KR20120123916A - Post reinforcing structure for buckling of braces in the steel moment connection frame - Google Patents

Abstract

PURPOSE: A post reinforcing structure for preventing the buckling of a brace for the seismic reinforcement of a steel moment frame is provided to prevent a brace from buckling using a concrete block and a fiber reinforced plastic sheet. CONSTITUTION: A post reinforcing structure for preventing the buckling of a brace for the seismic reinforcement of a steel moment frame comprises viscoelastic materials(30), first and second concrete blocks(20a,20b), and a fiber reinforced plastic sheet(40). The viscoelastic materials are attached to both surfaces of the web(13) of a brace(10). The first and second concrete blocks are arranged symmetrically to each other. The fiber reinforced plastic sheet surrounds the first and second concrete blocks to couple the first and second concrete blocks to the brace.

Description

Post reinforcing structure for buckling of braces in the steel moment connection frame}

The present invention relates to a reinforcement structure capable of preventing buckling of braces installed as lateral force resisting elements for seismic reinforcement of steel moment frames.

In steel moment frame buildings, braces have relatively high stiffness and strength, so they are used as lateral resistance elements that resist horizontal loads such as earthquakes and wind. Bracing systems are excellent lateral resistance systems that help to control damage caused by excessive horizontal displacement. However, if an extreme load such as an earthquake more than the design earthquake load is applied, stiffness of the brace causes a sharp drop in stiffness and strength, unstable behavior, and a decrease in energy dissipation.

Buckling-Restrained Braces have been developed to improve the load-bearing performance of these brace systems. The non-buckling brace restrains the buckling by using steel pipes around the steel member in the center so that the central steel member does not generate a full or local buckling when a large earthquake load is generated, and generates a large amount of energy by stable hysteretic behavior. Make it possible to dissipate.

In particular, non-buckling braces do not produce plastic hinges on beams or columns when the joints of beams and columns are shear-bonded, and all damage is concentrated on non-buckling braces. Braces that do not share gravity loads can be easily replaced, which has great advantages in the management and maintenance of structures after earthquakes.

Figure 4 schematically shows the concept of a non-buckling brace is a non-buckling brace is a central steel member 110 and the tube 120 and the steel member 110 is embedded between the steel member 110 and the tube 120 It is composed of a filler 122 to be filled and may have a variety of shapes depending on the shape of the central steel member and the tube is filled with the steel member and the filler is filled between the steel member and the tube.

However, the existing non-buckling brace is combined with the reinforcement member in the center steel member so that the buckling does not occur in the brace by horizontal load and is installed in the steel moment frame to prevent buckling of the brace in the moment frame where the brace is already installed. There is a problem that it is not suitable to apply as a reinforcement method.

An object of the present invention is to provide an anti-buckling candidate steel structure of a steel moment frame seismic reinforcement brace to be able to behave as a non-buckling brace by reinforcing the existing brace.

The anti-buckling candidate steel structure of the steel moment frame seismic reinforcement brace according to an embodiment of the present invention,

In the reinforcement structure of a brace composed of steel which is installed in steel moment frame and acts as a lateral resistance element, and the webs connecting the flanges to each other are connected to each other.

Viscoelastic materials each attached to both sides of the web of the brace;

First and second concrete blocks disposed symmetrically with respect to the web of the bracing; And

It includes a fiber-reinforced plastic sheet for wrapping the first and second concrete blocks in the direction perpendicular to the longitudinal direction and the longitudinal direction, and joining the first and second concrete blocks to the brace,

The first and second concrete blocks,

A section enlargement having a height corresponding to the height of the brace and having a width extending at a predetermined length at both ends of the upper flange and the lower flange, and a space protruding from the section enlargement and surrounded by the upper flange, the lower flange and the web of the brace. It is composed of a reinforcement insert is inserted, characterized in that the reinforcing iron plate is installed on the end surface of the reinforcing insert portion facing the viscoelastic material attached to the web of the brace.

A plurality of longitudinal rebars may be disposed in the cross section enlargement part at intervals along the height direction in the longitudinal direction.

In addition, a plurality of shear connecting members may be installed on the surface where the reinforcing steel plate is in contact with the reinforcing insertion portion.

In addition, the fiber reinforced plastic sheet may be a carbon fiber reinforced plastic sheet.

Further, both ends of the first and second concrete blocks may further include end fiber reinforced plastic sheets disposed at right angles to the longitudinal direction and joining the first and second concrete blocks to the brace.

According to the present invention, energy is dissipated by deformation of the viscoelastic material installed between the brace and the concrete block when the earthquake or wind load is applied, and the buckling of the brace can be prevented by the concrete block and the fiber reinforced plastic sheet when the earthquake occurs over the design earthquake load. .

