structure according to a third embodiment of the present invention.
7 is a view showing a structure in a state connected to a fixed steel plate installed outside a beam structure including a damper and a brace including a damper, which is installed outside a columnar structure and a fixed steel plate installed outside a beam structure.
8 is a view showing a structure applied to a fixed steel plate installed on one surface of a columnar structure in which a brace including a damper is cross-sectioned and a fixed steel plate installed on one surface of a beam structure as a fifth embodiment of the present invention.
9 is a perspective view and a detailed view showing the brace including the damper of the present invention.

Hereinafter, preferred embodiments in which the object of the present invention can be specifically realized will be described with reference to the accompanying drawings. In describing the present embodiment, the same name and the same code are used for the same configuration, and additional description will be omitted.

In the present invention, unless otherwise defined, the distinction of directions such as left and right and up and down is based on the direction in which each drawing is viewed, and the distinction between horizontal and vertical is perpendicular to the weight direction in a wall or beam or slab, and orthogonal thereto. Define the direction as horizontal.

The present invention is to install a reinforcing frame on the inner surface of a structure composed of a side surface, such as two parallel pillars connecting the beams and the beams located at the top of the opening, and a brace including a damper is disposed so as not to cover the opening. It is a reinforcing structure that improves the rigidity and seismic performance.

When the vibration energy is transmitted to the frame of the structure by the earthquake, the stress acts on the structure, the reinforcement frame connected to the brace is deformed close to the parallelogram, and the vibration energy is absorbed by the damper while the structure is prevented from being damaged and deformed by the earthquake.

1 is a view showing a structure with a brace applied to an opening in which a reinforcement frame is installed, and a reinforcement frame in the form of a square frame composed of a horizontal frame 110 and a vertical frame 120 is installed inside a side surface such as a beam and a pillar portion around the opening. And the brace 200 is composed of a bracing steel pipe 301 and a damper 300 is to be connected to the beam and pillar frame. At this time, one end of the brace 200 is connected to the first fixed steel plate 130 and the second fixed steel plate 140 attached to the horizontal frame 110, and the other end of the brace 200 is a vertical frame 120 ) Is attached to the third fixed steel plate 150 and the fourth fixed steel plate 160 attached to the brace 200 is installed in a form arranged diagonally across the opening.

However, the structure with this type of brace installed does not only harm the aesthetics of the structure, but also causes inconvenience in using the opening, obscuring visibility and obscuring, as the brace covers a part of the opening, causing mutually interfering areas. And ventilation.

The present invention is an invention devised to solve this problem, and the brace provided with a damper is disposed so as not to interfere with the opening when installed in the reinforcement frame, and provides a reinforcement structure that improves strength and seismic performance while considering the aesthetics of the structure. do.

2 to 4 as first and second embodiments of the present invention.

2(a) and 2(b), the first and second embodiments of the present invention include a beam 10 located above the opening and two parallel side surfaces connected to the beam 10 ( 11) A U-shaped reinforcement frame is installed on the inner surface of the structure. That is, the reinforcing frame is a horizontal frame 110, which is installed under the beam 10 in the horizontal direction of the structure surrounding the opening, and the inner side of the two parallel side surfaces 11 connected vertically to the beam 10, respectively, It is composed of left and right vertical frames 120 which are installed to extend in the longitudinal direction.

The reinforcing frame is installed on the beam 10 and the side 11 around the opening to increase the rigidity of the opening, thereby preventing the risk of the opening collapsing by an external force applied to the structure, such as an earthquake.

Since the present invention does not install a horizontal frame located at the bottom of the bottom of the structure among the reinforcement frames installed mainly in the form of a square frame on the inner surface of the structure including the opening, the space occupied by the frame and the manufacturing cost compared to the frame reinforced by the square frame Can be reduced. In other words, it is possible to reduce the erosion of the internal space due to the horizontal frame at the lower end, thereby increasing the openness and utilization of the space and facilitates the installation.

Reinforcing frame except the lower horizontal frame can secure sufficient strength and rigidity by the brace 200 provided with the damper 300 of the present invention. That is, in the function of the reinforcing frame serving to support the gravity load and the horizontal load of the basic frame, the horizontal load burden of the frame is reduced through the brace 200 composed of the damper 300 and the bracing steel pipe 301 of the present invention. To do. Therefore, the present invention reinforces the strength of the horizontal, vertical and joint parts that can occur by excluding the lower horizontal frame by providing a damper 300 member coupled to both ends of the bracing steel pipe 301 to the reinforcement frame.

