KR101888879B1 - Steel Plate Damper with Improved seismic and vibration suppression performance - Google Patents

Abstract

The present invention relates to a steel damper with improved earthquake-proof and vibration damping performance. The steel damper comprises: an upper supporter connected to an upper part of a building; a lower supporter connected to a lower part of the building; a central panel having a central upper plate, of which an upper end is connected to the upper supporter and a central lower plate mounted at a lower side of the central upper plate to be spaced apart at a predetermined interval, and, of which a lower end is connected to the lower supporter; a left panel having a left upper plate mounted at the left side of the central upper plate and a left lower plate mounted at a lower side of the left upper plate to be spaced apart at a predetermined interval, wherein an upper end of the left upper plate is connected to the upper supporter and a lower end of the left lower plate is connected to the lower supporter; and a right panel having a right upper plate mounted at the right side of the central upper plate and combined with the central upper plate and the left upper plate by a plurality of fastening bolts penetrating laterally, and a right lower plate mounted at a lower side of the right upper plate to be spaced apart at a predetermined interval and combined with the central upper plate, the central lower plate and the left lower plate by a plurality of fastening bolts penetrating laterally, wherein an upper end of the right upper plate is connected to the upper supporter and a lower end of the right lower plate is connected to the lower supporter. Therefore, the steel damper can effectively absorb vibration at the time of earthquake in order to enhance buffering force and vibration-absorbing force.

Description

Technical Field [0001] The present invention relates to a steel damper with improved seismic and vibration damping performance,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a steel material damper, and more particularly, to a steel material damper having improved seismic and damping performance capable of efficiently absorbing external vibrations affecting a building.

In recent years, the construction of new buildings tend to be high-rise, and the high-rise phenomenon of such buildings is expected to be generalized considering the efficient use of limited land.

Due to the frequent occurrence of earthquakes in neighboring countries, it is confirmed that Korea is not a safe zone for earthquakes.

Therefore, if a natural disaster such as an earthquake or a typhoon occurs, high-rise buildings may suffer great damage due to vibration. Therefore, it is necessary to design a building for earthquake proofing, vibration isolation or seismic isolation. Have been developed and proposed.

However, recently proposed vibration absorbing devices such as dampers have a problem in that the structure is too complicated or the vibration absorbing effect is not high.

Application No. 10-2011-0088693 (Registration No. 10-1146790, entitled "Hybrid Vibration Isolation Device Combined with Viscoelastic Damper and Hysteretic Damper)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a steel damper with improved seismic and vibration damping performance that can absorb vibrations sequentially in the event of an earthquake to improve buffering capacity and vibration absorbing capacity .

According to an aspect of the present invention, there is provided a steel damper having improved vibration damping performance, comprising: an upper support connected to an upper side of a building; A lower support connected to a lower side of the building; A center panel comprising a central upper plate having an upper end connected to the upper support and a central lower plate spaced apart from the lower end of the central upper plate and having a lower end connected to the lower support; A left upper panel installed at a left side of the central upper plate and having an upper end connected to the upper support and a left lower panel disposed at a distance from the lower side of the left upper plate and having a lower end connected to the lower support, ; A right upper plate coupled to the center top plate and the left upper plate by a plurality of fastening bolts installed on the right side of the center top plate and having an upper end connected to the upper support and penetrating right and left, And a right panel formed of a central bottom plate, a central bottom plate, and a right bottom plate coupled to the center bottom plate and the left bottom plate by a plurality of fastening bolts which are installed at a predetermined distance from each other and whose lower ends are connected to the lower support.

The central upper plate, the left lower plate, and the right lower plate are formed with a plurality of vertically long through holes between the portions through which the fastening bolts pass.

The distance between the center top plate and the center bottom plate, the distance between the left top plate and the left bottom plate, and the distance between the right top plate and the right bottom plate are the same.

The center upper plate is longer in the vertical direction than the central bottom plate, and the left lower plate is longer in the vertical direction than the left upper plate, and the right lower plate is longer than the right upper plate Is formed longer.

In addition, the left bottom plate is longer in the vertical direction than the center top plate, and the vertical length is shorter than the right bottom plate.

The steel damper of the present invention having the above-described seismic and vibration damping performance of the present invention comprises a center top plate and a center bottom plate spaced from each other, a left top plate and a left bottom plate, a right top plate and a right bottom plate contacting each other, And the vibration absorbing force can be improved.

