KR20190051325A - Steel Damper and Frame-type Damping Device usig the Damper and Reinforcing Method thereof - Google Patents

Abstract

The present invention relates to a composite damper with high damping rubber and a corrugated web, which includes a composite damper with a viscoelastic damper using high damping rubber and a corrugated web to reduce energy with characteristics of the viscoelastic damper and a steel hysteresis damper, a seismic device including the same, and a seismic structure reinforcement method using the same. According to one preferred embodiment of the present invention, the composite damper with high damping rubber and a corrugated web comprises: first and second fixing plates formed in a plate shape and spaced apart from each other at a predetermined distance in parallel; a plurality of corrugated webs made of a corrugated steel plate and spaced apart from each other at a predetermined interval to couple both longitudinal end parts to the first and second fixing plates, respectively, so as to connect the first and second fixing plates; and a viscoelastic damper member having an H-shaped cross section of a predetermined length, including a first connection member coupling one end part to a coupling plate having a plurality of coupling holes formed therein, a high damping rubber disposed outside the coupling plate of the first connection member, and a second connection member having a plurality of coupling holes formed in both end parts, and coupling a coupling plate, in which a coupling hole is formed as a long hole, to the coupling plate of one end part to couple the coupling plate, the high damping rubber, and the coupling plate with a bolt, thereby coupling the one end part of the first connection member to the outside of the first and second fixing plates of the composite damper.

Description

Technical Field [0001] The present invention relates to a frame damper including a composite damper and a composite damper including a high-damping rubber and a corrugated web, and a method for reinforcing a frame using the damper,

The present invention relates to a composite damper comprising a high-damping rubber and a corrugated web, a frame-type vibration damper including the composite damper, and a method for seismic-strengthening the structure using the damper and the composite damper. The damper comprises a viscoelastic damper using a high- The present invention relates to a frame type vibration damper including a composite damper and a composite damper constituted of a high-damping rubber and a corrugated web capable of dissipating energy due to the characteristics of a viscoelastic damper and a steel material history damper.

Vibration control refers to the control of vibration caused by wind or earthquake in a building, and the structure with a special device or mechanism, that is, a vibration suppression device, is called a vibration suppression structure for vibration control. The purpose of vibration damping is to improve the safety and habitability of the structure by dissipating vibration energy input to the structure by wind or earthquake by installing a vibration isolation device.

As a vibration suppression method, there is an active control that reduces the vibration of the structure by applying the control force corresponding to the vibration of the structure from inside or outside of the structure and having the function of sensing the vibration of the structure and the vibration of the structure accordingly. There is a passive control that controls the dynamic response of the building by installing an additional energy dissipation device to improve the damping performance of the structure.

Passive type vibration suppression devices can be classified into mass vibration type and energy dissipation type. The electrons are mainly installed at the top of the building for the purpose of increasing the residence of the wind, and the latter is installed mainly on each floor to enhance the safety of the earthquake and the residence of the wind.

The energy dissipative type vibration damper can be divided into a displacement dependent type and a speed dependent type. The displacement dependent type device utilizes the energy dissipation characteristic due to the frictional force between the materials or the plastic deformation of the metal. The speed dependent type is a case where the viscous material, The energy dissipated by generating heat and dissipating the vibration energy has a characteristic that the energy dissipated increases in proportion to the speed.

Hydraulic damper, which is a kind of speed dependent vibration damping device, has excellent seismic performance compared with a composite damper and is mainly used in Japan where heavy and strong earthquakes frequently occur nationwide. 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 composite damper has a somewhat lower seismic performance than a hydraulic damper, but has a low construction cost and is used for reinforcement of steel structure.

However, the vibration damping structure using the above-described composite damper is mostly of a brace type and is not suitable for a variable structure due to a spatial obstacle, and it is disadvantageous in that it is troublesome to replace it after an earthquake occurs. Therefore, it is difficult to apply it to the vibration damping structure of the RC structure requiring the variable structure, and it is inefficient to reinstall the vibration damping device after the earthquake.

