KR20110018283A - Linear and rotational friction damper and earthquake energy damping device using thereof - Google Patents

Abstract

PURPOSE: A linear and rotational friction damper and an earthquake-proof reinforcing device using the same are provided to facilitate installation on existing structures, since a linear and rotational friction damper and a steel frame member are coupled and modularized. CONSTITUTION: A linear and rotational friction damper comprises a first central member(110), a second central member(120), and a geostatic member(130). The first central member is formed with multiple circular arc cut portions(22). The second central member comprises faces to one side of the first central member and comprises a straight cut portion(33). The geostatic member connects the first central member and the second central member.

Description

Linear and rotary friction dampers, seismic reinforcement device using the same {Linear and Rotational Friction Damper and Earthquake Energy Damping Device using glowing}

The present invention relates to a friction damper for effectively damping the seismic energy by the friction force generated in the rotational motion and the linear motion process, and a seismic reinforcement device using the same.

Seismic reinforcement method using hydraulic damper and seismic reinforcement method using steel damper are used as seismic reinforcement method of steel structure or concrete structure which is used at home and abroad.

     Among the existing technologies, the seismic reinforcement method using hydraulic dampers is a technology mainly used in Japan, where earthquakes occur frequently throughout the country. The design is relatively improved so that the external environment is not rough, and the seismic reinforcement performance is excellent, but domestic environmental Considering factors, firstly, the construction cost is excessively necessary, and secondly, there is a possibility that the reinforcement will be excessively unnecessary in view of the domestic earthquake frequency or progress.

     Seismic reinforcement method using steel damper is a technology that has been developed at home and abroad recently and it can be said that the construction cost is relatively inexpensive, but it is mainly developed for steel structure reinforcement, and it is also a structural problem of existing steel damper. In the case of structures, the use of windows and entrances, etc. are inconveniently restricted, and the appearance of the product is rough, which not only impairs the aesthetics of the structure, but also causes emotional anxiety, and is applicable to the seismic reinforcement of RC structures with less deformation than steel structures. There is a difficult problem.

Therefore, excessive reinforcement and excessive construction cost, which are the problems of reinforcement method using the existing hydraulic damper, and aesthetic deterioration and emotional anxiety caused by the rough appearance, which is a problem of the existing steel damper, limiting the usability of windows and entrances, limiting the scope of application, etc. There is an urgent need for new means to solve the problems and achieve the optimum seismic effect at a reasonable cost.

In order to solve the above-mentioned problems, the object of the present invention is as follows.

First, it is an object of the present invention to provide a friction damper of a new concept that efficiently absorbs seismic energy by using the friction force generated in the rotational motion and linear motion process.

Second, it is another object of the present invention to provide a seismic reinforcement device that can be easily mounted on existing structures by modularizing the friction damper of the new concept and the steel member installed in the horizontal or vertical direction.

Thirdly, the present invention provides a new concept of seismic reinforcing device which can prevent the deformation of the steel member constituting the seismic reinforcing device by maximizing the frictional force of the friction damper and achieve a stable high efficiency seismic energy damping effect even in a major earthquake. Another purpose.

Fourth, it is another object of the present invention to provide a seismic energy damping device with a beautiful appearance to solve the emotional anxiety and cause aesthetics.

The technical configuration for achieving the object of the present invention is as follows.

The present invention includes a first central member (110) having a plurality of arc cutouts (22) cut in an arc shape at a predetermined distance about a hollow (11) formed on one side; A second central member 120 having one side arranged to face one side of the first central member 110 to form a straight line and having a plurality of linear cutouts 33 cut in a straight line in a horizontal direction; And a plurality of bolt holes 44 formed at positions corresponding to the arc cut portion 22 of the first central member 110 and the straight cut portion 33 of the second central member 120. A pair of acupressure members that are in close contact with the front and rear surfaces of the first central member 110 and the second central member 120 to connect the first central member 110 and the second central member 120 to one; 130 and a pair of acupressure members 130 are coupled to the first central member 110 when the nut is fastened to a bolt passing through the bolt holes 44 of the pair of acupressure members 130. ) And a linear and rotary friction damper for pressing the second central member 120.