For the installation of the brace 200 provided with the damper 300, the horizontal frame 110 and the inner side of the left and right sides connected to the horizontal frame 110 are respectively extended and installed in the longitudinal direction of the horizontal frame 110. The fixed steel plates 130, 140, 150, and 160 are attached to the reinforcing frame composed of the left and right vertical frames 120. That is, the first fixed steel plate 130 and the second fixed steel plate 140 are symmetrically attached to a fixed position spaced apart at the same distance from the both ends of the horizontal frame 110, and installed in the longitudinal direction of the left and right sides. The third fixed steel plate 150 and the fourth fixed steel plate 160 are symmetrically attached to a predetermined position of the same height in the longitudinal direction, respectively, from one end of the vertical frame 120.

Thereafter, a pair of braces 200 is symmetrical, and one end of one brace 200 is connected to and fixed to the first fixed steel plate 130 and the other end of the brace 200 is connected to the third fixed steel plate 150. Connect. Likewise, one end of the other brace 200 is fixed by connecting to the second fixed steel plate 140 and the other end of the brace 200 is connected to the fourth fixed steel plate 160 so that a pair of braces 200 is predetermined. It is installed symmetrically while forming an inclination angle of.

At this time, the brace 200 is composed of a bracing steel pipe 301 and a damper 300 provided at both ends of the bracing steel pipe 301. The damper 300 constitutes a part of the brace 200 as a rigid body, and not only serves as a damping function to absorb vibration energy during an earthquake, but also a structure in which the damper 300 is coupled to both ends of the bracing steel pipe 301 Stability can be further increased.

In the present invention, the fixed steel plates 130, 140, 150, and 160 are intended to fix and install the braces 200 on the reinforcing frame, and do not mean that they are fixed to the fixed steel plates 130, 140, 150, 160. , When adjusting the inclination angle so that the brace 200 is disposed in an area that does not interfere with the opening, the fixed steel plates 130, 140, 150, 160 to which the braces 200 are connected may be moved to an appropriate position. It means you can.

In the first embodiment of the present invention, in order to arrange the brace 200 provided with the damper 300 so as not to cover the opening, the lengthwise direction from one side end of the left and right vertical frames 120 as shown in FIG. 2(a). The third fixed steel plate 150 and the fourth fixed steel plate 160 are symmetrically attached to the vertical frame 120 having the same height and higher than the opening, respectively, and the third fixed steel plate 150 and the fourth fixing The first fixed steel plate 130 and the second fixed steel plate 140 attached to the horizontal frame 110 by adjusting a predetermined inclination angle so that the pair of braces 200 attached to the steel plate 160 do not interfere with the openings The other end of the brace 200 is connected to each other.

3 is a perspective view of the first embodiment, the brace 200 is located above the height where the opening is located, the brace 200 is located at the corner of the joint between the horizontal frame 110 and the vertical frame 120. It is a structure that can minimize the phenomenon of obstruction of view due to the window being blocked by 200, secure light, and improve openness.

In addition, when stress such as earthquake resistance occurs, the tensile and compressive forces are shared by the bracing steel pipe 301, and the damper 300 coupled to both ends of the bracing steel pipe 301 is plastically deformed to absorb stress to minimize the impact on the structure. To induce structural stability.

FIG. 4 is a view showing a second embodiment of the present invention. Referring to FIGS. 4(a) and 4(b), the brace 200 provided with the damper 300 of the present invention is arranged so as not to cover the opening. In order to do this, the first fixed steel plate 130 and the second fixed steel plate 140 are positioned at a predetermined position spaced apart at the same distance from the both ends of the horizontal frame 110 horizontally installed at the bottom of the beam 10 located above the opening. ) Is symmetrically attached, and respectively fixed to the lower ends of the left and right vertical frames 120, which are installed in the longitudinal direction and are installed inside the two parallel side surfaces 11 vertically connected to the beam 10, respectively. The steel plate 150 and the fourth fixed steel plate 160 are symmetrically attached.