As a background of the present invention, there is a patent document 10-1070043 'Column-shaped damper for improving seismic performance of a building' (Patent Document 1). This patent devises columnar dampers not to cause spatial obstacles. In particular, we propose columnar dampers with micro and macro fibers added to cement paste or cement mortar to improve the seismic performance of buildings. The column-type damper proposed by this patent has superior capability of suppressing or delaying cracks under design load and additional load as compared with existing cement composite, and is excellent in permeability and durability and improved energy dissipation and damage control ability However, when compared with other materials, there is a problem that the ductility limit of the cement composite and the non-environmentally friendly waste are generated when the column type damper needs to be replaced after the earthquake load.

Patent No. 10-0718294 'Column-type damper for improving seismic performance of buildings'

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a composite damper comprising a viscoelastic damper using a high-damping rubber, a vertical load-supporting steel rod, and a deformation-inducing steel rod, The energy is dissipated by the characteristics of the damper and the wave web is elastically deformed by the horizontal load such as earthquake to absorb and damp the horizontal load to secure the structural stability and usability of the structure, And installation is easy and cost is low, it contributes greatly to productivity improvement. In addition, even if a high-magnitude earthquake occurs, the earthquake energy is absorbed by the elastic deformation of the vibration damper. High-damping rubber that can be easily restored by frame and easy maintenance To provide a frame-like structure and the vibration suppression apparatus seismic strengthening method using the same, including composite damper and the damper composite waveform consisting of a web it is an object.

The present invention relates to a plasma display panel comprising first and second fixing plates arranged parallel to each other with a predetermined distance in a plate shape; A corrugated web formed of a corrugated steel plate and having a plurality of corrugated webs spaced apart from each other to connect the first and second corrugated plates so that both longitudinal ends thereof are joined to the first and second fixing plates; A first connecting member which is formed at a predetermined length of the H-shaped cross section and in which an engaging plate having a plurality of engaging holes is formed at the other end thereof, a highly damped rubber formed outside the engaging plate of the first connecting member, A plurality of coupling holes are formed at one end and the other end, respectively, and a coupling plate having a long hole is coupled to the coupling plate at one end, and a coupling plate, a high-damping rubber, and a coupling plate And a viscoelastic damper member composed of a second connecting member configured to be coupled with a bolt and configured to join one end of the first connecting member to the outside of the first and second fixing plates of the composite damper, respectively, Rubber and corrugated webs.

It is also desirable to provide a composite damper constituted by a highly damped rubber and a corrugated web, characterized in that the corrugated web has a center portion at both ends in the width direction drawn inward to constitute a section reducing portion.

An upper horizontal member coupled to the upper slab or lower surface of the structure; A lower horizontal member coupled to the lower slab or the beam surface of the structure; An upper vertical member coupled vertically at both ends of the upper horizontal member; A lower vertical member spaced in series from the upper vertical member and vertically coupled to opposite ends of the lower horizontal member; A first and second fixing plates arranged parallel to each other at a predetermined distance in a plate shape; A corrugated web which is formed of a corrugated steel plate and has both longitudinal ends joined to the first and second fixing plates so as to be spaced apart from each other by a predetermined distance so as to connect the first and second fixing plates; A first damping rubber formed on an outer side of an engaging plate of the first connecting member and a second damping rubber formed on the other end of the damping rubber, Wherein the coupling plate of one end is formed with a coupling plate having a long hole and the second coupling member is configured to fasten the coupling plate, the high-damping rubber and the coupling plate with bolts from the outside of the high-damping rubber, The viscoelastic damper member configured to join one end of the first connecting member to the outside of the first and second fixing plates of the composite damper, And a composite damper composed of a high-damping rubber and a corrugated web provided between the upper vertical member and the lower vertical member, and a composite damper including the high-damping rubber and the corrugated web. I want to.

The present invention also provides a frame damper including a composite damper constituted by a highly damped rubber and a corrugated web, characterized in that the corrugated web has a central portion of both ends in the width direction drawn inward to constitute a section reducing portion.

