KR20120035409A - Anti vibration device for construction - Google Patents

Abstract

PURPOSE: A vibration proofing device for a structure is provided to support vertical load and horizontal load applied to a structure from the outside with one device installed in the lower part of the structure. CONSTITUTION: A vibration proofing device for a structure includes a vertical vibration proofing part(10) and a horizontal vibration proofing part(20). The vertical vibration proofing part is installed to support vertical load which is vertically applied with respect to the structure. The vertical vibration proofing part comprises an upper plate(13), a lower plate(15), and an elastic body(11). The elastic body is installed between the upper and the lower plate. The horizontal vibration proofing part is arranged in the side part of the vertical vibration proofing part and installed to support vertical load which is horizontally applied with respect to the structure. The horizontal vibration proofing part includes stopper members(21) and shock absorbing members(23). The stopper members are installed in the side part of the elastic body. The shock absorbing members are installed between the elastic body and the stopper member.

Description

Anti vibration device for construction

The present invention relates to an anti-vibration device installed in a structure, and more particularly, is provided with a vertical, horizontal anti-vibration portion at the bottom of the structure to support both the vertical load and the horizontal load applied to the structure, as well as a simple structure It relates to a dustproof device for the structure can be made for the convenience of construction.

In general, the vibration source can be divided into two types, which are caused by all kinds of vibration such as traffic vibration, mechanical vibration, and strong wind, and earthquake caused by vibration.

These vibrations can be divided into vibration suppression and seismic isolation, which control vibrations according to the vibration source described above. Vibration damping is to reduce harmful vibrations, and seismic isolation is intended to support buildings from strong vibrations such as earthquakes, to suppress deformation of buildings due to earthquakes or to ensure building safety.

Here, vibration is required to avoid vibrations in order to increase workability or improve habitability by avoiding vibrations such as semiconductor fabrication, electron microscope, and art prints, which are subject to relatively short amplitude vibrations. In order to prevent the precision of the work from being lowered by external vibration during the operation by installing a dustproof device for each mechanical device, that is, a lower part of a semiconductor manufacturing facility, a lower part of an electron microscope, and the like.

 In recent years, vibration damping pads are installed in a building that is sensitive to external vibrations such as an opera house or a general residential structure to support both horizontal and vertical vibrations. Implement the dust-proof structure in order to impede the performance and reduce the discomfort or anxiety of the residents.

Such a vibration pad is installed on the mechanical device that generates the vibration to insulate the mechanical vibration, such as a structure directly installed in the building structure to implement a dustproof structure.

Such a conventional anti-vibration pad is installed separated into a horizontal anti-vibration pad and a vertical anti-vibration pad. In detail, the horizontal anti-vibration pad is installed horizontally with respect to the structure at the lower portion of the structure to support the vertical load applied to the structure, and the vertical anti-vibration. The pads are additionally installed on the side of the structure in parallel with the structure to support the horizontal load on the structure.

However, such a conventional dustproof pad has a problem that the installation is cumbersome and bulky as it is installed separately from the vertical and horizontal.

In addition, the anti-vibration pads can support the constant vibration, ie, non-vibration high frequency mechanical loads generated by subways, power plants, automobiles, and the like, and low frequency wind loads. As described above, there is a problem that it is difficult to support the load of the medium and low frequencies causing large vibration.

In detail, the anti-vibration pad has a problem in that it can be displaced from the installed structure when a large load is applied beyond the range, such as an earthquake, because the range in which displacement can be determined is determined.

In particular, the anti-vibration pads are not defined in the direction of displacement, but may be displaced in all directions, and since displacements are largely generated, the safety pads may have additional safety and buckling depending on the device support capacity limit even when the displacement of the rubber pads is restored. Problems may arise.

Accordingly, the present invention has been made to solve the conventional problems as described above, the present invention supports a vertical load applied to the structure from the outside as a device installed on the lower portion of the structure and also supports the horizontal load together It has a purpose to make it possible.

In addition, the present invention has an object to support the horizontal load by supporting the edge of the elastic body supporting the vertical load.

In addition, the present invention has an object to further support the portion that is most affected by the horizontal load.

In addition, the present invention has an object to detachably install the stopper member for supporting the horizontal load.

In addition, the present invention has an object to be able to distribute and support the vertical load and the horizontal load applied to the structure.

In addition, the present invention has an object to support not only vertical and horizontal loads applied to the structure but also earthquake loads.