In addition, the present invention the upper horizontal steel member 210 is installed in a horizontal direction; Straight and rotary friction damper 1 (101) coupled to the center lower portion of the upper horizontal steel member 210 in the vertical direction; A central vertical steel member 240 coupled to the lower portion of the straight and rotary friction damper 1 101 in a vertical direction; Another straight and rotary friction damper 2 (102) coupled to the lower portion of the central vertical steel member 240 in the vertical direction; And a lower horizontal steel member 220 coupled to a lower center of the linear and rotary friction damper 2 102 and installed in a horizontal direction. to provide.

Technical effects of the configuration of the present invention are as follows.

First, the seismic energy can be efficiently absorbed by using the frictional force generated during the rotational and linear motions.

Second, by combining the new damping friction damper with the steel frame members installed in the horizontal or vertical direction can be easily mounted on existing structures.

Third, it is possible to prevent the deformation of the steel frame member constituting the seismic reinforcement device to the maximum by utilizing the frictional force of the friction damper to maximize the seismic energy damping effect of stable high efficiency even in the earthquake.

Fourth, by providing a seismic energy damping device with a beautiful appearance, it can induce aesthetics and relieve emotional anxiety.

1 is a specific embodiment of the linear and rotary friction dampers.
2 is another specific embodiment of the linear and rotary friction dampers.
3 is another specific embodiment of the linear and rotary friction dampers.
Figure 4 shows the earthquake (shock) behavior of the seismic reinforcement device using a linear and rotary friction damper.
5 is a concrete embodiment of the seismic reinforcing device, which is of " I " shape and two linear and rotary friction dampers are used.
Fig. 6 is a specific embodiment of the seismic reinforcing device, in which " I " shape is used, and one linear and rotary friction damper is used.
7 is a concrete embodiment of the seismic reinforcing device, a total of four linear and rotary friction dampers forming a "?" Shape is used.
FIG. 8 is a concrete embodiment of the seismic reinforcing device, which has a shape of “?” And a total of two linear and rotary friction dampers are used.
9 is a specific embodiment of the seismic reinforcing device, a total of four linear and rotary friction dampers forming a "ㅁ" shape is used.
10 is a concrete embodiment of the seismic reinforcing device, which has a shape of "ㅁ" and a total of two linear and rotary friction dampers are used.
11 schematically shows an earthquake-proof reinforcement apparatus expanded in various forms according to the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a specific embodiment of a linear and rotary friction damper, it is composed of a first central member 110, a second central member 120, and a pair of acupressure member 130.

One side of the first central member 110 is provided with a plurality of arc cut portions 22 cut in an arc shape at a predetermined distance around the hollow 11, and is made of a metal material such as a general steel sheet.

One side of the second central member 120 is arranged so as to face one side of the first central member 110 to form a straight line, a plurality of straight line incisions 33 of the straight form arranged in the horizontal direction is provided, the first Like the central member 110 is made of a metal material such as a general steel sheet.

The pair of acupressure members 130 are provided with a plurality of bolt holes 44 at positions corresponding to the arc cut portions 22 of the first central member 110 and the straight cut portions 33 of the second central member 120. Is formed, is in close contact with each of the front and rear surfaces of the first central member 110 and the second central member 120 serves to connect the first central member 110 and the second central member 120 as one, When the nut is fastened to the bolt passing through the bolt hole 44 of the pair of acupressure members 130, the pair of acupressure members 130 compresses the first central member 110 and the second central member 120. to be. The acupressure member 130 is also made of a metal material such as a general steel sheet.

FIG. 2 illustrates a case in which the first friction pad 140 and the second friction pad 150 are added as another specific embodiment of the linear and rotary friction dampers.

The first friction pad 140 is inserted between the acupressure member 130 and the first central member 110, respectively, and an arc cutout portion having a shape corresponding to the circular arc cutout portion 22 of the first central member 110 ( 22).