Thereafter, the pair of braces 200 is symmetrical, and one end of one brace 200 is fixed by being connected to the first fixed steel plate 130 and the other end of the brace 200 is the third fixed steel plate 150 Connect to. Likewise, one end of the other brace 200 is fixed by connecting to the second fixed steel plate 140 and the other end of the brace 200 is connected to the fourth fixed steel plate 160 so that a pair of braces 200 is predetermined. It is installed symmetrically while forming an inclination angle of.

At this time, the first fixed steel plate 130 and the second fixed steel plate (so that the brace 200 with the damper 300 of the present invention can be disposed at a certain position outside the opening so as not to cover the opening) By adjusting the position on the horizontal frame 110 of 140) it can be installed while adjusting the inclination angle of the brace 200.

The second embodiment of the present invention can be applied to a building that requires more structural stability due to a greater lateral load than a normal load. That is, as the structure in which the brace 200 is arranged to reach the horizontal frame 110 from the lower end of the vertical frame 120, the stiffness of the structure relatively using the brace 200 having an extended length of the bracing steel pipe 301. Can be further improved. In addition, as shown in FIG. 4(b), since the brace 200 is installed to be disposed in the outer direction of the opening, it is a method that can be installed without limiting the size of the opening.

When an existing building to be seismic reinforced using a damper-equipped steel brace is obsolete and lacks seismic performance, it can be reinforced by additionally applying a section extension method of the concrete member to improve the flexural strength and shear strength of the concrete member. . That is, it is a reinforcing method that can increase the load carrying capacity while increasing the strength and stiffness when reinforcing the reinforcing bars and pouring concrete.

Particularly, when an earthquake occurs, the pillar portion is easily brittle and destroyed by shear, so it is necessary to reinforce the pillar secondarily to promote insufficient strength. Therefore, it is possible to improve the seismic performance by applying a vibration damping device such as a damper and expanding the section of the pillar in a way to increase the strength and rigidity of the existing building.

In the third to fifth embodiments of the present invention, to increase the strength and stiffness, the pillar portion 20 is enlarged in cross-section, and a vibration damping device such as a brace 200 equipped with a damper 300 is applied to improve seismic performance. A structure that can be improved will be described with reference to FIGS. 5 to 8.

The third, fourth, and fifth embodiments of the present invention are described in the concrete structure composed of a concrete beam 10 and two parallel pillars 20 vertically connected to the beam 10, as described below. Reinforcement frame is installed and the construction method of extending the section of the column 20 is applied.

FIG. 5 is a view showing that the brace 20 of the present invention is disposed so as not to cover an opening in a structure including the columnar section 20 of the present invention, the concrete beam 10 and the beam 10. In a concrete structure composed of two parallel pillars 20 connected vertically, a horizontal frame 110 installed horizontally at the bottom of a beam 10 and two parallel pillars vertically connected to the beam 10 A reinforcement frame consisting of left and right vertical frames 120 installed in the longitudinal direction of the pillar portion 20 is installed on the inner side of (20). The H-shaped steel is installed as a reinforcing frame to improve the structural performance of the member.

Figure 5 (a) is an embodiment of a structure including a columnar section 20 is enlarged and Figure 5 (b) shows a cross-sectional view of the column section 20 is expanded. Referring to Figure 5 (b), the reinforcement 190 is arranged in a U-shaped around the vertical frame 120, such as H-beams to reinforce the column section 20 by cross-section extension, and the adhesion when pouring concrete In order to improve, the pillar portions 20 of the existing concrete structure are chipped and roughly treated, and then, at predetermined intervals from the pillar portions 20 and the vertical frame 120 of the concrete structure, the pillar portions 20 and the vertical The adhesive reinforcement plate 170 is installed to surround the frame 120. It is possible to improve the toughness of the pillar portion 20 by attaching the adhesive reinforcing plate 170 so as not to cause a rapid shear failure against the shear force generated by the earthquake. A plurality of anchor holes are drilled so that the adhesive reinforcement plate 170 penetrates the vertical frame 120, and then the anchor holes are fixed through the anchor bolt 600 so that the adhesive reinforcement plate 170 is fixed. The mortar 500 is poured into the adhesive reinforcing plate 170 to cross-section the pillar portion 20.

