KR101388416B1 - Brace type damper - Google Patents

Abstract

The present invention discloses a brace-type damper, which is coupled with a vibration control device applying both viscoelastic deformation of high damping rubber and elastoplastic deformation of steel materials to a brace. The brace-type damper according to the present invention comprises a connection tube, which is an angular steel tube with a hollow inside and has a plastic link on the top and bottom surface in one end; a first brace, which is a length material with a cross section smaller than the hollow of the connection tube and has two and more joining surfaces joined to the connection tube, and which is inserted into the hollow of one end side of the connection tube in one end and is connected to the connection tube through the joining surfaces; a second brace, which is a length material having the same cross section with that of the first brace and is inserted into the hollow of the connection tube in one end to be separated from the first brace; and a viscoelastic rubber pad, which is inserted into the gap between the joining surface of the second brace and the connection tube where the second brace and the connection tube are overlapped. The viscoelastic rubber pad resists elastic deformation against a small-scale earthquake like wind load and absorbs vibrational energy. The plastic link of the connection tube is plastically deformed and dissipates earthquake energy when a design earthquake or any greater earthquake load occurs.

Description

Brace type damper

The present invention relates to a vibration damping device manufactured to dissipate vibration energy due to wind load or earthquake load, and more particularly, a vibration damping device using a combination of viscoelastic deformation of high damping rubber and carbonaceous deformation of steel in combination with a brace. A brace damper.

Recently, with the spread of concerns about earthquake damage, seismic design of building structures such as buildings and bridges has attracted attention. Seismic design is a comprehensive construction method to protect various structures from the impact of earthquake, and if it is classified in detail, it can be classified into seismic design, vibration suppression, and seismic design.

Firstly, seismic design includes seismic design and vibration damping design in a broad sense. However, if the meaning is narrowed down, it can be explained only by the design technique that overcomes the earthquake load through the strength of the structure itself. Such seismic design increases the strength and toughness of various members constituting the structure to increase the rigidity of the structure itself, thereby maintaining the structural stability and usability of the structure from earthquake load.

However, in the seismic design, since a member having a large cross section is used to increase the strength and toughness of the member constituting the structure, or a lot of rebar is consumed, the quantity is increased and economic efficiency is lowered. In particular, the earthquake resistance performance is questioned through the case of earthquake-resistant structures collapsed by earthquakes. Compared to the seismic design, the damping and seismic design is an advanced technology for reinforcing the economics and the seismic performance by the existing seismic design, and its use has recently been increased.

Among these, the vibration suppression design is a structure to dissipate the seismic load applied to the structure. That is, it is a design method to reduce the earthquake load by artificially adjusting the frequency of the structure according to the vibration characteristics of the seismic wave to prevent the resonance of the structure and further canceling the vibration of the structure and the vibration of the seismic wave.

Hydraulic dampers or steel dampers are used to apply the damping design described above to steel structures or concrete structures. In particular, in the case of braced frame, which is a system that secures the lateral stability of the structure by reinforcing the brace diagonally to the frame system consisting of pillars and beams, the hydraulic damper or steel damper is used for the brace. There are many cases.

Hydraulic dampers have superior seismic performance compared to steel dampers and are mainly used in Japan, where heavy and heavy earthquakes occur frequently throughout the country. However, since such a hydraulic damper is expensive, it is unnecessarily excessive in the country where the occurrence frequency of the earthquake is low and the strength of the earthquake is not high. On the other hand, the steel damper has a somewhat lower seismic performance than the hydraulic damper, but the steel damper is used for reinforcement of the steel structure because the construction cost is low.

As a background technology of the present invention, there is a patent registration 10-0908864 'steel damper using a load transfer plate and a slit steel plate' (Patent Document 1). This patent devises a steel damper that includes a slit steel plate coupled to a cylinder and a load transfer plate passing through a central cutout of the slit steel plate, so that it can be easily attached to the inside and outside of an existing structure and has a lower construction cost than a conventional hydraulic damper. Suggest. However, the steel damper proposed by this patent has the advantage of efficiently absorbing seismic energy through plastic deformation of the structure to prevent deformation of the members constituting the structure, but the steel damper cannot induce sufficient elastic deformation before plastic deformation. There are disadvantages.

Patent Registration No. 10-0908864 'Steel Damper Using Load Transfer Plate and Slit Steel Plate'

The present invention is to solve the problems of the prior art as described above, when the horizontal load such as wind load and earthquake load is transferred to the frame structure consisting of columns and beams, after inducing sufficient elastic deformation in the brace installed diagonally to the frame structure It is an object of the present invention to provide a brace type damper in which the damper plastically deforms and absorbs a horizontal load.