In addition, the upper and lower horizontal members and the upper and lower vertical members are constituted by H-shaped roll beams which are rolled and cast into an H-shaped section, a joint plate is provided at the joint portion of the upper and lower vertical members, And a composite damper constituted by a high-damping rubber and a corrugated web, which are connected to each other by bolts.

In addition, the upper and lower horizontal members and the upper and lower vertical members are made of reinforced concrete, and the upper horizontal member and the upper vertical member are integrally formed in the C shape, and the lower horizontal member and the lower vertical member are integrally formed And one end of the anchor bolt is previously embedded in the upper and lower vertical members, and the other end of the anchor bolt is projected from the upper and lower vertical members, and the anchor bolt protruding from the coupling plate of the viscoelastic damper member And a composite damper including a highly damped rubber and a corrugated web.

(A) first and second fixing plates arranged parallel to each other at a predetermined distance in a plate shape; A corrugated web formed of a corrugated steel plate and having a plurality of corrugated webs spaced apart from each other to connect the first and second corrugated plates so that both longitudinal ends thereof are joined to the first and second fixing plates; A first connecting member which is formed at a predetermined length of the H-shaped cross section and in which an engaging plate having a plurality of engaging holes is formed at the other end thereof, a highly damped rubber formed outside the engaging plate of the first connecting member, A plurality of coupling holes are formed at one end and the other end, respectively, and a coupling plate having a long hole is coupled to the coupling plate at one end, and a coupling plate, a high-damping rubber, and a coupling plate And a viscoelastic damper member composed of a second connecting member configured to be coupled with a bolt and configured to join one end of the first connecting member to the outside of the first and second fixing plates of the composite damper, An upper vertical member and a lower horizontal member vertically coupled at both ends of the upper horizontal member, Fabricating a lower vertical member that is tightly coupled; (b) joining the upper horizontal member to the upper slab or beam surface of the structure and the lower horizontal member to the lower slab or beam surface of the structure; And (c) installing a composite damper between the upper vertical member and the lower vertical member. The present invention also provides a method for reinforcing seismic resisting structures using the frame type vibration damper.

In addition, in the step (a), in the composite damper, the corrugated web of the composite damper is configured such that the central portion of both widthwise ends is drawn inward to constitute a section reducing portion. do.

In addition, in the step (a), the upper and lower horizontal members and the upper and lower vertical members are formed by H-shaped roll beams which are rolled and cast into an H-shaped section, a joint plate is provided at the joints of the upper and lower vertical members, Wherein the joint plate and the joint plate of the viscoelastic damper member are bolted to each other.

Also, in step (a), the upper and lower horizontal members and the upper and lower vertical members are made of reinforced concrete, and the upper horizontal member and the upper vertical member are integrally formed in a C shape, and the lower horizontal member and the lower vertical member (C), one end of the anchor bolt is previously embedded in the upper and lower vertical members and the other end of the anchor bolt is projected from the upper and lower vertical members in the upper and lower vertical members, And an anchor bolt protruding from the coupling plate of the viscoelastic damper member is nut-coupled to the coupling plate of the viscoelastic damper member.

A frame type vibration damper including a composite damper and a composite damper constituted of a high-damping rubber and a corrugated web of the present invention and a structure seismic reinforcement method using the same are provided with a composite damper constituted by a viscoelastic damper using a high-damping rubber, a vertical load-supporting steel bar, The energy is dissipated by the characteristics of the viscoelastic dampers using high damping rubber when wind or micro deformation occurs. For horizontal loads such as earthquakes, the corrugated web is elastically deformed to absorb and attenuate horizontal loads. It is possible to secure the structural stability and usability of the structure, and the structure is simple, and it is easy to manufacture and install, and the cost is low, so that it can contribute to the improvement of the productivity. In addition, even if the earthquake occurs with high magnitude, Because it is absorbed by deformation, I can easily revert back to the state before the frame to wear it is a very useful effect, maintenance is easy.

