KR101364922B1 - Buckling-Restrained Braces - Google Patents

Abstract

The weak-axis reinforced non-buckling brace of the present invention is a brace for reinforcing a steel structure consisting of steel pillars and beams, the core material formed of H-shaped steel consisting of a web and a flange; A first reinforcing member which is formed of a cross-section main body and a first coupling part having a shape in which both ends of the body are bent outwardly and coupled to each other in both directions of the flange of the core material so as to surround the central portion in the longitudinal direction of the core material; And a second reinforcing member formed between the core member and the first reinforcing member in the longitudinal direction of the core member, the main body forming a concave portion having a trapezoidal cross-sectional shape and bent portions formed by bending both ends of the main body. Not only to improve the tension to receive but also to prevent buckling during compression to reinforce to secure the compression strength in the tension brace to form a non-buckling brace.

Description

Weakly Reinforced Non-buckling Braces {Buckling-Restrained Braces}

The present invention relates to a weak axial reinforcement type non-buckling brace, more specifically, to configure the first reinforcement to surround the core formed of H-shaped steel, and to configure the second reinforcement in the longitudinal direction of the core between the first reinforcement and the core By strengthening the weak axis of the core and enlarging the cross section of the core to improve the cross-sectional performance, it is possible not only to receive tension but also to prevent the buckling during compression. It is about.

In general, steel structures have been widely used in infrastructure facilities and plants, and existing structures have been designed to meet the requirements of national design (earthquake) standards at the time. However, The seismic design criteria is judged to be the installation of reinforcement structures through the reinforcement design of existing facilities. Most of the braces are designed to receive tensile force and have a large slenderness ratio. When they receive compressive force, they cause elastic buckling, failing to function as a brace.

As a background of the present invention, there is a patent registration No. 0938978 entitled " new buckling buckle and new buckling buckle unit "(Patent Document 1).

In the background art, as shown in Figure 5 hollow tube 50; A hollow metallic core 60 of the hollow tube 50; The core 60 is fixed at equal intervals along the outer circumferential surface of the core 60 and inserted into the hollow tube 50 together with the core 60. The outer circumferential surface of the core 60 is closely contacted with the inner circumferential surface of the hollow tube 50, And a plurality of flat metal rings (70) which are supported on the tube (50) and frictionally sliding with the inner circumferential surface of the hollow tube (50) upon deformation of the hollow tube (50) according to axial force.

However, the background art is difficult to apply to the H-shaped steel used in many conventional steel structures, and there is a problem in that the composition is complicated and difficult to manufacture, such as separately configuring the metal core 60.

Patent No. 0938978 entitled "Unbuckling bird and thus unbuckling bird unit"

The present invention is to solve the above problems, by configuring the reinforcement to surround the core formed of H-shaped steel to increase the cross-section radius of the brace of the large equipment to reduce the thin equipment and increase the buckling strength to improve the cross-sectional performance The purpose of the present invention is to provide a weak-axis reinforced non-buckling brace that can be subjected to tension and compression at the same time to prevent buckling even during compression.

The present invention is a brace for reinforcing a steel structure consisting of steel pillars and beams, the core material formed of H-shaped steel consisting of a web and a flange; A first reinforcing member which is formed of a cross-section main body and a first coupling part having a shape in which both ends of the body are bent outwardly and coupled to each other in both directions of the flange of the core material so as to surround the central portion in the longitudinal direction of the core material; Weak reinforcement ratio formed of a second reinforcing member formed between the core member and the first reinforcing member in the longitudinal direction of the core material, the main body forming a concave portion in the trapezoidal cross-sectional shape and bent at both ends of the main body; To provide buckling braces.

In addition, the first coupling portion may be formed to extend the reinforcing coupling portion of the shape bent outward.

In addition, the first reinforcing material is made of a combination of the a-shaped bending member, the mutually coupled end of the bending member may be configured to form a second coupling portion of the shape bent outward, the second coupling portion is bent outward The shape of the reinforcing coupling portion can be extended.

In addition, the concave portion of the main body of the second reinforcing material can be configured to be filled with a filler.

In addition, the reinforcing member may be further configured to be introduced between the first coupling portion of the first reinforcing material to be coupled to each other so that the end portion is in contact with the longitudinal direction of the central portion of the body of the second reinforcing material.

The weak-shaft reinforced non-buckling brace of the present invention configures the reinforcement to surround the core formed of the H-shaped steel, reinforces the weak axis of the core web and enlarges the cross section of the core to improve the cross-sectional performance, so that not only the tension is applied but also the compression. It is very useful to increase the stability of steel structure by inducing stable hysteretic behavior even under repeated loads such as earthquakes by preventing buckling.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a view showing an embodiment of the installation state of the weak-axis reinforced non-buckling brace of the present invention,
2 is a cross-sectional view taken along line AA of FIG. 1;
3 is a cross-sectional view of a first embodiment along the line BB of FIG. 1;
4 is a cross-sectional view of a second embodiment along the line BB of FIG. 1;
5 is a cross-sectional view of a third embodiment along the line BB of FIG. 1;
6 is a cross-sectional view of a fourth embodiment along the line BB of FIG. 1;
7 is a perspective view of a buckling brace according to a conventional embodiment.