Thereafter, referring to FIGS. 5(a) and 6 as a third embodiment of the present invention, at least a portion of the beam 10 and the horizontal in the center of the beam 10 and the horizontal frame 110 of the concrete structure A connecting steel plate 180 covering at least a portion of the frame 110 is attached, and the first fixed steel plate 130 and the second fixed steel plate 140 are symmetrically connected to both ends of the connecting steel plate 180 in the horizontal direction. The third fixed steel plate 150 and the fourth fixed steel plate are located at a constant position of the same height from one end of the inner surface facing the brace 200 of the adhesive reinforcement plate 170 surrounding the expanded column portion 20. 160) is symmetrically attached.

The connecting steel plate 180 is located at the center of the beam 10 and the horizontal frame 110 to prevent local buckling by providing a support point of a predetermined interval on the horizontal beam 10 and the horizontal frame 110. do.

A pair of the braces 200 composed of a bracing steel pipe 301 and a damper 300 provided at both ends of the bracing steel pipe 301 are disposed in the structure as a symmetrical structure, and one end of the brace 200 is fixed to the first The steel plate 130 and the second fixed steel plate 140 are respectively connected, and the other end of the brace 200 is connected to the third fixed steel plate 150 and the fourth fixed steel plate 160, respectively, and the brace 200 is connected. ) Is installed at a predetermined inclination angle.

The cross sections are enlarged such that the braces 200 are symmetrically disposed at each corner between the beam 10 of the concrete structure and the inner surface of both sides of the horizontal frame 110 and the inner side of the pillar section 20. The third fixed steel plate 150 and the fourth fixed steel plate 160 at a position of 1/2 or more in the longitudinal direction from the lower end on the inner surface facing the brace 200 of the adhesive reinforcement plate 170 surrounding the pillar portion 20 ) Can be installed. That is, it means that it can be located at the top of the middle or more of the pillar portion 20 at a height based on the longitudinal direction of the pillar portion 20 from the bottom of the bottom surface of the pillar portion 20 that has been enlarged in section.

That is, in the third embodiment, since the brace 200 is positioned at an edge portion between the horizontal frame 110 and the column section 20, the opening is obstructed by the brace 200, obstructing the field of view and utilizing space. It is a form that can minimize the phenomenon that the constraints of can be secured mining and improve the open feeling.

7 is a fourth embodiment of the present invention, the connection of covering at least a portion of the beam 10 and the horizontal frame 110 in the center of the beam 10 and the horizontal frame 110 of the concrete structure The steel plate 180 is attached, and the first fixed steel plate 130 and the second fixed steel plate 140 are symmetrically connected to the lower end of the connecting steel plate 180, and then the pillar portion 20 is enlarged in cross section. The third fixed steel plate 150 and the fourth fixed steel plate 160 are symmetrically attached to the lower end of the inner surface facing the brace 200 of the adhesive reinforcement plate 170.

The fourth embodiment can be applied to a building that requires more structural stability because the lateral load is greater than the normal load. That is, the length of the bracing steel pipe 301 so that the brace 200 is disposed on the connecting steel plate 180 attached to the beam 10 and the horizontal frame 110 from the lower end of the inner surface of the column portion 20 that has been enlarged in section. By arranging the elongated brace 200, the rigidity of the structure can be further improved relatively.

In addition, the first steel plate 130 and the second fixed steel plate 140 connected to the connecting steel plate 180 and the connecting steel plate 180 are located at the center of the beam 10 and the horizontal frame 110, thereby concentrating the load. It supports the central point to receive local buckling.

In the third and fourth embodiments of the present invention, a bolt is inserted into a perforated portion of a beam 10 of a concrete structure and a connecting steel plate 180, and the connecting steel plate 180 is inserted into the beam 10 of the concrete structure. The upper end of the anchor bolt is fixed, and the lower end of the horizontal frame 110 and the connecting steel plate 180 is fastened to the through bolt through a bolt coupling hole penetrating the horizontal frame 110 and the connecting steel plate 180. By fixing, the upper and lower ends of the connecting steel plate 180 are coupled by different bolting methods according to the object to be joined.

Then, a pair of braces 200 composed of a bracing steel pipe 301 and a damper 300 provided at both ends of the bracing steel pipe 301 as a symmetrical structure, one end of the brace 200 is the first fixed steel plate 130 ) And the second fixed steel plate 140, and the other ends of the braces 200 are respectively connected to the third fixed steel plate 150 and the fourth fixed steel plate 160 to predetermined the brace 200. Install at an angle of inclination.