The brace damper according to the present invention comprises a connecting tube in which a plastic link is formed on one side end and a bottom thereof as a square steel pipe having a hollow therein; A first brace having two or more joining surfaces joined to the connecting tube with a length having a cross section smaller than the hollow of the connecting tube, one end of which is inserted into one side hollow of the connecting tube and joined to the connecting tube through the joining surface; A second brace having one end inserted into the hollow of the connecting tube so as to be spaced apart from the first brace by a length member having the same cross section as the first brace; It includes a viscoelastic rubber pad is inserted into the gap between the joining surface of the second brace and the connecting tube in the overlapping section of the second brace and the connection tube, and includes a viscoelastic rubber pad against the wind load and a small earthquake When the earthquake load absorbs vibration energy and includes a design earthquake, the plastic link of the connecting tube plastically deforms and dissipates the seismic energy.

At this time, the connecting tube is formed with a slot groove in the longitudinal direction in the center of the upper and lower sides of the one end of the first brace is inserted, the connecting tube and the first brace is coupled by the slot welding through the slot groove on the first brace joint surface You can do that.

In addition, the first and second braces are composed of a pair of upper and lower flanges, and a web of connecting a pair of upper and lower flange ends to form an I-shaped steel or an H-shaped steel, so that a plastic link is formed on the upper side of the connecting tube. The lower surface and the flange of the first and second braces may be joined in parallel.

In addition, the first and second brace is composed of I-shaped steel or H-shaped steel consisting of a web connecting a pair of upper and lower flanges and a pair of upper and lower flange stops, The lower surface and the flange of the first and second braces may be joined at right angles.

In addition, the first and second braces, each of which consists of a rectangular steel pipe having a hollow inside, the upper and lower surfaces of the connecting tube is formed in the plastic link and the upper and lower surfaces of the first and second braces can be joined in parallel.

In addition, the first and second braces are composed of a rectangular steel pipe having a hollow inside, and both sides of the upper and lower sides of the connecting tube on which the plastic link is formed may be joined to both sides of the first and second braces. .

The brace damper according to the present invention is a viscoelastic rubber pad installed in the gap between the connecting tube and the second brace against the wind load and the earthquake of a small scale to absorb the vibration energy while resisting the elastic deformation and the earthquake load larger than this, including the design earthquake. In this case, the plastic link of the connecting tube dissipates seismic energy while plastically deforming. That is, the energy dissipation capacity due to the viscoelastic deformation of the viscoelastic rubber pad reduces the vibration energy of the main structure and minimizes the residual deformation.For the maximum level earthquake including the design earthquake, the elastic linkage of the plastic link of the connecting tube By controlling the vibration of the structure, the main members such as beams and columns stay in the elastic region, thereby minimizing damage to the main structure.

Also, in case of earthquake, it is a convenient system that can be repaired by removing and replacing only plastic deformation or broken brace dampers while maintaining the main structural members of the frame, and it is inexpensive when remodeling old and old buildings before the seismic design standard is applied. A sufficient seismic reinforcing effect can be achieved at a cost.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
1 is an exploded perspective view showing a brace damper according to an embodiment of the present invention.
2 is a plan view of a connection tube of a brace damper according to an embodiment of the present invention.
Figure 3 shows a brace damper according to an embodiment of the present invention, 3a is a longitudinal cross-sectional view, Figure 3b is a cross-sectional view cut along the line AA of Figure 3a, Figure 3c is a cross-sectional view cut along the line BB of Figure 3a. to be.
Figure 4 shows a brace damper according to another embodiment of the present invention, Figure 4a is a cross-sectional view taken along line AA of Figure 3a, Figure 4b is a cross-sectional view cut along the line BB of Figure 3a.
5 is a perspective view showing a brace damper according to an embodiment of the present invention.
6 is a brace damper according to another embodiment of the present invention, Figure 6a is a longitudinal cross-sectional view, Figure 6b is a cross-sectional view cut along the line CC of Figure 6a, Figure 6c is a cut along the DD line of Figure 6a Cross section view.
FIG. 7 illustrates a brace damper according to another embodiment of the present invention. FIG. 7A is a cross-sectional view taken along line CC of FIG. 6A, and FIG. 7B is a cross-sectional view taken along line DD of FIG. 6A.
8 shows a brace frame in which a brace damper according to the invention can be used.

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 an exploded perspective view showing a brace damper according to an embodiment of the present invention.