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 a perspective view of a composite damper constituted by a highly damped rubber and corrugated web according to the present invention.
FIG. 2A is an exploded perspective view of the main part of FIG. 1; FIG.
Figure 2b is a perspective view of a corrugated web of the present invention.
FIG. 3 is a partially exploded perspective view of FIG. 1; FIG.
4 is a schematic view illustrating the behavior of a composite damper constituted by a highly damped rubber and a corrugated web according to the present invention.
5 is a cross-sectional view of a steel frame-type vibration damper including a composite damper constituted by a highly damped rubber and a corrugated web according to the present invention.
6 is a perspective view of the main part of FIG.
7 is a cross-sectional view of a reinforced concrete frame type vibration damper including a composite damper constituted by a highly damped rubber and a corrugated web according to the present invention.

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.

FIG. 1 is a perspective view of a composite damper constituted by a highly damped rubber and a corrugated web according to the present invention, FIG. 2 (a) is an exploded perspective view of the main part of FIG. 1, and FIG. 3 is a partially exploded perspective view of FIG.

As shown in FIG. 1, the composite damper 100 having the highly damped rubber and corrugated web of the present invention is configured to connect the first and second fixing plates 20 and 30 and the first and second fixing plates 20 and 30 A plurality of corrugated webs 10 and a viscoelastic damper member 60 coupled to the outside of the first and second fixing plates 20 and 30, respectively.

The first and second fixing plates 20 and 30 are arranged in parallel to each other with a predetermined distance in a plate shape and a plurality of corrugated webs 10 are formed to connect the first and second fixing plates 20 and 30 .

Figure 2b is a perspective view of a corrugated web of the present invention.

The corrugated web 10 is configured to connect the first and second fixing plates 20 and 30 so as to improve the buckling and torsional rigidity. In addition, when the horizontal load such as an earthquake or wind is applied, . That is, similar to the steel hysteretic damper known in the art, the seismic load is absorbed by using the characteristics of the material itself.

The corrugated web 10 may be formed by, for example, cold rolling, and the shape of the corrugation may be variously formed without being limited to a round shape, a bent rectangular shape, or the like.

As described above, by using the corrugated web 10 made of the corrugated steel sheet, the buckling and twisting strength can be improved and plastic deformation can be induced, thereby absorbing and attenuating the horizontal load and securing the structural stability and usability of the structure .

Particularly, such a corrugated web 10 is provided with an end face reduced portion 13 having a shape in which a central portion of both end portions in the width direction is drawn inward, When a large horizontal load such as an earthquake load is generated, both end portions of the corrugated web 10 fixed to the first and second fixing plates 20 and 30 have relative displacements in the horizontal direction. At this time, the corrugated web 10 The resilient and plastic deformation of the section reducing portion 13, which is a weak portion of the structure, is attenuated and the energy of the structure is attenuated.

The end face reduction portion 13 can be formed by cutting, folding, or the like in a certain range of the center portion in the height direction of the corrugated web 10.

A plurality of corrugated webs 10 are formed between the first and second fixing plates 20 and 30. In this case, the corrugated webs 10 may be arranged in a row or in parallel so that the directions of the corrugation coincide with each other. , 30) by various known methods such as welding, bracket bonding, or the like.

3, the viscoelastic damper member 60 is coupled to the outer sides of the first and second fixing plates 20 and 30, and the viscoelastic damper 60 using the high-damping rubber 62 and the deformation inducing steel bar 10 and the vertical load supporting steel bar 40 to dissipate the energy by the characteristics of the viscoelastic damper and the steel material history damper.

As shown in the figure, the viscoelastic damper member 60 is coupled to the outer sides of the first and second fixing plates 20 and 30. The first and second connecting members 61 and 61, And a high-damping rubber (62) is formed between the rubber (63).