The second friction pad 150 is sandwiched between the acupressure member 130 and the second central member 120, respectively, and a straight cut portion having a shape corresponding to the straight cut portion 33 of the second central member 120. 33).

The first friction pad 140 and the second friction pad 150 are relative movements of the acupressure member 130 and the first central member 110 or relative movements of the acupressure member 130 and the second central member 120. When this occurs, it generates friction heat and serves to resist the movement. Generally, a friction member of non-asbestos material is selected. In addition, the first friction pad 140 and the second friction pad 150 may be made of various kinds of metal members such as stainless steel and aluminum.

3 is another specific embodiment of the linear and rotary friction dampers, unlike the first central member 110, the second central member 120 is an H or I-shaped steel consisting of a web and a flange, and a straight cut portion ( 33) is a structure formed on the web surface. Otherwise, the same duplicate description as that of FIG. 2 is omitted.

The linear and rotary friction dampers shown in FIGS. 1 to 3 absorb impact energy with frictional heat according to frictional force when relative movement occurs due to external impact, thereby minimizing damage and deformation of the structure. Coupled with the steel members can be used as a modular product (seismic reinforcement device).

Fig. 5 is a concrete embodiment of the seismic reinforcing device, in which " I " shape is used, and two linear and rotary friction dampers 1, 2 (101, 102) are used. As the linear and rotary friction dampers 1 and 2 101 and 102 used herein, any one of the specific embodiments shown in FIGS. 1 to 3 may be selected.

The upper horizontal steel member 210 is installed in a horizontal direction to serve as an upper frame, and steel members of various structures and shapes may be selected.

The linear and rotary friction damper 1 (101) is coupled to the center lower portion of the upper horizontal steel member 210 in the vertical direction to serve to absorb the impact energy due to the earthquake with frictional heat.

The central vertical steel frame member 240 is coupled to the lower portion of the linear and rotary friction damper 1 (101) in the vertical direction to serve as a vertical frame, steel frame members of various structures and shapes can be selected.

The lower portion of the central vertical steel member 240 is provided with another linear and rotary friction damper 2 (102) coupled in the vertical direction serves to absorb the impact energy due to the earthquake with frictional heat.

The lower horizontal steel member 220 is installed in a horizontal direction by combining a central upper portion with a lower portion of the linear and rotary friction damper 2 102, and serves as a lower frame. Various steel structures having various structures and shapes may be selected.

The components constituting the seismic reinforcement device of FIG. 5 may be coupled by a bolt coupling or a welding coupling, and it is preferable to secure the coupling area to the maximum and to be firmly coupled.

Fig. 6 is a specific embodiment of the seismic reinforcing device, in which " I " shape is used, and one linear and rotary friction damper is used. As the linear and rotary friction dampers 100 used herein, any one of the specific embodiments illustrated in FIGS. 1 to 3 may be selected.

The upper horizontal steel member 210 is installed in the horizontal direction serves as an upper frame.

The upper vertical steel member 230 is coupled in a vertical direction to the center lower portion of the upper horizontal steel member 210 serves as a vertical frame with the lower vertical steel member 250.

The linear and rotary friction dampers 100 are coupled to the lower portion of the upper vertical steel frame member 230 in the vertical direction to absorb shock energy due to the earthquake as frictional heat.

The lower vertical steel member 250 is coupled to the lower portion of the straight and rotary friction damper 100 in the vertical direction to serve as a vertical frame with the upper vertical steel member 230.

The lower horizontal steel member 220 is installed in the horizontal direction by the center upper portion is coupled to the lower portion of the lower vertical steel member 250, and serves as a lower frame.

7 is a concrete embodiment of the seismic reinforcing device, a total of four linear and rotary friction dampers forming a "?" Shape is used. As the linear and rotary friction dampers 1 and 2 101 and 102 used herein, any one of the specific embodiments shown in FIGS. 1 to 3 may be selected.

The upper horizontal steel member 210 is installed in the horizontal direction serves as an upper frame.