As shown in FIG. 1, the brace damper of the present invention includes a connection tube 10 composed of a square steel pipe having a hollow therein and a length member having a cross section relatively smaller than the hollow of the connection tube 10. One end of the connecting tube 10 is inserted into a certain distance and coupled to the connecting tube 10, the first brace 20, and the length of the end member having the same cross-section as the first brace 20, one end of the connecting tube (10) The second brace 30 and the connection tube 10 in the overlapping section of the second brace 30 and the second brace 30 and the connection tube 10 inserted to be spaced apart from the first brace 20 at the other end of the second brace 30. It includes a viscoelastic rubber pad 40 is inserted between and bonded.

2 is a plan view of a connection tube of a brace damper according to an embodiment of the present invention.

As shown in Figure 1 and 2, the connection tube 10 is composed of a rectangular steel pipe having a hollow inside and having an upper, lower surface 14 and both sides 15 surrounding the hollow. The connection tube 10 has a slot groove 13 formed in a longitudinal direction at the center of the upper and lower surfaces 14 of one side end, that is, the side in which the first brace is inserted, and the slot groove 13 is centered on both sides thereof. There are a plurality of plastic grooves 12 are formed at regular intervals. The slot groove 13 is for joining the connecting tube 10 and the first brace 20, the firing groove 12 is to provide a firing link (11) formed between the firing grooves.

As shown in Figure 2, the plastic groove 12 is formed in an elongated oval perpendicular to the longitudinal direction of the connection tube 10, which discontinuous the cross section of the connection tube 10, that is formed between the plastic groove 12 The plastic link 11 is to be a relative weak portion of the upper and lower surfaces 14, the connecting tube. As such, by forming a weak portion in the connecting tube 10, plastic deformation is allowed in the plastic link 11, which is a weak portion when subjected to an extreme load such as an earthquake load, and a stress is redistributed after a plastic hinge such as permanent deformation is generated. Can resist additional external force. Therefore, there is an advantage that the first and second braces 20 and 30, which are structural members, do not affect the earthquake load.

Meanwhile, in the present embodiment, the plastic groove 12 and the plastic link 11 are illustrated as being formed on the upper and lower surfaces 14 of the connection tube 10. However, the plastic groove 12 and the plastic link 11 are not necessarily limited thereto. It may be formed on both sides 15 of the tube 10. In addition, the shape of the sintering groove 12 is also not limited to the elliptical shape as long as the sintering link 11 can be formed properly, it may be formed in a square or a circle.

The first and second braces 20 and 30 of the brace damper according to the present invention are a pair of upper and lower flanges 21 and 21 and 31 and 31 parallel to each other, and a pair of upper and lower flanges 21. It may be composed of an I-shaped steel or H-shaped steel consisting of webs 22 and 32 connecting the suspensions. Since the I-shaped steel or the H-shaped steel has larger cross-sectional coefficients and cross-sectional secondary moments than other steels, when used as the first and second braces 20 and 30, the structural performance of the brace damper can be further improved.

Figure 3 shows a brace damper according to an embodiment of the present invention, 3a is a longitudinal cross-sectional view, Figure 3b is a cross-sectional view cut along the line AA of Figure 3a, Figure 3c is a cross-sectional view cut along the line BB of Figure 3a. to be.

Referring to FIG. 3, the first brace 20 is inserted into one end of the connection tube 10 to insert the slot groove 13 in the upper and lower surfaces 14 of the connection tube and the flange 21 of the first brace. The connecting tube 10 and the first brace 20 are coupled to each other through the slot welding 50, and the upper and lower surfaces 14 of the connecting tube are connected to the other end of the connecting tube 10 into which the second brace 30 is inserted. The viscoelastic rubber pad 40 is installed at the gap between the flange and the flange 31 of the second brace and is bonded by applying any method known in the art such as vulcanization.

As the viscoelastic rubber pad 40, high damping rubber may be used. The high-damping rubber is prepared by adding additives such as fillers, vulcanizing agents, antioxidants and plasticizers to natural rubber and / or carbon black, and then vulcanizing the mixture at a predetermined temperature and a heat. At this time, the viscosity and elasticity of the highly damped rubber are controlled by adjusting the ratio of the additive added to the natural rubber or / and the carbon black.

The viscoelastic rubber pad 40 is a means for connecting the connecting tube 10 and the second brace 30 and serves to absorb vibration energy by the elastic deformation described later.

Figure 4 shows a brace damper according to another embodiment of the present invention, Figure 4a is a cross-sectional view taken along line A-A of Figure 3a, Figure 4b is a cross-sectional view cut along the line B-B of Figure 3a.