The fourth embodiment of the present invention is a fixed steel plate (150, 160) and a beam (10) installed outside the structure of the columnar section (20) in which the brace (200) including the damper (300) is cross-sectionally expanded in a form that does not interfere with the opening. ) As a structure connected to the fixed steel plates 130 and 140 installed outside the structure, even when the concrete structure reaches the final destruction, the brace 200 member provided with the damper 300 installed outside the structure is not damaged and is intact. Effect can be secured.

In particular, since the aged structure is in a state where the strength of concrete is lowered and micro-cracks are generated, it may be easily destroyed when a reinforcing member such as a fixed steel plate and a brace is directly connected to the structure, and the reinforcement effect of the brace may be halved. have. Therefore, the third and fourth embodiments of the present invention are applicable to such an aged building, and the connecting steel plate 180 attached to the beam 10 and the horizontal frame 110, and the connecting steel plate 180 ), the fixed steel plates (130, 140, 150, 160) and the braces 200 attached thereto are installed outside the structure to disperse the earthquake loads to the structure to prevent local destruction.

8 is a view showing a fifth embodiment of the present invention, the first fixed steel plate 130 and the second fixed steel plate 140 at a certain position spaced apart at the same interval from the both ends of the beam 10 of the concrete structure inwardly ) Is symmetrically attached, and the third fixed steel plate 150 and the fourth fixed steel plate 160 are symmetrically attached to the lower surface of the adhesive reinforcement plate 170 surrounding the expanded columnar section 20. .

Then, a pair of braces 200 composed of a bracing steel pipe 301 and a damper 300 provided at both ends of the bracing steel pipe 301 as a symmetrical structure, one end of the brace 200 is the first fixed steel plate 130 ) And the second fixed steel plate 140, and the other ends of the braces 200 are respectively connected to the third fixed steel plate 150 and the fourth fixed steel plate 160 to predetermined the brace 200. Install at an angle of inclination.

At this time, the braces 200 may be provided with the first to fourth fixed steel plates 130, 140, 150, 160 so as to be disposed outside the interior space of the concrete structure, the damper 300 of the present invention is provided The brace 200 is adjusted to the inclination angle so as to be disposed outside the interior space, for example, by adjusting the positions of the first fixed steel plate 130 and the second fixed steel plate 140 on the beam 10 of the concrete structure. It is a structure that can be installed without limiting the size of the opening because it is installed while adjusting the inclination angle of the brace 200 and does not cover the opening.

In the fifth embodiment, the first to fourth fixed steel plates 130 and 140 are directly attached to a concrete structure composed of a concrete beam 10 and two parallel cross-section columns 20 connected to the beam 10. 150, 160) by connecting the brace 200 with the damper 300, it is easy to construct by minimizing additional members, and the existing structure and brace 200 of the concrete beam 10 and the columnar section 20 are enlarged. The reinforcing member is a reinforcing structure with integral behavior. By securing the integrity between the existing structure of the concrete beam (10) and the columnar section (20) that has been enlarged in cross section and reinforcing members such as a brace (200) equipped with a damper (300), a problem that can be detached between members is prevented for a long period of time. It can maintain the durability of.

The earthquake-resistant reinforcement structure according to the present invention increases the compressive strength of the pillar through the cross-section extension of the concrete pillar portion 20, and also integrates the expanded cross-section with an adhesive reinforcement plate 170 to integrate the existing concrete pillar or wall with the structure. Since it is possible to integrally act with, it is possible to improve the load carrying capacity and prevent the phenomenon that the existing structure and the seismic reinforcement structure are separated from each other in the event of an earthquake.

That is, it is a reinforced structure that combines and complements the advantages of the section extension method of the pillar portion 20 and the reinforcement method by the brace 200 provided with the damper 300.

The brace 200 of the present invention has a bracing steel pipe 301 and a damper 300 coupled to both ends of the bracing steel pipe 301, whereby the brace 200 maintains an equilibrium state of force, thereby providing It can suppress sudden earthquake displacement and attenuate the magnitude of vibration caused by the earthquake.

In particular, the damper 300 of the present invention is installed on both ends of a pair of bracing steel pipes 301 symmetrically installed on the structure, and the four dampers 300 independently absorb and absorb seismic energy to effectively absorb energy transmitted to the structure. Cut off.