The linear and rotary friction dampers 1 101 are respectively coupled to the lower sides of the upper horizontal steel member 210 in the vertical direction to absorb shock energy due to the earthquake as frictional heat.

Central vertical steel member 240 is coupled to the lower portion of each of the linear and rotary friction damper 1 (101) in the vertical direction to serve as a vertical frame.

The linear and rotary friction dampers 2 102 are coupled to the lower portion of each of the central vertical steel frame members 240 in the vertical direction to absorb shock energy due to the earthquake as frictional heat.

The anchor bolt mounting flange 260 is coupled to the lower portion of each of the linear and rotary friction damper 2 (102) in a horizontal direction, the hole through which the anchor bolt 55 passes is formed in the vertical direction. The anchor bolt 55 is used as a fixing means for mounting the present invention to the existing structure.

FIG. 8 is a concrete embodiment of the seismic reinforcing device, which has a shape of “?” And a total of two linear and rotary friction dampers are used. As the linear and rotary friction dampers 100 used herein, any one of the specific embodiments illustrated in FIGS. 1 to 3 may be selected.

The upper horizontal steel member 210 is installed in the horizontal direction serves as an upper frame.

The upper vertical steel member 230 is coupled to each of the lower sides of the upper horizontal steel member 210 in the vertical direction to serve as a vertical frame.

The linear and rotary friction dampers 100 coupled to the lower portions of the upper vertical steel frame members 230 absorb the impact energy due to the earthquake as friction heat.

The lower vertical steel member 250 is coupled to the lower portion of each of the linear and rotary friction dampers 100 in a vertical direction to serve as a vertical frame together with the upper vertical steel member 230.

The anchor bolt mounting flange 260 is coupled to the lower portion of each of the lower vertical steel member 250 in the horizontal direction, the hole through which the anchor bolt 55 passes is formed in the vertical direction. The anchor bolt 55 is used as a fixing means for mounting the present invention to the existing structure.

9 is a specific embodiment of the seismic reinforcing device, a total of four linear and rotary friction dampers forming a "ㅁ" shape is used. As the linear and rotary friction dampers 1 and 2 101 and 102 used herein, any one of the specific embodiments shown in FIGS. 1 to 3 may be selected.

The upper horizontal steel member 210 is installed in the horizontal direction serves as an upper frame.

The linear and rotary friction dampers 1 101 are respectively coupled to the lower sides of the upper horizontal steel member 210 in the vertical direction to absorb shock energy due to the earthquake as frictional heat.

Central vertical steel member 240 is coupled to the lower portion of each of the linear and rotary friction damper 1 (101) in the vertical direction to serve as a vertical frame.

The linear and rotary friction dampers 2 102 are coupled to the lower portion of each of the central vertical steel frame members 240 in the vertical direction to absorb shock energy due to the earthquake as frictional heat.

The lower horizontal steel member 220 is coupled to both sides of the upper and lower portions of each of the linear and rotary friction dampers 2 (102) is installed in the horizontal direction and serves as a lower frame.

10 is a concrete embodiment of the seismic reinforcing device, which has a shape of "ㅁ" and a total of two linear and rotary friction dampers are used. As the linear and rotary friction dampers 100 used herein, any one of the specific embodiments illustrated in FIGS. 1 to 3 may be selected.

The upper horizontal steel member 210 is installed in the horizontal direction serves as an upper frame.

The upper vertical steel member 230 is coupled to each of the lower sides of the upper horizontal steel member 210 in the vertical direction to serve as a vertical frame.

The linear and rotary friction dampers 100 are coupled to the lower portions of the upper vertical steel frame members 230 to absorb shock energy due to the earthquake as friction heat.

The lower vertical steel member 250 is coupled to the lower portion of each of the linear and rotary friction dampers 100 in a vertical direction to serve as a vertical frame together with the upper vertical steel member 230.

The lower horizontal steel member 220 is installed at both sides of the lower vertical steel frame member 250, the upper side is coupled in the horizontal direction and serves as a lower frame.