In addition, the brace and the bending moment is also acting at the same time to the brace with both ends is a steel joint, not a pin joint. In the present invention, the cross section is increased by the concrete block and the fiber reinforced plastic sheet, so the lateral resistance performance is greatly improved.

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 front view showing the appearance of reinforcing braces installed on the steel moment frame in accordance with the present invention.
Figure 2 is an exploded perspective view showing the anti-buckling candidate steel structure of the brace according to the present invention showing the state before the concrete block is bonded by a fiber reinforced plastic sheet.
Figure 3 is a cross-sectional view taken along the line AA of Figure 1 shows a state after the concrete block is bonded by a fiber reinforced plastic sheet.
4 schematically illustrates the concept of a non-buckling brace.

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.

1 is a front view showing the appearance of reinforcing braces installed on the steel moment frame in accordance with the present invention.

As shown in FIG. 1, the present invention can actively cope with the increase in the design earthquake load by reinforcing the brace 10 installed as a transverse force resisting element in the steel moment frame and preventing buckling under extreme loads, thereby dissipating high energy. Have the ability. In FIG. 1, the braces 10 are illustrated in a diagonal form from the lower left to the upper right of the steel moment frame, but the present invention is not limited to the arrangement of the braces.

Figure 2 is an exploded perspective view showing the anti-buckling candidate steel structure of the brace according to the invention showing the state before the concrete block is bonded by the fiber reinforced plastic sheet, Figure 3 is a cross-sectional view taken along line AA of Figure 1 After the concrete blocks are bonded by the reinforcement plastic sheet.

In the present invention, as shown in Figures 2 and 3, the upper flange 11 and the lower flange 12 and the web 13 connecting them to each other, the concrete block 20a to the existing brace 10 having an H-shaped cross section 20b) is bonded using the fiber reinforced plastic sheet 40 to prevent buckling of the brace 10.

The concrete block is composed of a first concrete block 20a and a second concrete block 20b which are installed symmetrically with respect to the web 13 on both sides corresponding to the cross-sectional shape of the brace 10. Since the first and second concrete blocks 20a and 20b have symmetrical shapes with respect to the web 13 of the brace 10, only the first concrete block 20a will be described below for convenience of description.

The first concrete block 20a protrudes from the section enlargement section 21 and the section enlargement section 21 and is inserted into a space surrounded by the upper flange 11, the lower flange 12, and the web 13 of the brace 10. It consists of a reinforcement insertion part 22 which becomes.

The cross-sectional enlarged portion 21 has a height corresponding to the height of the brace 10 and has a width in which a predetermined length is extended at both ends of the upper flange 11 and the lower flange 12. A plurality of longitudinal reinforcing bars 211 are arranged in the cross-sectional enlargement section 21 at intervals along the height direction in the longitudinal direction, and the bending rigidity of the cross-sectional enlargement section 21 is reinforced by the longitudinal reinforcing bars 211.

The reinforcement insertion part 22 protrudes from the section enlargement part 21 and is inserted into a space surrounded by the upper flange 11, the lower flange 12, and the web 13 of the brace 10. Therefore, the height is determined corresponding to the distance between the upper flange 11 and the lower flange 12 of the brace 10, and a certain distance from these flanges 11 and 12 so that only the brace 10 is subjected to axial force under the design earthquake load. It has a height that can be. The width is determined corresponding to the distance between the web 13 at one end of the upper flange 11 and the lower flange 12 and has a width that can be spaced apart from the web 13 by a certain distance.

A reinforcing iron plate 25 is installed on an end face of the reinforcing insertion part 22 facing the web 13 of the brace 10. The reinforcing iron plate 25 is in contact with the reinforcement insert 22, a plurality of shear connection member 26 is installed so that the reinforcing iron plate 25 can be integrally combined with the reinforcement insert (22). Shear connector 26 may be any shear connector known in the art and has shown an example where stud bolts are used in the figures.

The viscoelastic material 30 is attached to the web 13 surface of the brace 10 facing the reinforcing steel plate 25, and the tensile or compressive force may act on the brace 10 by weakness or wind load through the viscoelastic material 30. When the first and second concrete blocks 20a and 20b do not have a tensile force or a compressive force, and the viscoelastic material 30 deforms and dissipates energy. The viscoelastic material 30 may be selected and used from any material known in the art such as high damping rubber as a displacement dependent energy absorbing material.

The first and second concrete blocks 20a and 20b are pre-fabricated at the factory and brought into the field, and are coupled to the braces 10 by the fiber reinforced plastic sheet 40. That is, while the first and second concrete blocks 20a and 20b are installed on both sides of the brace 10, respectively, the fiber-reinforced plastic sheet 40 is wrapped in the direction perpendicular to the longitudinal direction of the concrete block, and the fibers are also in the longitudinal direction again. The reinforcing plastic sheet 40 is bonded to wrap the fiber reinforced plastic sheet 40 in a direction perpendicular to the longitudinal direction and the longitudinal direction over the entire length of the concrete blocks 20a and 20b.