In addition, since the spacing space between the center top plate and the center bottom plate, the spacing space between the left top plate and the left bottom plate, and the spacing space between the right top plate and the right bottom plate are located at different heights, The steel damper is deformed sequentially without being deformed at the same time so that the vibration can be smoothly absorbed, thereby minimizing the influence of the vibration applied to the building.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1A and FIG. 1B are perspective views of a steel material damper with improved seismic and vibration damping performance according to the present invention. FIG.
2 is an exploded perspective view of a steel material damper with improved seismic and vibration damping performance according to the present invention.
FIG. 3A and FIG. 3B are sectional views of a steel material damper with improved seismic and vibration damping performance according to the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a steel material damper with improved seismic and vibration damping performance according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a steel damper with improved seismic and damping performance according to the present invention, FIG. 2 is an exploded perspective view of a steel damper with improved seismic and vibration damping performance according to the present invention, Sectional view of a steel material damper with improved seismic and vibration damping performance.

The steel damper with improved seismic and vibration damping performance according to the present invention is manufactured for the purpose of maintaining the structural stability of the building for a long time by absorbing various vibrations affecting the building. The steel damper has an upper support 10, 20, a center panel 30, a left panel 40, and a right panel 50.

The upper support 10 is connected to and fixed to the upper side of the building.

The lower support 20 is connected to and fixed to the lower side of the building. Accordingly, the upper support 10 and the lower support 20 are separated from each other by a certain distance.

The center panel 30 is installed between the upper support 10 and the lower support 20 and includes a central upper plate 31 and a central lower plate 31 spaced apart from the central upper plate 31 by a predetermined distance, (32).

The upper end of the central upper plate (31) is fixedly connected to the upper support (10). A plurality of fastening holes 31a through which the fastening bolts B pass are formed in the upper upper plate 31 and the lower lower part of the upper plate 31. The fastening bolts B pass through the fastening holes 31a A plurality of long through holes 31b are formed in parallel between the upper and lower fixed sections.

The length of the connecting hole 31a formed on the upper side of the central upper plate 31 is shorter than the length of the connecting hole 31a formed on the lower side of the central upper plate 31, And the through holes 31b are formed side by side along the width direction of the center top plate 31. [

The fastening hole 31a is a hole through which the fastening bolt B passes as described above and is a hole used for firmly fixing the left panel 40 and the right panel 50 to the center panel 30.

The through hole 31b is a slip damping section that minimizes the transmission of vibration and the like to the building by distorting the shape of the steel damper according to the present invention while absorbing the external force when an external force such as an earthquake acts.

And a lower end of the central bottom plate 32 is fixedly connected to the lower support 20. The central bottom plate 32 is formed with a plurality of fastening holes 32a through which the fastening bolts B are inserted in a lower lower part of the center bottom.

The fastening holes 32a formed in the central bottom plate 32 are holes through which the fastening bolts B are passed in the same manner as the fastening holes 31a formed in the center top plate 31. The fastening holes 32a are formed in the left and right panels 40, To the center panel (30).

On the other hand, in a normal state in which the vibration is not absorbed, the lower end of the center top plate 31 and the upper end of the middle bottom plate 32 are not in contact with each other, In this state, when the vibration generated by an earthquake or the like is absorbed, the lower end of the center top plate 31 and the upper end of the middle bottom plate 32 are brought into contact with each other.

The left panel 40 is installed on the left side of the center panel 30 between the upper support 10 and the lower support 20 and includes a left upper plate 41, And a left lower plate 42 which is installed at a predetermined distance away from the lower side.

The left upper plate 41 is installed on the left side of the center top plate 31, and its upper end is connected and fixed to the upper support table 10. The left upper plate 41 is formed with a plurality of fastening holes 41a through which the fastening bolts B pass.

The fastening hole 41a is a hole through which the fastening bolt B passes and is a hole used for closely fixing the center panel 30 and the right panel 50 to the left panel 40. [

And the lower end of the left lower plate 42 is fixedly connected to the lower support 20. A plurality of fastening holes 42a through which the fastening bolts B pass are formed in the upper left side plate 42 and the lower side portions of the left lower plate 42. The fastening holes 42a are formed between the portions through which the fastening bolts B penetrate, A plurality of through holes 42b extending in the vertical direction are formed between the upper and lower fixed sections and the lower left plate 42 along the width direction of the left lower plate 42. [

The length of the fastening hole 42a formed in the upper side of the left lower plate 42 is longer than the length of the fastening hole 42a formed in the lower side of the left lower plate 42, And the length of the section where the fastening hole 31a is formed is the same. The fastening bolt B passing through the fastening hole 42a formed on the lower side of the left lower plate 42 passes through the fastening hole 31a formed on the lower side of the center upper plate 31. [

The fastening hole 42a is a hole through which the fastening bolt B passes as described above and is a hole used for firmly fixing the center panel 30 and the right panel 50 to the left panel 40.