Specific examples of the seismic reinforcement apparatus using the linear and rotary friction dampers are shown in FIGS. Can be.

Figure 4 shows the behavior according to the seismic load of a specific embodiment (shape shown in Figure 9) of the seismic reinforcing device according to the present invention.

When the horizontal load due to the earthquake acts on the upper horizontal steel member 210 is formed on the first central member 110, acupressure member 130 and the first friction pad 140 of the linear and rotary friction damper 100 Relative rotational movements are made along each other along the cutout shape of the arc cutout 22, and in this process, the seismic energy is attenuated by frictional heat.

In addition, relative linear movements are made along the cutouts of the linear cutouts 33 formed on the second central member 120, the acupressure member 130, and the second friction pad 150, and frictional heat generated in the process. As the earthquake energy is reduced, the deformation of the central vertical steel member 240 is prevented. This is because the flow distance of the central vertical steel member 240 can be secured by the length of the incision of the straight cutout 33.

As described above, the technical spirit of the present invention has been described with reference to specific embodiments of the present invention, but the protection scope of the present invention is not necessarily limited to these embodiments, and various designs may be made without changing the technical spirit of the present invention. Changes, additions or deletions of well-known technology, and simple numerical limitations also make it clear that they belong to the protection scope of the present invention.

Codes relating to linear and rotary friction dampers are divided into 100, 101, and 102 for convenience of explanation.
100: straight and rotary friction damper
101: linear and rotary friction damper 1
102: straight and rotary friction damper 2
110: first center member
120: second center member
130: acupressure member
140: first friction pad
150: second friction pad
210: upper horizontal steel member
220: lower horizontal steel member
230: upper vertical steel member
240: central vertical steel member
250: lower vertical steel member
260: anchor bolt mounting flange
11: Hollow
22: arc incision
33: straight incision
44: Bolt hole
55: anchor bolt

Claims (9)