In the above description, the coupling of the connection tube 10 and the first and second braces 20 and 30 is performed by the upper and lower surfaces 14 and the flanges of the first and second braces of the connection tube on which the plastic link 11 is formed. 21 and 31 are coupled in parallel, but the present invention is not limited thereto, and the flanges of the upper and lower surfaces 14 and the first and second braces of the connecting tube in which the plastic link 11 is formed as shown in FIG. (21, 31) can be combined in a right direction.

Referring to the operation of the brace damper according to the present invention configured as described above is as follows.

5 is a perspective view showing a brace damper according to an embodiment of the present invention.

The dashed line shown in FIG. 5 is for explaining the mechanical mechanism of the brace damper according to the present invention. The first brace 20 serves as a plastic damper 60 and the second brace 30 serves as a viscoelastic damper 70. Done.

When micro deformation occurs due to wind load and small scale earthquake, the viscoelastic rubber pad 40 installed in the upper and lower voids between the connecting tube 10 and the second brace 30 absorbs vibration energy while deforming and deforming. In addition, when the maximum level earthquake, including a design earthquake, acts, the plastic link 11 of the connection tube 10 dissipates seismic energy while plastically deforming.

Therefore, it is possible to cope with one vibration damper without installing a separate vibration damper according to the type of vibration source, so that the cost can be reduced and the degree of freedom in construction planning is improved.

6 is a brace damper according to another embodiment of the present invention, Figure 6a is a longitudinal cross-sectional view, Figure 6b is a cross-sectional view cut along the line CC of Figure 6a, Figure 6c is a cut along the DD line of Figure 6a Cross section view.

In the above-described embodiment, the H-shaped steel is used as the member of the first and second braces 20 and 30, but in the present embodiment, the square steel pipe is used. Since the configuration and function of the brace dampers except for the cross sections of the first and second braces 20 and 30 are the same as in the above-described embodiment, repeated descriptions thereof will be omitted.

The first brace 20 is inserted into one end of the connecting tube 10 and the first brace by the slot welding 50 through the slot groove 13 on the upper and lower surfaces of the connecting tube and the upper and lower surfaces of the first brace. 20 is coupled to the other end of the connecting tube 10, the second brace 30 is inserted into the viscoelastic rubber pad 40 is installed in the upper and lower intervals between the connecting tube 10 and the second brace 30 Then, it is bonded by applying any method known in the art such as vulcanization.

As shown in FIG. 6, the first and second braces 20 and 30 are rectangular steel pipes having a constant thickness and length, and are length members having a smaller cross section than the hollow of the connection tube 10. The first brace 20 is inserted into the slot welding through the slot groove 13 on the upper and lower surfaces 14 and the upper and lower surfaces 21a of the first brace at one end of the connecting tube 10 ( The connecting tube 10 and the first brace 20 are coupled to each other, and the upper and lower surfaces 14 and second of the connecting tube are formed at the other end of the connecting tube 10 into which the second brace 30 is inserted. A viscoelastic rubber pad 40 is provided between the upper and lower surfaces 31a of the brace and is bonded by applying any method known in the art such as vulcanization.

7 is a brace damper according to another embodiment of the present invention, Figure 7a is a cross-sectional view taken along the line C-C of Figure 6a, Figure 7b is a cross-sectional view taken along the line D-D of Figure 6a.

In the foregoing description, the coupling of the connecting tube 10 and the first and second braces 20 and 30 is performed by the first and second braces parallel to the upper and lower surfaces 14 of the connecting tube on which the plastic link 11 is formed. Although coupled to the upper and lower surfaces 21 and 31, the present invention is not limited thereto, and the first orthogonal direction is perpendicular to the upper and lower surfaces 14 of the connection tube on which the plastic link 11 is formed, as shown in FIG. 7. 2 may be coupled at both sides 22a and 32a of the brace.

In the present embodiment, the connecting tube 10 and the first and second braces 20 and 30 are illustrated as steel pipes having a rectangular cross-sectional shape, but the present invention is not limited thereto and may be configured as steel pipes having a circular or polygonal cross-sectional shape. It may be.

In addition, in the present embodiment, the coupling of the connection tube 10 and the first and braces 20 has been described as the slot welding 50 through the slot groove 13, but it is well known in the art such as bolt joining, piece joining, and crimping. Any method can be applied.

8 shows a brace frame in which a brace damper according to the invention can be used.