The first connecting member 61 is formed to have a predetermined length of the H-shaped cross section to facilitate the engagement with the first and second fixing plates 20 and 30 and the coupling plate 611 to the other end, 62 are interviewed. One end of the first linking member 61 is joined to the outside of the first and second fixing plates 20 and 30 of the composite damper 100 by various methods known for welding or the like.

The second connecting member 63 is formed to have a predetermined length of the H-shaped cross section, and the coupling plates 631 and 632 are coupled to the one end and the other end, respectively, to provide a space for installing the highly damped rubber 62, It is possible to facilitate the installation with the steel frame or the like.

The coupling plates 611, 631 and 632 and the high-damping rubber 62 may be formed with a plurality of coupling holes 611a, 621a, 631a and 632a for bolt coupling.

Particularly in the second coupling member 63 of the viscoelastic damper member 60, the coupling hole 631a is formed in the coupling plate 631 at one end so as to be elongated so that the first coupling member 61 and the second coupling member 63 The high-damping rubber 62 is slid in a state of being press-fitted along the engagement hole 631a of the elongated hole when receiving a wind load or the like so that the high-damping rubber 62 is slid on the first connecting member 61 And the joining plates 611 and 631 of the second linking member 63 to absorb the energy while performing viscoelastic resistance and deformation.

In the composite damper 100 constituted of the high-damping rubber and the deformation-inducing steel bar combined as described above, the energy is dissipated by the characteristics of the viscoelastic damper using the high-damping rubber 62 in the event of wind or minute deformation, The steel rod 40 supports the vertical load and resists in the horizontal direction according to the relative displacement of the ends of the deformation inducing steel bar 10 fixed to the first and second fixing plates 20 and 30 and the first and second fixing plates.

4 is a schematic view illustrating the behavior of a composite damper constituted by a highly damped rubber and a corrugated web according to the present invention.

As shown in FIG. 4, when a horizontal load is applied to a moment frame, rotation of the lower end of the moment-connected column and the column-to-beam connection is restrained, and the column is horizontally displaced .

If a damper is installed in the horizontal displacement area (D) of the column, the damper is not subjected to axial force and is used as a member absorbing the horizontal load.

A plurality of corrugated webs 10 are installed where energy dissipation is highly required, and the energy dissipating capacity of the damper can be easily adjusted by providing a few corrugated webs 10 where energy dissipation is not required. To be more specific, the damper functions as a damping structure to prevent the structural members of the building from collapsing against the lateral load due to the earthquake, and the total cross-sectional area of the corrugated web 10 is determined according to the designed value of the lateral load to withstand. Therefore, it is possible to cope with the required performance adequately by a simple method of adjusting the number of the corrugated webs 10 to be manufactured as a unit unit considering the design value of the lateral load.

5 is a cross-sectional view of a steel frame-type vibration damper including a composite damper constituted by a highly damped rubber and a corrugated web according to the present invention.

A steel frame type vibration damper including a composite damper including a high-damping rubber and a corrugated web according to the present invention includes an upper horizontal member 110 coupled to an upper slab or a lower surface of a structure, a lower- A vertical member 130, 130 vertically coupled at both ends of the upper horizontal member 110, a lower vertical member 130 vertically coupled to both ends of the lower horizontal member 120, 140, 140), and a composite damper (100) comprising a highly damped rubber and corrugated web disposed between the upper vertical members (130, 130) and the lower vertical members (140, 140).

The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 may be formed of various shapes and materials as members for forming a frame. For example, in this embodiment, A steel frame is formed by an H-type roll beam. If a steel frame is formed using an existing H-type roll beam, it is advantageous in that it is easy to manufacture and economical.

6 is a perspective view of a main portion of a steel frame type vibration damper including a composite damper constituted of a highly damped rubber and a corrugated web according to the present invention.

As shown in FIG. 6, the upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are formed by H-shaped roll beams which are rolled and cast into an H-shaped section, The joint plates 131 and 141 are provided and the joint plate 632 and the joint plates 131 and 141 of the viscoelastic damper member 60 can be bolted to each other and further welded.

