KR20110140058A - Isolating table system - Google Patents

Abstract

PURPOSE: A seismic device is provided to enable easy adjustment on attenuation factor and cycle control and prevent various equipment from overturning in times of large scale earthquake. CONSTITUTION: A seismic device comprises a lower plate(100), a lower guide rail(110), an upper plate(200), an upper guide rail, and a support unit. The lower plate is formed on the floor of a structure or on the ground surface. The lower guide rail has a convex curvature toward the lower plate and is formed on the lower plate. The upper plate holds various equipment or instruments. The upper guide rail has a convex curvature toward the upper plate. The upper guide rail is formed under the upper plate perpendicularly to the lower guide rail. The support unit is formed between the lower and upper plates to be able to slide along the lower and upper guide rails.

Description

Isolation System {ISOLATING TABLE SYSTEM}

The present invention relates to an isolator, and more particularly, to an isolator that can protect a computer server, communication equipment, exhibition stand, vending machine, medical equipment, etc. during an earthquake.

Seismic design for earthquakes generally serves to prevent the structure of the structure from being destroyed in part or all of the earthquake and losing its function. However, even in the case of the earthquake-proof design, the structure will shake when an earthquake occurs, and expensive equipment or devices such as various computer servers, communication equipment, exhibition stands, vending machines, and medical equipment may cause damage due to conduction. .

In order to prevent such earthquake damage of various equipments, as shown in FIG.

The conventional seismic isolator, as shown in Figure 9, the upper member 21 for supporting a variety of equipment and the bearing portion 22 to isolate the vibration, the damping portion 23 to optimize the performance of the seismic isolation device, seismic isolation device It consists of a restoring force 24 for the restoration of the lower member 25 for installing the seismic isolator on the bottom or ground of the structure, the restoring force 24 also implements the intrinsic period that is the main performance of the seismic isolator.

One of the existing seismic isolators shown in FIG. 10 has a structure in which beads 32 are inserted between a pair of rails or curvature surfaces 31 having a curvature. In this case, the ball rolls from side to side to act as a bearing part to isolate the vibration by horizontally moving the upper and lower members, and the curvature rail or curvature surface acts as the restoring force part of the seismic isolator by gravity and at the same time according to the curvature. The natural period of the seismic isolator is determined.

Existing seismic isolator shown in FIG. 10 is effective in restoring and adjusting the original position by curvature, but when a large earthquake occurs, the upper member and the lower member are separated or separated so that the equipment is conducted and the damage may occur. There is this.

Another conventional seismic isolator shown in Figure 11 is a structure for inserting the bearing 42 and the spring member 43 is restrained up and down between a pair of linear rail or plane 41, the bearing is to the left and right It slides and horizontally moves the upper and lower members to act as a bearing part to isolate vibration. The spring member acts as a restoring force part of the seismic isolator by elastic force and determines the inherent period of the seismic isolator according to the spring stiffness. Done.

The existing seismic isolator shown in Figure 11 is constrained in the up and down direction, even if a large earthquake occurs, the upper member and the lower member is separated or separated to prevent the equipment from conducting the device, but is restored by a spring having a certain rigidity There is a drawback that the cycle of the base isolation device changes depending on the weight of the equipment or equipment loaded in the base isolation device.

In addition, the existing seismic isolator is not installed in most cases, because it is difficult to install a general damper (damper) because the movement stroke of the seismic isolator is relatively large, the operation direction is two-dimensional. When the damping part is not provided, in order to obtain the same base isolation performance, the movement stroke of the base isolation device is increased and the overall configuration of the base isolation device is enlarged, which restricts the installation space and makes it uneconomical.

Accordingly, the present invention was created to solve the above problems, the object of the present invention is to provide a variety of equipment independently installed inside or outside the building or structure, such as computer server, telecommunication equipment, exhibition stand, vending machine, medical equipment and the like; It is an object of the present invention to provide a seismic isolator that prevents damage from an earthquake, and to provide a seismic isolator that can easily adjust the attenuation rate and periodicity, and which does not conduct various equipment even when a large earthquake occurs.

In addition, the object of the present invention is to provide a seismic isolator that is easy to manufacture and economical with a simple configuration, and is easy to install and maintain.

