KR101971502B1 - Seismic isolation equipment - Google Patents

Abstract

The present invention provides seismic isolation equipment which comprises: an upper bracket supporting a seismic isolation object; a lower bracket formed in the shape corresponding to the upper bracket and arranged on a floor to face the upper bracket; and a plurality of first, second, and third vibration absorbing units arranged between the upper bracket and the lower bracket. The third vibration absorbing unit has a compression spring device.

Description

[0001] SEISMIC ISOLATION EQUIPMENT [0002]

The present invention relates to an isolation device and an isolation table including the same.

Since expensive computer equipment, communication equipment or precision measuring equipment are sensitive to temperature, it is necessary to maintain the temperature of the space where these equipment is installed at an appropriate temperature. For this purpose, a double floor is usually installed, And a duct connected to an air conditioner or the like is installed at the lower part of the floor to adjust the room temperature.

On the other hand, when an earthquake occurs, vibrations are transmitted vertically or horizontally to structures such as buildings or facilities. Vibration in the horizontal direction shakes the structure severely and twists. If the transmitted vibration is large, the structure is partially damaged to lower the stability of the structure, and in the worst case, the structure may be collapsed. Various seismic devices have been developed and used to protect structures and equipment by earthquakes.

Even if a double floor is installed, if vibration is applied from an earthquake, precision equipment can not avoid damage. In this case, it may lead to serious work paralysis. Therefore, even if an external force such as an earthquake Various devices have been developed to protect equipment installed on the upper floors.

1 is a view showing a conventional isolation device. Isolation devices for damping vibration can be applied to seismic double floors. In order to maximize the seismic vibration reduction function, the tension of the spring used for vibration absorption is very important. The conventional seismic isolation device has a problem that it is difficult to replace the spring according to the magnitude of the earthquake vibration by preliminarily manufacturing the spring with a predetermined length. The isolation device of FIG. 1 includes a rectangular upper bracket 10 and a lower bracket 20. The first vibration absorbing portion 40 and the second vibration absorbing portion 30 are disposed between the rectangular upper bracket 10 and the lower bracket 20. [ A diagonal frame connecting diagonal lines is formed inside the rectangular frame of the upper bracket 10 and the lower bracket 20 and a central square frame formed of vertexes facing the respective sides of the rectangular frame is formed at the center thereof. The first vibration absorbing portion 40 is disposed at each vertex of the rectangular frame and the second vibration absorbing portion 30 is disposed at each vertex of the central rectangular frame. The compression spring and the tension spring are applied to the first vibration absorbing part 40 and the tension spring is applied to the second vibration absorbing part 30. When the spring is connected to the upper bracket 10 and the lower bracket 20, Both end spring rings are fixed. Thus, when the spring is connected, it is fixed only in one direction, and when the upper bracket moves according to the vibration along the xyz axis, it receives a lot of stress and obstructs the tension function.

The spring of the first vibration absorbing part 30 and the second vibration absorbing part 40 can not adjust the tension of the spring so that the tension of the spring becomes larger than the initial setting value There is a problem of loosening, and even if the tension of the spring is loosened, there is a problem that it is difficult to change such as a new assembly is required to adjust it.

Korean Registered Patent No. 10-1178870 Korean Registered Patent No. 10-1314872 Korean Patent Registration No. 10-1595509

Disclosure of the Invention The present invention has been conceived to solve the problems of the above-described seismic isolation device, and it is an object of the present invention to provide a seismic isolation structure capable of adjusting a spring tension, The present invention has been made in view of the above problems.

It is another object of the present invention to provide a seismic isolation device capable of preventing vertical separation of the seismic isolation device even under vertical submarine earthquakes.

It is another object of the present invention to provide an seismic table provided with a seismic isolation device that further enhances the seismic isolation function.