A first central member 110 having a plurality of arc cutouts 22 cut in an arc shape at a predetermined distance with respect to the hollow 11 formed at one side;
A second central member 120 having one side arranged to face one side of the first central member 110 to form a straight line and having a plurality of linear cutouts 33 cut in a straight line in a horizontal direction; And,
A plurality of bolt holes 44 are formed at positions corresponding to the arc cut portions 22 of the first central member 110 and the straight cut portions 33 of the second central member 120. A pair of acupressure members 130 in close contact with the front and rear surfaces of the central member 110 and the second central member 120 to connect the first central member 110 and the second central member 120 as one. ;
It is configured to include,
When the nut is fastened to the bolt that has passed through the bolt hole 44 of the pair of acupressure members 130, the pair of acupressure members 130 is connected to the first central member 110 and the second central member 120. Linear and rotary friction damper, characterized in that the compression). In claim 1,
First friction between the acupressure member 130 and the first central member 110 is provided with an arc cut portion 22 of a shape corresponding to the arc cut portion 22 of the first central member 110, respectively. Pad 140;
More is included,
Second friction between the acupressure member 130 and the second central member 120 is provided with a straight cut portion 33 of a shape corresponding to the straight cut portion 33 of the second central member 120, respectively. Pad 150;
Straight and rotary friction damper, characterized in that it further comprises. In claim 2,
The second central member 120 is an H or I-shaped steel consisting of a web and a flange, the straight cut portion 33 is a straight and rotary friction damper, characterized in that formed on the web surface. As related to the seismic reinforcement device using a linear and rotary friction damper of any one of claims 1 to 3,
An upper horizontal steel member 210 installed in a horizontal direction;
Straight and rotary friction damper 1 (101) coupled to the center lower portion of the upper horizontal steel member 210 in the vertical direction;
A central vertical steel member 240 coupled to the lower portion of the straight and rotary friction damper 1 101 in a vertical direction;
Another straight and rotary friction damper 2 (102) coupled to the lower portion of the central vertical steel member 240 in the vertical direction; And,
A lower horizontal steel member 220 coupled to a central upper portion of the straight and rotary friction damper 2 102 and installed in a horizontal direction;
Seismic reinforcement device using a straight and rotary friction damper, characterized in that configured to include. As related to the seismic reinforcement device using a linear and rotary friction damper of any one of claims 1 to 3,
An upper horizontal steel member 210 installed in a horizontal direction;
An upper vertical steel frame member 230 coupled to the center lower portion of the upper horizontal steel frame member 210 in a vertical direction;
Linear and rotary friction dampers 100 coupled to the lower portion of the upper vertical steel member 230 in a vertical direction;
A lower vertical steel member 250 coupled to the lower portion of the straight and rotary friction dampers 100 in a vertical direction; And,
A lower horizontal steel member (220) having a central upper portion coupled to a lower portion of the lower vertical steel member (250) and installed in a horizontal direction;
Seismic reinforcement device using a straight and rotary friction damper, characterized in that configured to include. As related to the seismic reinforcement device using a linear and rotary friction damper of any one of claims 1 to 3,
An upper horizontal steel member 210 installed in a horizontal direction;
Linear and rotary friction dampers 1 101 coupled to the lower sides of the upper horizontal steel member 210 in the vertical direction, respectively;
A central vertical steel frame member 240 coupled to the lower portion of each of the linear and rotary friction dampers 1 101 in a vertical direction;
Linear and rotary friction dampers 2 102 coupled to a lower portion of each of the central vertical steel frame members 240 in a vertical direction; And,
An anchor bolt mounting flange 260 coupled to a lower portion of each of the linear and rotary friction dampers 2 102 in a horizontal direction and having a hole through which the anchor bolt 55 passes;
Seismic reinforcement device using a straight and rotary friction damper, characterized in that configured to include. As related to the seismic reinforcement device using a linear and rotary friction damper of any one of claims 1 to 3,
An upper horizontal steel member 210 installed in a horizontal direction;
An upper vertical steel member 230 coupled to each of the lower sides of the upper horizontal steel member 210 in a vertical direction;
Linear and rotary friction dampers 100 coupled to the lower portions of the upper vertical steel frame members 230;
A lower vertical steel frame member 250 coupled to the lower portion of each of the linear and rotary friction dampers 100 in a vertical direction; And,
An anchor bolt mounting flange 260 coupled to a lower portion of each of the lower vertical steel frame members 250 and having a hole through which the anchor bolt 55 passes;
Seismic reinforcement device using a straight and rotary friction damper, characterized in that configured to include. As related to the seismic reinforcement device using any one of the linear and rotary friction damper (100) of claim 1,
An upper horizontal steel member 210 installed in a horizontal direction;
Linear and rotary friction dampers 1 101 coupled to the lower sides of the upper horizontal steel member 210 in the vertical direction, respectively;
A central vertical steel frame member 240 coupled to the lower portion of each of the linear and rotary friction dampers 1 101 in a vertical direction;
Linear and rotary friction dampers 2 102 coupled to a lower portion of each of the central vertical steel frame members 240 in a vertical direction; And,
A lower horizontal steel member 220 having both upper portions coupled to lower portions of each of the linear and rotary friction dampers 2 102 and installed in a horizontal direction;
Seismic reinforcement device using a straight and rotary friction damper, characterized in that configured to include. As related to the seismic reinforcement device using any one of the linear and rotary friction damper (100) of claim 1,
An upper horizontal steel member 210 installed in a horizontal direction;
An upper vertical steel member 230 coupled to each of the lower sides of the upper horizontal steel member 210 in a vertical direction;
Linear and rotary friction dampers 100 coupled to the lower portions of the upper vertical steel frame members 230;
A lower vertical steel frame member 250 coupled to the lower portion of each of the linear and rotary friction dampers 100 in a vertical direction; And,
A lower horizontal steel member 220 installed at both sides of the lower vertical steel member 250 in a horizontal direction by coupling both upper portions thereof;
Seismic reinforcement device using a straight and rotary friction damper, characterized in that configured to include.

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