That is, the damper 300 can greatly reduce the crack size by absorbing the vibration energy of the structure through energy dissipation by hysteretic behavior. In particular, when an earthquake occurs, the damper 300 causes elastic deformation and plastic deformation and absorbs energy to minimize damage to the structure. Since the shear force is concentrated on the brace 200 having high lateral stiffness, the damper 300 is installed at both ends of the bracing steel pipe 301 to dissipate the vibrational energy caused by the earthquake, thereby securing rigidity while maximizing ductility and securing seismic performance. do.

In the present invention, the damper 300 is a damping damper, a hydraulic damper such as a steel damper, a lead damper, a friction damper, a hysteretic damper, an oil damper, a viscoelastic damper, or the like. Preferably, a hydraulic damper is used.

The hydraulic damper is a damper that uses the hydraulic pressure of the fluid in the cylinder, and when vibration energy is generated by the seismic wave, it is possible to absorb the shaking of the structure using the fluid resistance of the fluid filled inside the hydraulic damper. Damping force is generated by fluid flow and effectively reduces vibration. In particular, the viscous damper has a feature of providing a large and stable damping force by using a highly sensitive viscous oil, and amplifies the displacement generated in the structure variably to easily exert a damping function even for micro displacement.

That is, the brace 200 is compressed by the hydraulic cylinders of both the dampers 300, when the other is compressed, the other is compressed, and when the other is compressed, the other is stretched, and the external force is a damper installed at the end of the bracing steel pipe 301, respectively. Attenuated at 300.

In the present invention, the coupling of the damper 300 in the brace 200 member is made by partially inserting the bracing steel pipe 301 into the damper 300 as shown in FIG. 9. Since the diameter of the damper 300 is larger than the diameter of the bracing steel pipe 301, a portion of the bracing steel pipe 301 is inserted into a portion of the damper 300 to form an overlapping portion.

One or more through holes 400 are formed on both sides of the bracing steel pipe 301 and the damper 300 so that bolts can penetrate the overlapping portion on the overlapping portion where the bracing steel pipe 301 and the damper 300 are combined. . In other words, a portion of both ends of the bracing steel pipe 301 and a damper 300 overlapping with each other are formed in the same position, respectively, so that the bracing steel pipe 301 is inserted into the damper 300. By adjusting the overlapping positions of the bracing steel pipe 301 and the damper 300 to match the through holes 400, the length of the entire brace 200 can be increased or decreased.

When working in the field, the length of the brace 200 may be short or short because the length of the brace 200 required according to the size and shape of the structure is difficult to accurately determine, and the brace 200 according to the present invention is a bracing steel pipe Since a portion of the portion 301 and the damper 300 overlap one or more through holes 400, the bolts penetrate the appropriate through holes 400 according to the required length of the brace 200 according to the site structure. And the damper 300 can be coupled by fastening the nut to the pierced bolt.

As described above, the earthquake-resistant reinforcement structure according to the present invention can be easily applied in a form that does not cover openings in various structures since the length of the structure and the installation angle of the brace 200 can be variably adjusted. , The bracing steel pipe 301 and the damper 300, which are assembled by bolt-nut fastening as separate members, are efficient vacuum methods that can be easily replaced when damaged by an earthquake, and can be removed and replaced when plastic deformation or destruction occurs. Easy maintenance and repair.

Therefore, the seismic reinforcing structure of the present invention can be applied to existing buildings as well as new buildings, and is suitable for seismic reinforcing of buildings such as schools that require a short construction period and economical and sufficient seismic reinforcing effect. In particular, it is a simple process that can be finished by inserting a reinforcement frame excluding the bottom frame on the inside surface of the structure, and it has a higher economic efficiency than the structure applied with the general construction method.

In addition, since the brace 200 provided with the damper 300 is installed so as not to cover the opening, there is an effect of eliminating the restriction of utilization of the opening and not impairing the aesthetics compared to the structure of the conventional opening.

In the present invention, a reinforcing member for a structure composed of a side surface 11, such as a beam 10 located at the top of an opening and two parallel pillar portions 20 connecting both sides of the beam, the horizontal frame 110 and the vertical frame Reinforcement frame composed of 120, first to fourth fixed steel plates 130, 140, 150, 160, adhesive reinforcement plate 170, connecting steel plate 180, bracing steel pipe 301, and bracing steel pipe 301 The brace 200 composed of the dampers 300 provided at both ends may be used, but is not limited thereto.