According to an aspect of the present invention,

An upper bracket for supporting the object to be seated;

A lower bracket formed in a shape corresponding to the upper bracket and disposed on the floor so as to face the upper bracket; And

And a plurality of first vibration absorbing parts disposed between the upper bracket and the lower bracket,

Wherein the first vibration-

A first spring having spring rings at both ends thereof and being a tension spring,

A pin-shaped spring hanger passing through each of the spring rings;

A spring assembly cap formed with a bolt hole on an upper surface of a tubular body and formed with a spring hook insertion groove penetrating the side surface of the lower body for insertion and coupling of the spring hanger, And

And a spring tension adjusting bolt passing through an outer surface of the upper bracket and having a lower end fastened to the bolt fitting hole,

A spring tension adjusting bolt coupling groove to which the spring tension adjusting bolt of the upper bracket is coupled is formed and a bolt tap capable of screwing with the bolt groove of the spring tension adjusting bolt groove is formed on the inner circumferential surface of the spring tension adjusting bolt coupling groove, And a spring tension adjusting bolt penetrating through the upper bracket and being bolted to be vertically movable.

According to an embodiment of the present invention, there is provided an upper bracket comprising: a rectangular upper bracket supporting an object to be tested;

A lower bracket formed in a shape corresponding to the upper bracket and disposed on the floor so as to face the upper bracket; And

And a third vibration absorbing portion disposed at a position where the diagonal line of the rectangle meets between the upper bracket and the lower bracket,

The third vibration absorber may include a first LM rail disposed along one diagonal line of the diagonal line, a first LM block movably disposed along the first LM rail, a second LM rail disposed along the other diagonal line of the diagonal line, A second LM block movably disposed along the second LM rail, and a compression spring device disposed between the first LM block and the second LM block,

Wherein the compression spring device comprises a cylinder to be pushed downwardly and closed in a cylinder shape and having a plurality of air holes formed on the upper surface thereof, an upper opening and a lower closed cylinder shape, A mail cylinder formed to be inserted. And a compression spring disposed in a space between the mail cylinder and the e-mail cylinder, wherein the e-mail cylinder and the e-mail cylinder are coupled using rotation and vertical separating fastening bolts,

Wherein a spring seat portion is formed in the mail cylinder so as to accommodate a plurality of compression springs corresponding to the number of the compression springs and a compression spring guide protrusion Is formed to protrude downward at a position corresponding to the center of each of the spring inner teeth portions.

An anti-rotation bolt hole 732-2 is formed in the side surface of the cylinder 732 so as to penetrate through the side surface of the mail cylinder 732 in the vertical direction. The rotation preventing bolt groove 731-2 is formed in a shape corresponding to the position of the rotation preventing bolt hole 731-2 and inserted into the rotation preventing bolt hole 731-2 through the rotation preventing bolt hole 732-2, (780) are combined with each other.

The vertex angles of the bottom surface of the mail cylinder 731 are formed with cushion rubber seat portions protruding upward and the vertex angles of the upper surface of the cylinder 732 are downwardly projected to form a cushion rubber contact portion, Characterized in that a cushion rubber is disposed.

And the rotation and vertical separation preventing bolts are coupled through the compression spring guide protrusion.

According to the embodiment of the present invention configured as described above, the structure of the vibration absorbing part applied to the seismic isolation device can be improved, the tension of the spring can be adjusted, and the stress applied to the spring can be reduced.

It is another object of the present invention to provide a seismic isolation device capable of preventing vertical separation of the seismic isolation device even under vertical submarine earthquakes.

Further, according to the embodiment of the present invention, it is possible to provide a seismic table having an enhanced seismic function.

1 is a perspective view showing a conventional isolation device.
2 is an exploded perspective view of a first vibration absorbing portion of a seismic isolation device according to an embodiment of the present invention.
Figure 3 is a perspective view of Figure 2;
Fig. 4 is an enlarged view of the components of Fig. 2. Fig.
Figure 5 is an incision view of the upper frame of Figure 2;
6 is a view showing another embodiment of the spring coupling structure of the first vibration absorbing portion.
7 is an exploded perspective view of a second vibration absorbing portion of a seismic isolation device according to an embodiment of the present invention.
8 is an exploded perspective view of a second vibration absorbing part of a seismic isolation device according to another embodiment of the present invention.
9 is a view for explaining a process of assembling the second vibration absorbing portion of FIG.
10 is a perspective view showing a third vibration absorption unit of the seismic isolation device according to the embodiment of the present invention.
11 is an exploded perspective view of Fig.
FIG. 12 is a perspective view showing a third vibration absorbing unit according to another embodiment of the present invention, and FIG. 13 is an exploded perspective view thereof.
FIG. 14 is a perspective view showing a third vibration absorbing unit according to another embodiment of the present invention, and FIG. 15 is an exploded perspective view thereof.
16 is a view showing an isolation table provided with a seismic isolation device according to an embodiment of the present invention.