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

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

1 is a view showing an embodiment of the installation state of the weak axis reinforced non-buckling brace of the present invention.

As shown in Figure 1, the non-buckling brace 10 of the present invention is used as a brace to reinforce the steel structure consisting of steel pillars 2 and beams (3).

In general, braces under tension can be compressed by compressive forces during an earthquake, and structures such as plants are pin-bonded, so the only transverse resistance element is brace. However, because the brace is designed to be subjected to a tensile force, the large equipment is large, the elastic buckling caused by the compression force does not play the role of the brace, so in the weak-shaft reinforcement non-buckling brace (1) of the present invention to weaken the weak axis of the core (1) The first reinforcing material 100 and the second reinforcing material 200 configured in the longitudinal direction of the core material 10 in a trapezoidal cross-sectional shape to reinforce, thereby increasing the cross-sectional secondary radius to secure the compressive strength in the tension brace To form a non-buckled brace.

On the other hand, the weak-shaft reinforced non-buckling brace 1 of the present invention as described above may be coupled to the beam (3) at both ends, or coupled to the center of the column (2) and the beam (3) by various methods.

 In the embodiment of the present invention, the brace plate (4) is provided between the beam (3) and the weak-axis reinforced non-buckling brace (1), respectively, the brace (1) and the brace plate (4) is a welding and connecting member (5) It is configured to be connected by).

2 is a cross-sectional view taken along the line A-A of FIG.

The weak-shaft reinforcing non-buckling brace 1 of the present invention is a core material 10 formed of H-shaped steel and the first reinforcing material 100 and a trapezoid configured to surround the outside by coupling the core material 10 in both directions of a flange. The second reinforcement 200 is configured in the longitudinal direction of the core material 10 in the cross-sectional shape.

3 is a cross-sectional view of the first embodiment taken along the line B-B of FIG.

As shown in FIG. 3, the first reinforcing material 100 includes a main body 110 having a c-shaped cross section and a first coupling part 120 having both ends of the main body 110 bent outward. The body 110 of the first reinforcement 100 is positioned in such a manner as to cover the flange of the core 10 on both sides, and the first coupling portion 120 of the first reinforcing material 100 facing each other may be bolted, welded, or the like. Combine the first two reinforcing materials (100) facing each other by a combination.

The core 10 uses H-beams, which are manufactured in the factory to have two axial directions, and are effective when used as a beam member. In order to reduce the buckling effect when the compressive force is applied, the H-shaped steel should be reinforced in a section of the section. In other words, reinforcement of the weak axis is required for the H-beam.

The core material 10 and the first reinforcing material 100 are non-attached so that there is no direct coupling surface to reinforce only the buckling of the core material 10, but only by the mutual coupling of the first reinforcing material 100, the first reinforcing material 100 ) Is fixedly coupled to the outside of the core material (10).

The main body 110 of the first reinforcing material 100 is configured in a U-shaped cross-sectional shape, so as to cover the flange portion of the core 10. That is, the flange of the core 10 is drawn into the concave portion of the main body 100, both ends of the main body 110 is to be located in the center of the web of the core 10. Both ends of the first reinforcing material 100 constitute a first coupling portion 12 having a shape that is bent outwardly, which is the first contacting when the first reinforcing material 100 is coupled in both flange directions of the core material 10. In order to increase the buckling strength by increasing the contact area of the reinforcement 100 to facilitate the coupling, and to increase the cross-sectional secondary radius of the core 10 made of H-shaped steel to strengthen the weak axis. With this configuration, the compression resistance can be secured by the sectional strength of the bracing.

The first reinforcing material 100 is coupled to the central portion in the longitudinal direction except for both ends of the core material (10).

4 is a cross-sectional view of a second embodiment along the line B-B in FIG.

The second reinforcement 200 has a main body 210 having a long side open in a trapezoidal cross section, and forms a concave portion 211 that is a concave portion of the main body 210. The concave portion 211 of the second reinforcement 200 is to be interviewed with the web of the beam 3. In addition, a coupling portion 220 having a shape in which both ends of the main body 210 of the second reinforcement 200 is bent is formed, and the coupling portion 220 is formed in a shape bent outwardly at both ends of the main body 210. The coupling portion 220 can be seated at the end of the flange of the beam (3).

The core 10, the first reinforcing material 100 and the second reinforcing material 200 are non-attached so that there is no surface to be directly coupled to reinforce only the buckling of the core 10, the second reinforcing material 200 is the first reinforcing material Is coupled to (100), it is fixed to the outside of the core material 10 by the mutual coupling of the first reinforcing material (100).

The first reinforcing material 100 and the second reinforcing material 200 may be made of various materials such as steel, composite materials such as FRP, aluminum.

5 is a cross-sectional view of the third embodiment along the line B-B in FIG. As shown in FIG. 5, the concave portion 211 may be filled with the filler 212 to further secure the compressive strength of the core material 10 having a large size. The filler 212 may use various fillers such as concrete.