The accompanying drawings are not shown according to scale, but partially enlarged and reduced to illustrate the technical idea of the present invention.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, it will be understood by those skilled in the art that the present invention may be implemented in other specific forms without changing its technical spirit or essential features. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

10: Bo
11: side
20: pillar
110: horizontal frame
120: vertical frame
130: first fixed steel sheet
140: second fixed steel sheet
150: third fixed steel sheet
160: fourth fixed steel sheet
170: adhesive reinforcement plate
180: connecting steel sheet
190: Rebar
200: Brace
300: damper
301: bracing steel pipe
400: through hole
500: mortar
600: anchor bolt

Claims (15)

delete delete As a concrete structure reinforced seismically using a steel brace, a structure consisting of a beam located at the top of the opening and two parallel sides connected to the beam,
A reinforcement frame composed of a horizontal frame installed in the horizontal direction at the bottom of the beam, and left and right vertical frames extending in the longitudinal direction, respectively, on two parallel sides vertically connected to the beam;
A first fixed steel plate and a second fixed steel plate symmetrically attached to a predetermined position spaced apart at equal intervals from the both ends of the horizontal frame;
A third fixed steel plate and a fourth fixed steel plate symmetrically attached to lower end portions of the left and right vertical frames of the side surface; And
The pair of braces have a symmetrical structure, and one end of the brace is connected to the first fixed steel plate and the second fixed steel plate, respectively, and the other end of the brace is connected to the third fixed steel plate and the fourth fixed steel plate, respectively. Is composed of a steel brace that is installed at a predetermined angle of inclination,
At this time, the brace is a structure using a steel brace, characterized in that consisting of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe. According to claim 3,
The brace having the damper connected to one end of the brace to the first fixed steel plate and the second fixed steel plate and the other end of the brace to the third fixed steel plate and the fourth fixed steel plate so as not to cover the opening. Structure using a steel brace characterized in that it is installed while adjusting the inclination angle of the brace by adjusting the positions on the horizontal frame of the first fixed steel plate and the second fixed steel plate so that they can be disposed at a certain position outside the opening. . A concrete structure consisting of a concrete beam and two parallel pillars connected to the beam, which is seismic reinforced using a steel brace,
A reinforcement frame composed of a horizontal frame installed horizontally at the bottom of the beam, and left and right vertical frames extending in the lengthwise direction of the two pillar sections connected vertically to the beam;
Chipping the surface of the pillar to increase the adhesion;
An adhesive reinforcement plate is installed to cover the vertical frame and the column at a predetermined distance from the column and the vertical frame;
Punching a plurality of anchor holes to penetrate the adhesive reinforcement plate and the vertical frame;
Fixing the adhesive reinforcement plate through the anchor hole with an anchor bolt so as to be fixed;
A pillar section in which a mortar is poured into the adhesive reinforcing plate to increase its cross section;
A connecting steel plate attached to cover at least a portion of the beam and at least a portion of the horizontal frame in the center of the beam and the horizontal frame of the concrete structure;
A first fixed steel plate and a second fixed steel plate symmetrically connected to both ends of the connecting steel plate in a horizontal direction;
A third fixed steel plate and a fourth fixed steel plate symmetrically attached to a predetermined position of the same height from one end of the inner side facing the brace of the adhesive reinforcement plate surrounding the expanded column section; And
The pair of braces have a symmetrical structure, and one end of the brace is connected to the first fixed steel plate and the second fixed steel plate, respectively, and the other end of the brace is connected to the third fixed steel plate and the fourth fixed steel plate respectively. Is composed of a steel brace that is installed at a predetermined angle of inclination,
At this time, the brace is a structure using a steel brace, characterized in that consisting of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe. The method of claim 5,
The third fixed steel plate and the fourth fixed steel plate is a steel material characterized in that it can be installed at a position of at least 1/2 in the longitudinal direction from the lower end on the inner side facing the brace of the adhesive reinforcing plate surrounding the expanded section in section. Structure using braces. A concrete structure consisting of a concrete beam and two parallel pillars connected to the beam, which is seismic reinforced using a steel brace,
A reinforcement frame composed of a horizontal frame installed in the horizontal direction at the bottom of the beam, and a left and right vertical frame extending in the longitudinal direction of the column in two parallel pillar parts vertically connected to the beam;