The through hole 42b is a slip damping section that minimizes the transmission of vibrations and the like to the building by distorting its shape while absorbing the external force when an external force such as an earthquake acts on the steel damper according to the present invention.

On the other hand, in a normal state in which the vibration is not absorbed, the lower end of the left upper plate 41 and the upper end of the left lower plate 42 are not in contact with each other and are kept apart from each other by a certain distance. In this state, when the vibration generated by an earthquake or the like is absorbed, the lower end of the left upper plate 41 and the upper end of the left lower plate 42 come into contact with each other.

The right panel 50 is installed between the upper support 10 and the lower support 20 and is installed on the right side of the center panel 30 and includes a right upper plate 51, And a lower right side plate 52 spaced apart from the lower side by a predetermined distance.

The right upper plate 51 is installed on the right side of the center top plate 31, and its upper end is connected to and fixed to the upper support plate 10. The right upper plate 51 has a plurality of fastening holes 51a through which the fastening bolts B pass through in a predetermined upper section.

The fastening hole 51a is a hole through which a plurality of fastening bolts B passing through right and left pass. The fastening bolt B is engaged with the central upper plate 31 and the left upper plate 41. That is, the left upper plate 41 and the right upper plate 51 come into close contact with both sides of the central upper plate 31, and in this state, the fastening bolts B are fastened to the left upper plate 41, A fastening hole 31a formed on the upper side of the central upper plate 31 and a fastening hole 51a formed on the right upper plate 51 and then the nut N is coupled to the end of the fastening hole 41a, The upper plate 41 and the central upper plate 31 and the upper right plate 51 are integrated.

The lower end of the right lower plate 52 is fixedly connected to the lower support 20. A plurality of fastening holes 52a through which the fastening bolts B pass are formed in the upper right side plate 52 and lower right side portions of the lower right side plate 52. The fastening holes 52a are formed between the portions through which the fastening bolts B pass, A plurality of through holes 52b extending in the up-and-down direction are formed side by side along the width direction of the right lower plate 52 between the upper certain period and the lower certain period.

The length of the fastening hole 52a formed in the upper side of the right lower plate 52 is longer than the length of the fastening hole 52a formed in the lower side of the lower right plate 52, And the length of the section where the fastening hole 31a is formed is the same. The fastening bolt B passing through the fastening hole 42a formed on the upper left side plate 42 is fastened to the fastening hole 31a formed on the lower side of the center upper plate 31 and the fastening hole 31a formed on the upper side plate 52a.

The fastening holes 52a formed on the lower side of the right lower plate 52 are in communication with the fastening holes 42a formed on the lower side of the left lower plate 42 and the fastening holes 32a formed on the middle lower plate 32, The right bottom plate 52 is connected to the center top plate 31 by the plurality of fastening bolts B passing through the fastening holes 52a in the left and right direction because the fastening bolts B pass through the holes 52a, And the central bottom plate 32 and the left bottom plate 42, respectively.

The fastening bolt B passing through the fastening hole 41a of the left upper plate 41 is formed in the upper panel 41. [ Passes through the fastening hole 31a formed on the upper side of the through hole 31b of the central upper plate 31 and then passes through the fastening hole 51a of the right upper plate 51 and then is coupled by the nut N .

The fastening bolt B that penetrates the fastening hole 42a formed on the upper side of the through hole 42b of the left lower plate 42 has a fastening hole 31a formed on the lower side of the fastening hole 31b of the center upper plate 31, And through the fastening hole 52a formed on the upper side of the through hole 52b of the lower right side plate 52, and is then screwed by the nut N. [

The fastening bolt B passing through the fastening hole 42a formed under the through hole 42b of the left bottom plate 42 passes through the fastening hole 32a of the center bottom plate 32, Through a fastening hole 52a formed on the lower side of the through hole 52b of the fastening hole 52b.

The through hole 52b formed in the right bottom plate 52 is a slip that minimizes the transmission of vibrations and the like to the building due to the distorted shape while absorbing the external force when an external force such as an earthquake acts on the steel damper according to the present invention. It is the attenuation section.