The seismic isolator according to the embodiment of the present invention for achieving the above object has a lower plate provided on the floor or the ground of the structure, the lower guide rail is convexly curved in the lower plate direction and provided on the lower plate, various equipments or An upper plate on which the device is placed, an upper guide rail provided convexly in the direction of the upper plate and provided below the upper plate perpendicular to the lower guide rail, and slidably along the lower guide rail and the upper guide rail; It may include a support portion provided between the lower plate and the upper plate.

The support part may include a lower sliding part slidable to the lower guide rail, an upper sliding part slidable to the upper guide rail, and a coupling part for coupling the lower sliding part and the upper sliding part.

The lower sliding part may include a lower bearing in contact with the lower guide rail.

The lower bearing may be provided to surround the lower guide rail so as not to be separated from the lower guide rail.

The upper sliding part may include an upper bearing in contact with the upper guide rail.

The upper bearing may be provided to surround the upper guide rail so as not to be separated from the upper guide rail.

The coupling part may include a damping part that provides a damping force to the seismic isolator by vertical expansion and contraction of the coupling part when the upper plate moves.

The damping unit may be provided with at least one damping member selected from the group consisting of silicon, urethane, and high damping rubber.

The damping unit may be adjusted in the initial compression amount by a coupling bolt for coupling the upper sliding portion and the lower sliding portion.

The lower guide rail and the upper guide rail may be provided along a diagonal direction of the lower plate or the upper plate.

A gap adjusting part may be provided on the lower plate and the upper plate.

As described above, according to the seismic isolator according to an embodiment of the present invention, when an earthquake occurs for various equipment and devices that are independently installed inside or outside a building or structure, such as a computer server, a telecommunication equipment, an exhibition stand, a vending machine, a medical device, and the like. Damage can be prevented, especially the attenuation rate and period adjustment is easy, and even in the event of a large earthquake, various equipment may not be conducted.

In addition, it is easy to manufacture with a simple configuration, the overall size can be relatively reduced, installation convenience is expected.

Further, by adjusting the initial compression amount of the damping member, the damping force of the seismic isolator during operation can be easily adjusted.

1 is a perspective view of a seismic isolator according to an embodiment of the present invention.
2 is a plan view of a general state of a base isolation device according to an embodiment of the present invention.
3 is a plan view illustrating a state in which the base isolation device operates according to an embodiment of the present invention.
4 is a perspective view showing the support of the base isolation device according to an embodiment of the present invention.
5 is a front view of the support part of the base isolation device according to the embodiment of the present invention.
Figure 6 is a plan view of the support portion of the base isolation device according to an embodiment of the present invention.
7 is a view explaining the operation principle of the damping unit.
8 is a view showing a general isolation device.
9 is a view schematically showing the configuration of a general isolation device.
10 is a view for explaining the configuration and operation of a base isolation device according to the prior art.
11 is a view for explaining another configuration and operation of the base isolation device according to the prior art.

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

1 is a perspective view of a base isolation device according to an embodiment of the present invention, FIG. 2 is a plan view of a general state of a base isolation device according to an embodiment of the present invention, and FIG. 3 is an operating state of a base isolation device according to an embodiment of the present invention. It is a top view showing the.

1 to 3, the seismic isolation device according to the embodiment of the present invention is bent convexly toward the lower plate 100 and the lower plate 100 provided on the floor or the ground of the structure, that is, the lower plate 100. Bend convexly in the direction of the upper plate 200, the lower guide rail 110, the upper plate 200 on which various equipment or devices are placed, The upper guide rail 210 and the lower guide rail having a curvature in the direction of the upper plate 200 and provided below the upper plate 200 so as to intersect the lower guide rail 110 perpendicularly, that is, at right angles. A support portion 300 provided between the lower plate 100 and the upper plate 200 to be slidable along the 110 and the upper guide rail 210 is included. The.

Here, the lower guide rail 110 and the upper guide rail 210 has an earthquake due to the curvature R (see FIG. 5), and the seismic isolator is restored to its original position by gravity when the seismic device is operated. The natural period will be determined.