Chipping the surface of the pillar to increase the adhesion;
An adhesive reinforcement plate is installed to cover the vertical frame and the pillar at a predetermined distance from the pillar and the vertical frame;
Punching a plurality of anchor holes to penetrate the adhesive reinforcement plate and the vertical frame;
Fix the adhesive reinforcement plate through the anchor hole with an anchor bolt to be fixed;
A pillar section in which a mortar is poured into the adhesive reinforcing plate to increase its cross section;
A connecting steel plate attached to cover at least a portion of the beam and at least a portion of the horizontal frame in the center of the beam and the horizontal frame of the concrete structure;
A first fixed steel plate and a second fixed steel plate symmetrically connected to the lower end of the connecting steel plate;
A third fixed steel plate and a fourth fixed steel plate symmetrically attached to a lower end of an inner surface facing the brace of the adhesive reinforcement plate surrounding the expanded columnar section; And
The pair of braces have a symmetrical structure, and one end of the brace is connected to the first and second fixed steel plates, respectively, and the other end of the brace is connected to the third and fourth fixed steel plates, respectively, so that the brace has a predetermined inclination angle. It consists of a steel brace that is installed on the road,
At this time, the brace is a structure using a steel brace, characterized in that consisting of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe. A concrete structure consisting of a concrete beam and two parallel pillars connected to the beam, which is seismic reinforced using a steel brace,
A reinforcement frame composed of a horizontal frame installed in the horizontal direction at the bottom of the beam, and a left and right vertical frame extending in the longitudinal direction of the column in two parallel pillar parts vertically connected to the beam;
Chipping the surface of the pillar to increase the adhesion;
An adhesive reinforcement plate is installed to cover the vertical frame and the pillar at a predetermined distance from the pillar and the vertical frame;
Punching a plurality of anchor holes to penetrate the adhesive reinforcement plate and the vertical frame;
Fix the adhesive reinforcement plate through the anchor hole with an anchor bolt to be fixed;
A pillar section in which a mortar is poured into the adhesive reinforcing plate to increase its cross section;
A first fixed steel plate and a second fixed steel plate symmetrically attached to a predetermined position spaced apart from each other at the same intervals from the opposite ends of the concrete structures;
A third fixed steel plate and a fourth fixed steel plate symmetrically attached to one lower surface of the adhesive reinforcing plate surrounding the expanded column portion; And
The pair of braces have a symmetrical structure, and one end of the brace is connected to the first and second fixed steel plates, respectively, and the other end of the brace is connected to the third and fourth fixed steel plates, respectively, so that the brace has a predetermined inclination angle. It consists of a steel brace that is installed on the road,
At this time, the brace is a structure using a steel brace, characterized in that consisting of a bracing steel pipe and a damper provided at both ends of the bracing steel pipe. The method of claim 8,
Steel material characterized in that it can be installed while adjusting the angle of inclination of the brace by adjusting the positions of the concrete structures of the first fixed steel plate and the second fixed steel plate so that the brace is disposed outside the interior space of the concrete structure. Structure using braces. The method of claim 5 or 7,
The anchor bolt is fixed to the beam of the concrete structure by inserting an anchor bolt into the perforated part of the beam of the concrete structure and the top of the connection steel sheet,
By fixing the lower end of the connecting steel plate to the horizontal frame by fastening the through bolt and the corresponding nut through the bolt coupling hole passing through the horizontal frame and the lower end of the connecting steel plate, the beam of the concrete structure and the upper end of the connecting steel plate and Structure using a steel brace, characterized in that the bottom is coupled by different bolting methods. The method of claim 3, 5, 7, or 8,
The fixed steel plate is a structure using a steel brace, characterized in that fixed to the reinforcement frame by an anchor bolt. The method of claim 3, 5, 7, or 8,
The damper is a structure using a steel brace, characterized in that it comprises elastic, viscoelastic, friction, steel, oil, viscous damper. The method of claim 3, 5, 7, or 8,
The diameter of the damper is larger than the diameter of the bracing steel pipe, a structure using a steel brace, characterized in that a portion of the bracing steel pipe is inserted into and overlapped in a portion of the damper. The method of claim 3, 5, 7, or 8,
A structure using a steel brace, characterized in that one or more through holes are provided to adjust the length of the braces on both sides where the part of the bracing steel pipe is inserted and overlapped in a part of the damper. The method of claim 14,
The through hole is a structure using a steel brace, characterized in that a bolt passes through the through hole and a corresponding nut is fastened.

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