On the other hand, in a normal state in which vibration is not absorbed, the lower end of the right upper plate 51 and the upper end of the right lower plate 52 are not in contact with each other, and are kept apart from each other by a certain distance. In this state, when the vibration generated by the earthquake or the like is absorbed, the lower end of the right upper plate 51 and the upper end of the right lower plate 52 come into contact with each other.

The steel damper according to the present invention will be described in more detail with reference to the distance between the center top plate 31 and the center bottom plate 32 and the distance between the left top plate 41 and the left bottom plate 42, The distance between the plate 51 and the right lower plate 52 is the same.

The center upper plate 31 is longer than the central bottom plate 32 in the vertical direction and the left lower plate 42 is formed to have a longer length in the vertical direction than the left upper plate 41, Is longer than the right upper plate 51 in the vertical direction. In addition, the left lower plate 42 is formed to have a longer length in the vertical direction than the center top plate 31, and a shorter length in the vertical direction than the right lower plate 52 is formed.

Therefore, the space between the right top plate 51 and the right bottom plate 52 is located at the highest position, and the space between the left top plate 41 and the left bottom plate 42 is located thereunder, A spacing space between the center top plate 31 and the middle bottom plate 32 is located. The reason for this is to prevent the steel damper from being simultaneously deformed at the same time when the vibration generated by the earthquake or the like is transmitted to the steel damper so that the steel damper is deformed sequentially so that the vibration is absorbed smoothly,

The through hole 31b formed in the central upper plate 31 has the highest position and the left bottom plate 31b located on both sides of the through hole 31b, The through hole 42b and the through hole 52b of the right lower plate 52 are the same. Accordingly, the portions of the steel material damper in which the through holes 31b, 42b, 52b are formed are sequentially twisted and deformed while absorbing the external force due to vibration, so that the vibration can be smoothly absorbed.

10: upper support 20: lower support
30: center panel 31: center top plate
31a: fastening hole 31b: through hole
32: central bottom plate 32a: fastening hole
40: left panel 41: left upper plate
41a: fastening hole 42: left bottom plate
42a: fastening hole 42b: through hole
50: right panel 51: right upper plate
51a: fastening hole 52: right bottom plate
52a: fastening hole 52b: through hole
B: Fastening bolt N: Nut

Claims (5)

An upper support (10) connected to the upper side of the building;
A lower support 20 connected to a lower side of the building;
A central upper plate 31 having an upper end connected to the upper supporter 10 and a plurality of vertically elongated through holes 31b arranged in parallel to the lower supporter 10, And a central bottom panel (32) having a lower end connected to the lower support (20);
A left upper plate 41 installed on the left side of the central upper plate 31 and having an upper end connected to the upper supporter 10 and a lower end fixed to the lower side of the left upper plate 41, And a left lower panel 42 connected to the lower support 20 and formed with a plurality of vertically elongated through holes 42b.
The center top plate 31 and the left top plate 41 are connected to each other by a plurality of fastening bolts B which are installed on the right side of the central upper plate 31 and whose upper ends are connected to the upper support 10, A lower upper plate 51 and a lower upper plate 51. The lower upper plate 51 is spaced apart from the lower upper plate 51 by a predetermined distance and has a lower end connected to the lower support 20 and a longer vertical through- And a right panel 50 composed of a plurality of fastening bolts B penetrating right and left and composed of a central upper plate 31, a central lower plate 32 and a lower right plate 52 joined to the left lower plate 42 ),
The center panel 30, the left panel 40 and the right panel 50 are connected to the central, left and right top plates 31, 41 and 51 constituting each panel 30, 40 and 50, The heights of the center, left and right lower panels 32, 42 and 52 are different from each other and the height of the through holes 31b formed in the center panel 30 and the height of the left panel 40, The through holes 42b and 52b formed in the right panel 50 are disposed at different heights and the through holes 42b and 52b formed in the left panel 40 and the right panel 50 are positioned at the same height Wherein the damper is made of a steel material.
delete The method according to claim 1,
The distance between the center top plate 31 and the center bottom plate 32 and the distance between the left top plate 41 and the left bottom plate 42 and the distance between the right top plate 51 and the right bottom plate 52 Wherein the vibration damping device further comprises:
The method of claim 3,
The center upper plate 31 is longer than the central bottom plate 32 in the vertical direction and the left lower plate 42 is longer than the left upper plate 41 in the vertical direction, Wherein the lower plate (52) has a longer length in the vertical direction than the upper right plate (51).
The method of claim 4,
The left lower plate (42) is formed to have a longer length in the vertical direction than the central upper plate (31), and the vertical length is shorter than the right lower plate (52) .

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