As described above, the vibration isolator for a structure for achieving the object of the present invention is provided on the side of the vertical dust and the vertical dust is installed to support the vertical load applied to the structure perpendicular to the structure is applied horizontally to the structure Characterized in that it is made to support the structure from the vertical, horizontal load applied to the structure by a horizontal vibration isolator installed to support the vertical load.

The vertical dustproof part includes an elastic body provided between the upper plate, the lower plate, and the upper and lower plates, and the horizontal dustproof part is a stopper member provided at the side of the elastic body at an edge of the elastic body, and an impact relaxation provided between the elastic body and the stopper member. And a member is included.

The stopper member and the shock absorbing member may be further installed at edge portions of the elastic body.

The stopper member is removably installed.

The elastic body is characterized in that separated into a plurality of pieces installed.

A vertical dustproof part provided to support a vertical load applied vertically to the structure, a horizontal dustproof part provided on the side of the vertical dustproof part and installed to support a vertical load applied horizontally to the structure and on top of the vertical dustproof part It is characterized in that it is made to support the structure from the load applied to the structure by the seismic isolation unit is installed to support the earthquake load applied to the structure.

The seismic isolator is characterized in that the elastic support is installed between the vertical dust-proof part and the structure.

The seismic isolator is characterized in that the lead reinforcement elastic support provided between the vertical dust-proof part and the structure.

The seismic isolator is characterized in that the sliding plate provided between the vertical dust-proof part and the structure.

The seismic isolator is characterized in that it is installed below the vertical dustproof part.

Therefore, according to the present invention, a vertical dustproof part supporting the vertical load applied to the structure and a horizontal dustproof part supporting the horizontal load at the side of the vertical dustproof part are provided, so that both the vertical load and the horizontal load applied to the structure with one dustproof device. It can support, of course, its structure and volume are small and simple to install.

In addition, the present invention, while installing a shock-absorbing member between the dustproof part and the stopper member, while supporting the horizontal load, and further installed to the corner portion of the dustproof part, the portion which is most affected by the horizontal load more There is a supportable effect.

In addition, the present invention has an effect that the maintenance of the device is easy as the stopper member is detachably installed.

In addition, according to the present invention, since the elastic body is separated into a plurality of pieces and installed, the vertical load and the horizontal load applied to the structure are distributed and applied to the respective pieces of elastic material, and thus, it is possible to distribute and support them. It can be effective.

On the other hand, as the vertical, horizontal dustproof part and the base isolation part installed in the lower part of the structure are provided, the vertical and horizontal loads applied to the structure, that is, the constant load such as the vibration of the car or subway, and the wind load, as well as the large load such as earthquake It is made to support all the effects that can minimize the discomfort or anxiety of the residents living in the structure.

1 is a view showing an embodiment of a structure dustproof device according to the present invention.
Figure 2 is a plan view showing one embodiment of a structure vibration isolation device according to the present invention.
Figure 3 is a plan view showing another embodiment of the structure of the vibration isolator according to the present invention.
Figure 4 is a view showing an embodiment of the vibration isolator for structures having a seismic isolator according to the present invention.
5 is a view showing another embodiment of the structure of the vibration isolator having a seismic isolator according to the present invention.
Figure 6a, 6b is a view showing another embodiment of the structure of the vibration isolator having a seismic isolator according to the present invention.
Figure 7 is a view showing the seismic isolator is located in the lower portion of the vibration isolator in one embodiment of the structure of the vibration isolator having a seismic isolator according to the present invention.

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

1 is a view showing an embodiment of a structure dustproof device according to the present invention, Figure 2 is a plan view showing an embodiment of a structure dustproof device according to the present invention, Figure 3 is a structure according to the present invention It is a top view which shows another Example of the dustproof apparatus for.

As shown, the vibration isolator 1 for the structure is provided with a vertical dustproof part 10 installed to support a vertical load applied to the structure perpendicular to the structure, and is provided on the side of the vertical dustproof part 10 horizontally with respect to the structure It is made to support the structure from the vertical, horizontal load at the bottom of the structure by a horizontal dustproof portion 20 installed to support the applied horizontal load.

The vertical dustproof part 10 is composed of an elastic body 11 provided between the upper plate 13, the lower plate 15, and the upper and lower plates 13 and 15.

Here, the vertical dustproof part 10 is provided with a lower slab 17 in which a plurality of anchors (A) and stud bolts (S) are embedded therein when the concrete (C) is poured in the lower part of the lower plate (15). The lower plate 15 and the lower slab 17 are fixed by the lower plate fixing member 17a.

In addition, the upper slab 19 in contact with the lower surface of the structure is fixed to the upper surface of the upper plate 13 by the upper plate fixing member 19a.