The frame type vibration damper including the composite dampers constituted by the high-damping rubber and the deformation-inducing steel bar according to the present invention can be installed in existing or elongated moment frame structures and can be used for seismic reinforcement of the structures.

As shown in FIG. 4, if a damper of a moment frame shape is fabricated to constitute a composite damper composed of a high-damping rubber and a corrugated web in the deformation section D of the vertical member, the frame- So that the composite damper constituted by the high-damping rubber and the corrugated web provided in the deformation section (D) is subjected to shear deformation. The deformation of the structure is not occurred even after the earthquake load, and the shear deformation is concentrated only in the composite damper constituted by the high damping rubber and the corrugated web even in the frame type vibration damper. Even if a high-intensity earthquake occurs, the seismic energy is absorbed by the carbon and plastic deformation of the composite damper constituted by the high-damping rubber and corrugated web of the frame-type vibration damper, and only the steel bar of the composite damper constituted of the high- Additional installation can be easily repaired with the framework of the condition before the earthquake damage, so it is easy to repair.

7 is a cross-sectional view of a reinforced concrete frame type vibration damper including a composite damper constituted by a highly damped rubber and a corrugated web according to the present invention.

Since the present embodiment is the same as the previous embodiment except for the constituent material of the frame, repeated explanation is omitted. Unlike the previous embodiment, the upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 constituting the frame are made of reinforced concrete in this embodiment. The amount of reinforcement (not shown) and the location of the reinforcement placed in the reinforced concrete frame are determined by the structural calculation.

The upper horizontal member 110 and the upper vertical members 130 and 130 may be integrally formed in a U shape and the lower horizontal member 120 and the lower vertical members 140 and 140 may be integrally formed. One end of the anchor bolts 132 and 142 is embedded in the upper and lower vertical members 130 and 140 in advance so that the other ends of the anchor bolts 132 and 142 protrude from the upper and lower vertical members 130 and 140 do. The composite damper 100 constituted by the highly damped rubber and corrugated web in such a manner that the anchor bolts 132 and 142 protruded from the coupling plate 632 of the viscoelastic damper member 60 are nut- Can be installed in the frame.

Hereinafter, a description will be given of a method of reinforcing a frame-type vibration damper including a composite damper constituted as described above according to the present invention by a high-damping rubber and a corrugated web, in a conventional or expansion-moment frame structure.

First, the upper and lower vertical members 130 and 130 and the lower horizontal member 120, which are vertically coupled at both ends of the upper horizontal member 110 and the composite damper 100, (A), which are vertically coupled to the lower vertical members 140 and 140, respectively.

Subsequently, the upper horizontal member 110 is joined to the upper slab or lower surface of the structure and the lower horizontal member 120 is joined to the lower slab or beam surface of the structure (b).

At this time, a space is formed between the upper vertical members 130 and 130 and the lower vertical members 140 and 140. The upper vertical members 130 and 130 and the lower vertical members 140 and 140 are spaced apart from the pillars of the structure, .

As described above, an H-shaped roll beam that is rolled and cast into an H-shaped section can be used as the upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 as members for forming a frame.

Next, a composite damper 100 having a high-damping rubber and corrugated webs is installed in a space between the upper vertical members 130 and the lower vertical members 140, 140 (c).

It is preferable that the joint plates 131 and 141 are installed at the connecting portions of the upper and lower vertical members 130 and 140 and the joint plate 632 and the joint plates 131 and 141 are bolted to each other.