Brace frame is a system that adopts braces such as X, Pratt, Diagonal, K, V, Knee type to the ramen frame structure consisting of pillars and beams. It is a structural method that supports the lateral force of the frame through the axial force of the brace. When the brace damper according to the present invention is used as a brace for the brace frame, the viscoelastic rubber pad 40 installed in the gap between the connecting tube 10 and the second brace 30 is elastically deformed for wind load and small earthquake. Absorbs vibration energy while resisting. In addition, when a larger earthquake load including a design earthquake acts, the plastic link 11 of the connecting tube 10 dissipates seismic energy while plastically deforming.

That is, the energy dissipation capacity due to the viscoelastic deformation of the viscoelastic rubber pad 40 reduces the vibration energy of the main structure and minimizes the residual deformation, and the plasticity of the connection tube 10 is increased for the maximum level earthquake including the design earthquake. By controlling the vibration of the structure by the elastic deformation of the link 11, the main members such as beams and columns stay in the elastic region to minimize the damage of the main structure. In case of an earthquake, it is a convenient system that can be recovered by removing and replacing only plastic deformation or broken brace dampers while maintaining the main structural members of the frame.

In addition, it is possible to achieve sufficient seismic reinforcement effect at a low cost when remodeling a building and an old building that were constructed before the seismic design criteria were applied.

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: connecting tube 11: firing link
12: plastic groove 13: slot groove
14: connecting tube upper and lower surfaces 15: connecting tube both sides
20: First brace 21: Upper and lower flanges of the first brace
22: web of the first brace 21a: image of the first brace
22a: Both sides of the first brace 30: The second brace
31: Upper and lower flanges of the second brace 32: Web of the second brace
31a: upper and lower surfaces of the second brace 32a: both sides of the second brace
40: viscoelastic rubber pad (40) 50: slot welding
60: plastic damper 70: viscoelastic damper

Claims (6)

A connection tube 10 in which a plastic link 11 is formed on one side end and a lower surface 14 of a rectangular steel pipe having a hollow inside;
It is a length member having a smaller cross section than the hollow of the connecting tube 10 and has two or more joining surfaces joined to the connecting tube 10, one end of which is inserted into one side hollow of the connecting tube 10 to connect the connecting tube through the joining surface. A first brace 20 bonded with the 10;
A second brace 30 having one end inserted into the hollow of the connection tube 10 so as to be spaced apart from the first brace 20 by a length member having the same cross section as the first brace 20;
It includes; viscoelastic rubber pad 40 is inserted into the gap between the second brace 30 and the connecting tube 10 in the overlapping section of the second brace 30 and the connecting tube 10;
The viscoelastic rubber pad 40 absorbs vibrational energy while resisting elastic deformation against wind loads and small-scale earthquakes, and the plastic link 11 of the connecting tube 10 is fired when a larger earthquake load is applied, including a design earthquake. A brace type damper, characterized by dissipation and dissipation of seismic energy. The method according to claim 1,
The connection tube 10 is formed with a slot groove 13 in the longitudinal direction in the center of the upper and lower surfaces 14 of one end of the first brace 20 is inserted, the slot groove ( 13 is a brace type damper, characterized in that the connection tube 10 and the first brace 20 is coupled to the slot welding 50 through. The method according to claim 1,
The first and second braces 20 and 30 are
I consisting of a pair of upper and lower flanges (21, 21) (31, 31) and webs (22) (32) connecting a pair of upper and lower flanges (21, 21) (31, 31) suspension Consists of section steel or H section steel,
The brace, characterized in that the upper and lower surfaces 14 of the connecting tube 10, on which the plastic link 11 is formed, and the flanges 21 and 31 of the first and second braces 20 and 30 are joined in parallel. Type damper. The method according to claim 1,
The first and second braces 20 and 30 are
I consisting of a pair of upper and lower flanges (21, 21) (31, 31) and webs (22) (32) connecting a pair of upper and lower flanges (21, 21) (31, 31) suspension Consists of section steel or H section steel,
The upper and lower surfaces 14 and the flanges 21 and 31 of the first and second braces 20 and 30 of the connecting tube 10 having the plastic link 11 are joined to each other at right angles. Brace dampers. The method according to claim 1,
The first and second braces 20 and 30 are
Consists of a square steel pipe with a hollow inside,
The upper and lower surfaces 14 and the upper and lower surfaces 21a and 31a of the first and second braces 20 and 30 of the connecting tube 10 having the plastic link 11 are formed in parallel to each other. Brace damper. The method according to claim 1,
The first and second braces 20 and 30 are
Consists of a square steel pipe with a hollow inside,
Both sides 15 of the connecting tube 10 in which the plastic link 11 is formed are perpendicular to the upper and lower surfaces 14 are joined to both sides 22a and 32a of the first and second braces 20 and 30. Brace type damper, characterized in that.

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