The filler 212 is in contact with the core 10 so as not to be directly coupled to each other, and the end of the filler 212 and the web of the core 10 allow slip to occur. In addition, the hollow 213 may be formed in the filler to reduce the weight.

As shown in Figure 4 and 5, the first coupling portion 120 of the first reinforcing material 100 may be to form a reinforcing coupling portion 121 in a shape bent once to the outside. This is to reinforce the weak axis by additionally increasing the cross section and increasing the rigidity against the buckling to the bent shape once more.

The main body 110 is made of a combination of the a-shaped bending members (110a) (110b), the end of the mutually coupled ends of the bending members (110a) (110b) the second coupling portion 130 of the shape bent outwardly Can be configured.

The main body 110 may be formed of one member as described above, but may also be formed of a combination of two members having the same shape. In order to combine the two members of the same shape, the main body 110 of the first reinforcing material 100 is to be made of a combination of the a-shaped bending members (110a) (110b).

In order to facilitate the mutual coupling of the two bending members 110a and 110b, the portion where the bending members 110a and 110b abut each other is bent to the outside to form the second coupling portion 130. The second coupling portion 130 has a shape in which one end of the bending members 110a and 110b is bent, and the bending members 110a and 110b are formed by mutual coupling of the second coupling portions 130. It will be integrated to form the reinforcement (100). At this time, the other end of the bending member (110a, 110b) forming both ends of the reinforcing material 100 is the first coupling portion of the shape in which the first reinforcing material 100 is bent outwardly the same as the shape consisting of one member ( 120 is configured.

As described above, the second coupling portion 130 may have the same shape as the reinforcement coupling portion 121 of the first coupling portion 120, such that the reinforcement coupling portion 131 of the shape bent outwardly extends. have.

This is to reinforce the weak axis by additionally increasing the cross section and bending it once more.

6 is a cross-sectional view of the fourth embodiment taken along the line B-B of FIG.

As shown in FIG. 6, the first reinforcing member 100 is joined between the first coupling parts 120 to be coupled to each other so that the end portion thereof is in contact with the longitudinal direction of the central portion of the main body 210 of the second reinforcing material 200. Auxiliary reinforcement member 300 is configured to be further configured.

As such, configuring the auxiliary reinforcing member 300 is configured to reinforce the weak axis of the core material 10, the end of the auxiliary reinforcing member 300 is coupled to the central portion of the main body 210 of the second reinforcing material (200) It is configured.

Coupling of the auxiliary reinforcing member 300, when the first coupling portion 120 of the reinforcing material 100 is coupled to each other, the auxiliary reinforcing member 300 is also coupled together. Since the auxiliary reinforcing member 300 is sandwiched between the first coupling portion 120 of the reinforcing material 100 to be coupled to each other, at the time of mutual coupling of the first coupling portion 120 of the reinforcing material 100 to be mutually coupled Auxiliary reinforcement member 300 is also coupled together, so as to be integral with the reinforcement 100.

The auxiliary reinforcing member 300 may be any one of a cross-section plate type, T type, I type.

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

1: buckling brace
2: pillar
3: Bo
4: Brace plate
5:
10: heartwood
100: first reinforcing material
110:
110a, 110b: bending member
120: first coupling part
121, 131: reinforcing coupling portion
130: second coupling part
200: second reinforcement
210:
211: recess
212 filling material
220: coupling part
300: auxiliary reinforcing member

Claims (6)

In a brace to reinforce a steel structure made up of a steel column (2) and a beam (3)
Core material 10 formed of H-shaped steel consisting of the web 11 and the flange 12;
The main body 110 having a c-shaped cross section and the first coupling part 120 having a shape in which both ends of the main body 110 are bent to the outer side are coupled to each other in both directions of the flange of the core material 10 so that the core material 10 is formed. A first reinforcement (100) configured to surround a central portion of the longitudinal direction of the;
It consists of a main body 210 to form a concave portion 211 in a trapezoidal cross-sectional shape, and the coupling portion 220 formed by bending both ends of the main body 210 to the outside, the core material in the longitudinal direction of the core material 10 ( 10) and the second reinforcing material 200 configured between the first reinforcing material 100; And
Reinforcing member 300 is introduced between the first coupling portion 120 of the first reinforcing material 100 to be coupled to each other end is in contact with the longitudinal direction of the central portion of the main body 210 of the second reinforcing material (200); About axial buckling-free buckling brace characterized in that it comprises a. The method of claim 1,
The first coupling portion 120 is a weak-axis reinforced non-buckling brace, characterized in that the reinforcement coupling portion 121 is formed to be extended to the outside. 3. The method of claim 2,
The main body 110 is made of a combination of the a-shaped bending members (110a) (110b), the end of the mutually coupled ends of the bending members (110a) (110b) the second coupling portion 130 of the shape bent outwardly About axial reinforcement non-buckling brace, characterized in that the configuration. The method of claim 3, wherein
The second coupling portion 130 is a weak-axis reinforced non-buckling brace, characterized in that the reinforcement coupling portion 131 of the shape bent outwardly extended. delete delete

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