Alternatively, the upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140, which are members for forming the frame, may be made of reinforced concrete. At this time, it is preferable that the upper horizontal member 110 and the upper vertical members 130 and 130 are integrally formed in a C shape, and the lower horizontal member 120 and the lower vertical members 140 and 140 are integrally formed in a C shape. One end of the anchor bolts 132 and 142 is embedded in the upper and lower vertical members 130 and 140 in advance so that the other ends of the anchor bolts 132 and 142 protrude from the upper and lower vertical members 130 and 140 do. The composite damper 100 constituted by the high-damping rubber and the corrugated web in a manner that the anchor bolts 132 and 142 protruded from the coupling plate 632 of the visco-elastic damper member 60 are nut- Can be installed in frame

The frame type vibration damper including the composite damper and the composite damper including the highly damped rubber and corrugated web of the present invention as described above, and the method for seismic strengthening using the damper are provided with a viscoelastic damper using a high-damping rubber, a vertical load- The composite damper is constructed to dissipate energy by the characteristics of a viscoelastic damper using a high-damping rubber when wind or small deformation occurs. For a horizontal load such as an earthquake, a corrugated web is elastically deformed to absorb a horizontal load And it is possible to secure the structural stability and usability of the structure by attenuating it. The structure is simple, and it is easy to manufacture and install, and the cost is low, so that it can contribute to the improvement of the productivity. In addition, It is absorbed by the elastic deformation of the vibration suppression device If you have a very useful effect, easy maintenance can easily revert back to the state before the earthquake wear Frames.

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: Waveform web
13:
20: first fixing plate
30: Second fixing plate
60: Viscoelastic damper member
61: first connecting member
62: Highly damped rubber
63: second connecting member
100: Composite damper consisting of highly damped rubber and corrugated web
110: upper horizontal member
120: Lower horizontal member
130: upper vertical member
140: Lower vertical member
131, 141: upper and lower vertical member joint plates
132, 142: upper and lower vertical member anchor bolts

Claims (10)