The lower guide rail 110 and the upper guide rail 210 may be provided along a diagonal direction of the lower plate 100 or the upper plate 200. Therefore, a larger working distance than the parallel guide rails may be secured through the diagonal arrangement of the lower guide rail 110 and the upper guide rail 210.

3 is a view showing the operation when vibration occurs in the horizontal direction in the base isolation device according to an embodiment of the present invention.

4, 5, and 6 are a perspective view, a front view, and a plan view respectively showing a supporting part of the base isolation device according to the embodiment of the present invention.

4 to 6, the support part 300 includes a lower sliding part 310 that is slidable to the lower guide rail 110, an upper sliding part 330 that is slidable to the upper guide rail 210, and It includes a coupling portion 350 for coupling the lower sliding portion 310 and the upper sliding portion 330.

The lower sliding part 310 includes a lower bearing 312 in contact with the lower guide rail 110.

The lower bearing 312 may be provided to surround the lower guide rail 110 so as not to be separated from the lower guide rail 110.

The upper sliding part 330 includes an upper bearing 332 in contact with the upper guide rail 210.

The upper bearing 332 may be provided to surround the upper guide rail 210 so as not to be separated from the upper guide rail 210.

Therefore, the device is connected to the lower plate 100, the lower guide rail 110, the support portion 300, the upper guide rail 210, the upper plate 200 in the vertical direction allows the operation in the horizontal direction, but the vertical direction Operation is constrained.

Here, the bearings 312 and 332 included in the sliding parts 310 and 330 may be used regardless of their types such as sliding bearings or rolling bearings.

The coupling part 350 may include a damping part 352 that provides a damping force to the device when the upper sliding part 330 or the lower sliding part 310 operates in a horizontal direction.

Referring to FIG. 8, the principle of the damping part 352 will be described. For example, when the lower sliding part 310 is operated horizontally, the damping part 352 is caused by the curvature of the lower guide rail 110. The top and bottom spacing of is reduced. That is, when the base isolation device is operated in the horizontal direction, the damping member is compressed by the vertical gap reduction of the damping unit 352. According to the amount of compression, the damping member generates a predetermined damping force to act as the damping force of the whole base isolation device. do. This principle is equally applied to the operation of the upper sliding part 330, so that even if the seismic isolator operates in any direction in the horizontal plane, appropriate damping force can be obtained. In addition, the damping force of the seismic isolator during operation can be easily adjusted by adjusting the initial compression amount of the damping member.

The damping unit 352 may be provided with at least one damping member selected from the group consisting of silicon, urethane, and high damping rubber.

6 and 7, the upper sliding part 330 and the lower sliding part 310 are coupled to and supported by one or more coupling bolts 354. Here, the coupling bolt 354 is used to fix the upper sliding portion 330 and the lower sliding portion 310 in the vertical direction and to adjust the initial compression amount of the damping portion 352.

In addition, the lower plate 100 and the upper plate 200 may be provided with a gap adjusting unit 370 that can adjust the size of the device according to the size of the various equipment installed in the device. It is possible to adjust the size of the lower plate 100 or the upper plate 200 in accordance with the size of the various equipment installed in the device through a simple replacement of the gap adjusting unit 370.

2 to 4, the operation of the base isolation device according to the embodiment of the present invention will be described.

In general, as shown in FIG. 2, the bearing part 300 is positioned at the center of each of the guide rails 110 and 210.

When an external force such as an earthquake occurs, the bottom or ground of the structure vibrates greatly in the horizontal direction, and the lower plate 100 operates in the horizontal direction. When the lower plate 100 operates horizontally, the lower guide rail 110 fixed to the lower plate 100 also moves horizontally. However, at this time, by the sliding function (isolating function) of the lower sliding part 310, the moving part 300 and the upper plate 200 and the various equipment loaded thereon hardly move.

As the lower plate 100 moves horizontally, the supporting part 300 rises on the curvature of the lower guide rail 110, and accordingly, gravity caused by the weight of various equipment is generated in the supporting part 300. do. Restoring force is generated to move to the center of the lower guide rail 110 by the gravity of the support portion 300 and the upper plate 200 and the various equipment, by the restoring force moves to the center of the guide rail, The movement speed, that is, the period of the base isolation device, can be adjusted by the curvature of the guide rail.