The elastic body 11 may be formed of a rubber material having elastic force or a composite of laminated rubber and an iron plate, and may be a dustproof pad configured to support vibration generated from the outside of the structure in a vertical direction.

The horizontal dustproof part 20 includes a stopper member 21 provided at the side of the elastic body 11 at the edge of the elastic body 11 and an impact relaxation member 23 provided between the elastic body 11 and the stopper member 21. Is done.

In detail, the elastic body 11 is installed between the upper plate 13 and the lower plate 15, and the stopper member 21 is disposed at the edge of the lower plate 15 so as to be spaced apart from the side surface of the elastic body 11. This is seated and fixed by the stopper fixing member 21a.

Therefore, the stopper member 21 is detachable by the stopper fixing member 21a and is easily detached and fixed, thereby repairing the stopper member 21 repeatedly applied to the load and the shock absorbing member 23 to be described later. Maintenance work is easy.

In addition, the shock absorbing member 23 is installed between the elastic body 11 and the stopper member 21, that is, fixed to the stopper member 21 and in contact with the upper plate 13 positioned above the elastic body 11. At this time, the shock absorbing member 23 is formed of a rubber material having elasticity.

Accordingly, when the horizontal dustproof part 20 supports the vertical load in the elastic body 11, the horizontal load applied to the elastic body 13 is supported by the stopper member 21 supporting the side surface of the elastic body 11. At this time, the shock absorbing member 23 provided between the elastic body 11 and the stopper member 21 buffers the horizontal load applied to the stopper member 21 by the horizontal load.

That is, the vertical dustproof part 20 has the effect of double buffering the horizontal load by the stopper member 21 and the impact buffer member 23.

Here, referring to FIG. 2, since the horizontal load may be concentrated on the edge portion 12b, the horizontal dustproof portion 20, that is, the stopper member 21 and the impact buffer member 23 may be further installed on the edge portion 12b. Thus, it is preferable that the horizontal load concentrated on the edge portion 12b can be smoothly supported.

On the other hand, the elastic body 11a constituting the vertical dustproof part 10, as shown in Figure 3 as another embodiment of the present invention, may be installed separated into a plurality of pieces.

In detail, when the elastic body 11a is separated into a plurality, the vertical load and the horizontal load can be separately supported by each elastic body 11a installed separately, thereby increasing the supporting efficiency. In addition, the repeated fatigue of the elastic body 11a is also dispersed, so that the effect of increasing the life of the product is of course increased.

Accordingly, the vibration isolator 1 of the structure includes the stopper member 21 and the shock absorbing member 23 to support the horizontal load on the side of the vertical dustproof part 10 having the elastic body 11 supporting the vertical load. Since the horizontal vibration isolator 20 is installed in a simple configuration that can support both vertical and horizontal loads, vibrations generated in the vicinity of the structure, for example, there is an effect that can be vibration-resistant due to the collapse of the building from the subway operation. .

Figure 4 is a view showing an embodiment of a structure vibration isolation device having a base isolation according to the present invention, Figure 5 is a view showing another embodiment of the structure vibration isolation device having a base isolation according to the present invention.

Figure 6a, 6b is a view showing another embodiment of the structure of the vibration isolation device having a base isolation according to the present invention, Figure 7 is a vibration isolation unit in one embodiment of the structure vibration isolation device having an isolation base according to the present invention It is a figure showing the lower portion of the vibration isolator.

As shown, an embodiment of the structure dustproof device having a seismic isolation unit to support the seismic load on the upper part of the vertical dustproof part 10 'and the horizontal dustproof part 20' constituting the above-described dustproof device 1. The installed base isolation unit 30 is further installed to support the earthquake load as well as the vertical load and the horizontal load applied to the structure.

The vertical dustproof part 10 'and the horizontal dustproof part 20' have the same structure as described above, so that the lower plate 17 'and the lower plate 15' are embedded so that the anchor A is embedded when the concrete C is placed. ) Is fixed by the lower plate fixing member 17a ', and an elastic body 11' is installed on the upper surface of the lower plate 15 '. In addition, a stopper member 23 'and an impact releasing member 21' are provided on the side of the elastic body 11 '.

In addition, the stone intermediate plate fixing member for fixing the upper plate 13 'and the stone intermediate plate 19 is installed on the upper portion of the elastic body 11', that is, the upper plate 13 '. It is fixed by 19a, and the base isolation part 30 in which the base isolation lower plate 31a, the base isolation elastic body 35, and the top plate 31b are laminated | stacked sequentially is provided.