First and second fixing plates (20, 30) arranged parallel to each other with a predetermined distance in a plate shape;
A corrugated web 10 formed of a corrugated steel sheet and having a plurality of corrugated webs spaced apart from each other by connecting the first and second fixing plates 20 and 30 with the first and second fixing plates 20 and 30, ;
A first linking member 61 formed at a predetermined length of the H-shaped cross section and coupled to an engaging plate 611 formed at the other end thereof with a plurality of engaging holes 611a, A plurality of coupling holes 631a and 632a are formed at one end and the other end of the H-shaped cross section, respectively, and a coupling plate 631 The engaging holes 631a are engaged with the engaging plates 631 and 632 which are elongated holes so that the engaging plate 611 and the high attenuation rubber 62 and the engaging plate 631 And one end of the first connecting member 61 is connected to the outside of the first and second fixing plates 20 and 30 of the composite damper 100, And a viscoelastic damper member (60) configured to form a high-damping rubber and corrugated web Compound damper. The method according to claim 1,
Characterized in that the corrugated web (10) has a central portion at both ends in the width direction drawn inward to constitute an end face reduction portion (13). An upper horizontal member (110) coupled to the upper slab or lower surface of the structure;
A lower horizontal member 120 coupled to the lower slab or beam surface of the structure;
Upper vertical members 130 and 130 vertically coupled at both ends of the upper horizontal member 110;
A lower vertical member 140, 140 spaced in series with the upper vertical member and vertically coupled to opposite ends of the lower horizontal member 120;
First and second fixing plates (20, 30) arranged parallel to each other with a predetermined distance in a plate shape;
A corrugated web 10 formed of a corrugated steel sheet and having a plurality of corrugated webs spaced apart from each other by connecting the first and second fixing plates 20 and 30 with the first and second fixing plates 20 and 30, A first connecting member 61 formed at a predetermined length of the H-shaped cross section and coupled to an engaging plate 611 having a plurality of engaging holes 611a formed at the other end thereof, A plurality of coupling holes 631a and 632a are formed at one end and the other end, respectively, of the H-shaped cross section, The coupling plate 631 and the coupling plate 631 are coupled to each other through the coupling plate 631 and the coupling plate 631. The coupling plate 631 and the coupling plate 631 are coupled to each other through the coupling plate 631 and the high- And a second connecting member 63 configured to be coupled to the first connecting member 61 with the bolts 70, And a viscoelastic damper member 60 configured to be joined to the outer sides of the first and second fixing plates 20 and 30 of the respective composite dampers 100 so as to be positioned between the upper vertical members 130 and 130 and the lower vertical members 140 and 140 Wherein the damper comprises a high damper rubber and a corrugated web. The method of claim 3,
Wherein the corrugated web (10) is constructed such that a central portion of both end portions in the width direction is drawn inward to constitute an end face reduction portion (13). The method of claim 3,
The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are constituted by an H-shaped roll beam which is rolled and cast in an H-shaped section,
The joint plates 131 and 141 are installed at the connecting portions of the upper and lower vertical members 130 and 140,
Characterized in that the coupling plate (632) of the viscoelastic damper member (60) and the joint plates (131, 141) are bolted to each other, and the high damping rubber and the corrugated web are constituted. The method of claim 3,
The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are made of reinforced concrete and the upper horizontal member 110 and the upper vertical members 130 and 130 are integrally formed in a U- 120 and the lower vertical members 140, 140 are integrally formed in a U-
One end of the anchor bolts 132 and 142 is embedded in the upper and lower vertical members 130 and 140 and the other end of the anchor bolts 132 and 142 protrudes from the upper and lower vertical members 130 and 140 on the upper and lower vertical members 130 and 140 ,
Characterized in that the anchor bolts (132, 142) protruding from the coupling plate (632) of the viscoelastic damper member (60) are nut-engaged. (a) first and second fixing plates 20 and 30 formed parallel to each other with a predetermined distance from each other in a plate shape, and corrugated steel plates joined to the first and second fixing plates 20 and 30, respectively, And a plurality of coupling holes 611a formed at a predetermined length of the H-shaped cross section and having a plurality of coupling holes 611a formed therein, A first connecting member 61 to which the plate 611 is coupled and a highly damped rubber 62 which is formed on the outside of the coupling plate 611 of the first connecting member 61, And a plurality of coupling holes 631a and 632a are formed at one end and the other end of the coupling plate 631. A coupling plate 631 and an elongated coupling plate 633 are coupled to the coupling plate 631 at one end, The high damping rubber 62 and the coupling plate 631 are combined with the bolts 70 at the outside of the damping rubber 62 And the first connecting member 61 is connected to the outside of the first and second fixing plates 20 and 30 of the composite damper 100. The viscoelastic damper member The upper horizontal member 110 and the upper vertical members 130 and 130 vertically coupled at both ends of the upper horizontal member 110 and the lower horizontal member 120 and the lower horizontal member 110, (140, 140) vertically coupled to both ends of the lower vertical member (120);
(b) coupling the upper horizontal member (110) to the upper slab or beam surface of the structure and coupling the lower horizontal member (120) to the lower slab or beam surface of the structure; And
(c) installing the composite damper (100) between the upper vertical members (130, 130) and the lower vertical members (140, 140). The method of claim 7,
In step (a)
Wherein the corrugated web (10) of the composite damper (100) is drawn inward at the center of both end portions in the width direction to constitute an end face reduction portion (13). The method of claim 7,
In step (a)
The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are formed by H-shaped roll beams that are rolled and cast into an H-shaped section. The joint plates 131 and 141 are installed at connection portions of the upper and lower vertical members 130 and 140 And,
In the step (c)
Wherein the joint plate (632) of the viscoelastic damper member (60) and the joint plates (131, 141) are bolted to each other. The method of claim 7,
In step (a)
The upper and lower horizontal members 110 and 120 and the upper and lower vertical members 130 and 140 are made of reinforced concrete and the upper horizontal member 110 and the upper vertical members 130 and 130 are integrally formed in a U- 120 and the lower vertical members 140, 140 are integrally formed in a U-
In the step (c)
One end of the anchor bolts 132 and 142 is embedded in the upper and lower vertical members 130 and 140 and the other end of the anchor bolts 132 and 142 protrudes from the upper and lower vertical members 130 and 140 on the upper and lower vertical members 130 and 140 ,
Wherein the anchor bolts (132, 142) protruding from the coupling plate (632) of the viscoelastic damper member (60) are nut-engaged.

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