In this device, the curvature of the guide rail is very gentle to realize the long period (4 to 6 seconds), and this long period is much longer than the period of the earthquake load, which isolates most of the vibration caused by the earthquake.

That is, when the earthquake occurs, the lower plate 100 and the lower guide rail 110 provided on the floor or ground of the structure vibrate violently in the horizontal direction, but are loaded on the seismic isolation device by the sliding effect of the supporting part 300. The equipment moves very slowly from side to side so that no earthquake acceleration or damage occurs.

Meanwhile, when the earthquake occurs, attention is paid to the behavior of the support part 300, and a relative displacement occurs in the horizontal direction between the lower plate 100 and the upper plate 200, and accordingly, the support part 300 has the lower guide rail 110. Alternatively, the upper guide rail 210 moves along the upper and lower intervals of the damping part 352 due to the curvature of the guide rail. That is, when the base isolation device is operated in the horizontal direction, the damping member is compressed by the vertical gap reduction of the damping unit 352. According to the amount of compression, the damping member generates a predetermined damping force to act as the damping force of the whole base isolation device. do. This damping force can be easily and economically adjusted by adjusting the initial compression amount of the damping member or by replacing the damping member.

In addition, by arranging the lower guide rail 110 and the upper guide rail 210 in the diagonal direction of the lower plate 100 and the upper plate 200 surface, it is possible to greatly increase the operable distance of the seismic isolator in the event of an earthquake. .

As described above, the seismic isolator according to an embodiment of the present invention can prevent the occurrence of damage during the earthquake for various equipment and devices that are independently installed inside or outside the building or structure, such as a computer server, a medical device, In particular, the attenuation rate and period can be easily adjusted, and various equipment may not be conducted even in the event of a large earthquake.

In addition, it is easy to manufacture with a simple configuration, the overall size can be relatively reduced through the arrangement of the guide rail is expected installation convenience.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And all changes to the scope that are deemed to be valid.

100: lower plate 110: lower guide rail
200: upper plate 210: upper guide rail
300: support portion 310: lower sliding portion
312: lower bearing 330: upper sliding portion
332: upper bare work 350: coupling portion
352: damping section 354: coupling bolt
370: spacing adjuster

Claims (11)

A lower plate provided on the floor or ground of the structure;
A lower guide rail having a convex curvature in the lower plate direction and disposed above the lower plate;
An upper plate on which various equipment or devices are placed;
An upper guide rail having a convex curvature in the upper plate direction and provided below the upper plate perpendicular to the lower guide rail; And
A support part provided between the lower plate and the upper plate to be slidable along the lower guide rail and the upper guide rail;
Isolation device comprising a. In claim 1,
The winning part is
A lower sliding part slidable to the lower guide rail;
An upper sliding part slidable to the upper guide rail; And
A coupling part for coupling the lower sliding part and the upper sliding part;
A seismic isolator comprising a. In claim 2,
The lower sliding part
And a lower bearing in contact with the lower guide rail. 4. The method of claim 3,
The lower bearing
Isolation device characterized in that it is provided so as to surround the lower guide rail so as not to be separated from the lower guide rail. In claim 2,
The upper sliding part
And an upper bearing in contact with the upper guide rail. In claim 5,
The upper bearing
Isolation device characterized in that it is provided so as to surround the upper guide rail so as not to be separated from the upper guide rail. In claim 2,
The coupling portion
And an attenuator for providing a damping force to the base isolation device by vertical expansion and contraction of the coupling part when the upper plate or the lower plate moves. In claim 7,
The attenuation part
A seismic isolator characterized in that it is provided with at least one damping member selected from the group consisting of silicone, urethane, high damping rubber. In claim 7,
The attenuation part
Isolation device characterized in that the initial compression amount is adjusted by the coupling bolt coupling the upper sliding portion and the lower sliding portion. The method according to any one of claims 1 to 9,
The lower guide rail and the upper guide rail is seismic isolation apparatus, characterized in that provided along the diagonal direction of the lower plate or the upper plate. The method according to any one of claims 1 to 9,
Isolation device, characterized in that the lower plate and the upper plate is provided with a gap adjusting portion.

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