As shown in FIG. 4, the base isolation elastic body 35 may be an elastic pad having a large displacement elasticity, or as shown in FIG. 5, and the lead rods 37 are installed in the form of a core in the base isolation elastic body 35. It may be a reinforced basal elastic body 31.

Here, the elastic body 11 ′ disposed at the position of first contact with the vibration source applying the load to the structure is preferably formed larger than the basal elastic body 35 disposed above the elastic body 11 ′ to primarily support the load. In addition, if a load is first applied to the base elastic body 35, it is natural that the size of the base elastic body 35 is larger than that of the elastic body 11 '.

In addition, as shown in FIG. 6A, the base isolation elastic body includes a sliding base elastic body 38 having a sliding plate 38a provided between the upper plate 31b and the lower plate 31a, or an upper portion thereof, as shown in FIG. 6B. Between the plate 31b and the lower plate 31a becomes a bearing base elastic body 39 having a spherical bearing 39a installed therein so that the upper plate 31b slides.

Therefore, when an earthquake load is applied to the structure installed on the upper part of the upper plate 31b, the base elastic body 35 or the lead reinforced base elastic body 31 from one side to the other side generates displacement in the elastic pad having elasticity to damp the earthquake load. In addition, the sliding seismic isolator 38 or the bearing seismic isolator 39 is made to attenuate the earthquake load while moving from one side to the other by the sliding plate 38a or the rotating bearing 39a.

The seismic isolator 30 attenuates the earthquake load when an earthquake occurs to prevent the structure from being collapsed or damaged, and is restored to its original position after the earthquake ends, thereby preparing for an earthquake again.

Meanwhile, as shown in FIG. 7, the seismic isolation unit 30 is installed below the vertical vibration isolation unit 10 'and the horizontal vibration isolation unit 20' to perform an earthquake-proof function against an earthquake load. Of course.

Accordingly, the present invention prevents vibration generated in the periphery of the structure by the vertical dustproof part 10 and the horizontal dustproof part 20 from being transmitted to the structure, as well as the seismic force applied to the structure by the base isolation part 30. There is an effect that can be attenuated.

1: Dustproof device for structure with seismic isolation function
10: vertical dustproof part 11: elastic body
13: upper plate 15: lower plate
20: horizontal dustproof part 21: stopper member
23: shock absorbing member 30: seismic isolation unit

Claims (10)

A vertical dustproof part 10 installed to support a vertical load applied perpendicularly to the structure; and
It is provided to support the structure from the vertical, horizontal load applied to the structure by a horizontal dust-proof part 20 provided on the side of the vertical dust-proof part 10 is installed to support the vertical load applied to the structure horizontally Dustproof device for structure.
The method of claim 1,
The vertical dustproof part 10 includes an elastic body 11 installed between the upper plate 13 and the lower plate 15 and the upper and lower plates 13 and 15,
The horizontal dustproof part 20 includes a stopper member 21 provided at the side of the elastic body 11 at the edge of the elastic body 11 and an impact relaxation member provided between the elastic body 11 and the stopper member 21 ( 23) dustproof device for a structure comprising a.
The method of claim 2,
The stopper member (21) and the shock absorbing member (23) is characterized in that the structure is further provided for the edge portion of the elastic body (11).
The method of claim 3,
The stopper member (21) is a dustproof device for a structure, characterized in that detachably installed.
The method of claim 2,
The elastic body (11) is a dustproof device for a structure, characterized in that installed separated into a plurality of pieces.
A vertical dustproof part 10 'installed to support a vertical load applied perpendicularly to the structure; and
A horizontal dustproof part 20 'provided at a side of the vertical dustproof part 10' and installed to support a vertical load applied horizontally to the structure; And
Dust isolation for the structure, characterized in that made up to support the structure from the load applied to the structure by; Device.
The method of claim 6,
The seismic isolator (30) is a dustproof device for the structure, characterized in that the elastic support installed between the vertical dustproof part (10 ') and the structure.
The method of claim 6,
The seismic isolator (30) is a dustproof device for the structure, characterized in that the lead reinforcement elastic support installed between the vertical dust-proof part (10 ') and the structure.
The method of claim 6,
The seismic isolator (30) is a vibration isolation device for a structure, characterized in that the sliding plate is installed between the vertical dustproof part (10 ') and the structure.
The method according to any one of claims 6 to 9,
The seismic isolator (30) is a dustproof device for the structure, characterized in that installed below the vertical dustproof part (10 ').

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