Alternatively, after fabricating the concrete blocks 20a and 20b, the fiber reinforced plastic sheet 40 is bonded to the exposed surfaces of the concrete blocks 20a and 20b, that is, the top, side and bottom surfaces thereof in the longitudinal direction, and the fiber reinforced plastic in the longitudinal direction. Fiber-reinforced plastic sheet 40 in a direction perpendicular to the longitudinal direction of the concrete blocks 20a and 20b in a state in which the concrete blocks 20a and 20b to which the citic sheet 40 is bonded are respectively installed on both sides of the brace 10. Wrap the concrete blocks 20a and 20b to couple to the brace 10.

Further, at both ends of the concrete blocks 20a and 20b, the end fiber reinforced plastic sheet 41 is wrapped in a direction perpendicular to the longitudinal direction of the concrete blocks 20a and 20b. Therefore, the concrete blocks 20a and 20b are more firmly coupled to the brace 10 at both ends.

As the reinforcing fibers in the fiber reinforced plastic sheets 40 and 41 applied to the present invention, appropriate reinforcing fibers may be selected and used in consideration of the application environment in carbon fibers, glass fibers, and amide fibers, and as a base material (matrix resin). Epoxy resins, phenolic resins and the like, and any resin known in the art may be used.

As described above, according to the present invention, the brace 10 is concrete block by firmly coupling the concrete blocks 20a and 20b with the fiber reinforced plastic sheets 40 and 41 to the existing brace 10 composed of the H-shaped steel frame member. Since it is restrained by (20a, 20b), it is possible to greatly increase the buckling load.

In addition, the brace installed in the moment frame is rigidly coupled to the column and / or beam, and receives not only the axial force such as tensile force or compressive force due to the horizontal load, but also the bending moment. The cross section can be reinforced to have rigidity.

In addition, according to the present invention, a predetermined gap is formed between the concrete blocks 20a and 20b and the upper and lower flanges 11 and 12 of the brace 10 and separated from each other and the web 13 of the brace 10 by the viscoelastic material 30. ) And the concrete blocks 20a and 20b are separated, so only the brace 10 corresponding to the core material behaves when the damping or wind load is applied. Therefore, energy dissipation by the brace 10 does not occur and energy is deformed by the deformation of the viscoelastic material 30. Dissipation. And the buckling of the brace 10 that can be generated by the compressive force acting on the brace 10 when the earthquake or more than the design earthquake load occurs is increased by the concrete blocks (20a, 20b) and the fiber reinforced plastic sheet (40, 41) Prevented by cross section.

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.

10: brace
20a, 20b: concrete block
21: section enlargement
211: longitudinal rebar
22: reinforcement insert
25: reinforcing steel plate
26: shear connector
30: viscoelastic material
40: fiber reinforced plastic sheet
41: end fiber reinforced plastic sheet

Claims (5)

In the reinforcement structure of a brace composed of steel which is installed in steel moment frame and acts as a lateral resistance element, and the webs connecting the flanges to each other are connected to each other.
Viscoelastic materials each attached to both sides of the web of the brace;
First and second concrete blocks disposed symmetrically with respect to the web of the bracing; And
It includes a fiber-reinforced plastic sheet for wrapping the first and second concrete blocks in the direction perpendicular to the longitudinal direction and the longitudinal direction, and joining the first and second concrete blocks to the brace,
The first and second concrete blocks,
A section enlargement having a height corresponding to the height of the brace and having a width extending at a predetermined length at both ends of the upper flange and the lower flange, and a space protruding from the section enlargement and surrounded by the upper flange, the lower flange and the web of the brace. Anti-buckling candidate steel structure of the steel moment frame seismic reinforcement brace, characterized in that the reinforcement insert portion is inserted, the reinforcement insert portion end face facing the viscoelastic material attached to the web of the brace is installed. The method according to claim 1,
The anti-buckling candidate steel structure of the steel moment frame seismic reinforcement brace, characterized in that the plurality of longitudinal rebars are arranged at intervals along the height direction in the longitudinal direction. The method according to claim 1,
The anti-buckling candidate steel structure of the steel moment frame seismic reinforcement bracing, characterized in that a plurality of shear connecting members are installed on the surface where the reinforcing steel plate is in contact with the reinforcing insertion portion. The method according to claim 1,
Fiber reinforced plastic sheet is a carbon fiber reinforced plastic sheet characterized in that the anti-buckling candidate steel structure of the steel moment frame seismic reinforcement brace. The method according to claim 1,
Steel moment moment seismic reinforcement brace, characterized in that it further comprises end fiber reinforced plastic sheets disposed at right angles to the longitudinal direction at both ends of the first and second concrete blocks to couple the first and second concrete blocks to the brace. Anti-buckling candidate steel structure.

Images