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

The isolation device according to the embodiment of the present invention includes an upper bracket 100 supporting an object to be seamed, a lower bracket 200 disposed on the floor, at least one first And includes a vibration absorbing portion 400, a second vibration absorbing portion 300, and / or a third vibration absorbing portion 700.

The upper bracket 100 and the lower bracket 200 are formed in corresponding shapes. The upper bracket 100 and the lower bracket 200 may be formed of a section having a square, right angle, cross, or ⊥ shape. The upper bracket 100 and the lower bracket 200 have a rectangular frame, a + -type frame connecting the vertexes of the rectangular frame, and a center square formed by the vertexes facing the sides of the rectangular frame at the center of the + Frame. The second vibration absorbing part 300 is disposed between the upper bracket 100 and the lower bracket 200 at positions corresponding to the respective vertexes of the rectangular frame and the first vibration absorbing part 400 is attached to each vertex of the central rectangular frame. . And the third vibration absorbing portion 400 is disposed between the central square frames. The upper surface of the upper bracket 100 and the lower surface of the lower bracket 200 are called the outer surface and the upper surface of the upper bracket 100 and the upper surface of the lower bracket 200 are called inner surfaces.

The structure of the upper bracket 100 and the lower bracket 200 to which the first vibration absorbing part 400 and the first vibration absorbing part 400 are coupled will be described with reference to FIGS. 2 is an exploded perspective view showing a first vibration absorbing part 400 and a part of upper and lower brackets 100 and 200 of a seismic isolation device according to an embodiment of the present invention, FIG. 3 is a perspective view of FIG. 2, 2 is an exploded view of the upper bracket 100 of FIG. 2, and FIG. 6 is a view showing another embodiment of the spring coupling structure of the first vibration absorbing part 400 .

2 to 4, the first vibration absorbing part 400 of the isolation device of the present invention includes a first spring 410 and a first spring 410. The first vibration absorbing part 400 includes a first spring 410, A spring tension adjusting bolt 430, a spring assembly cap 440, a spring hanger 451, and first and second snap rings 452 and 453. The bolt loosening prevention block 420 includes a bolt lock prevention block 420, a spring tension adjusting bolt 430,

The first spring 410 can be applied with a tension spring, and spring rings 411 are provided at both ends. The tension spring is a coil spring which receives an axial tension, and the tension spring is generally made in a circular cross section. A pin-shaped spring hanger 451 is fitted to the spring hooks 411 at both ends of the first spring 410. The spring hanger 451 is preferably formed to have a length corresponding to the diameter of the first spring 410. A second seat groove 451a is formed at both ends of the spring hanger 451 so that the second snap ring 453 can be inserted. The spring hanger 451 is fitted in the spring assembly cap 440. The spring assembly cap 440 has a bolt insertion hole 444 formed on the upper surface of the pipe-shaped body and a spring hanger 451 insertion groove 443 formed through the side surface of the lower body to face the side surface. An interference groove 442 is formed by being cut in the side lengthwise direction so that the spring ring 411 can pass through the pair of insertion grooves 443 facing each other at a 90 ° position. The spring tension adjusting bolt 430 is engaged with the bolt fitting hole 444. The spring tension adjusting bolt 430 is formed with a bolt head 431 and a bolt groove portion 432. A first seat groove 433 is formed in the lower end of the bolt groove portion 432 to allow the first snap ring 452 to be inserted . The bolt groove portion 432 of the spring tension adjusting bolt 430 is formed to have a corresponding diameter so as to fit into the bolt fitting hole 444 and the bolt fitting portion 432 is fitted into the bolt fitting hole 444, The first snap ring 452 is inserted and engaged. The spring assembly cap 440 is lifted and lowered according to the ascending and descending of the spring tension adjusting bolt 430 and the spring hook 411 is inserted into the spring hanger 451 according to the ascending and descending of the spring assembly cap 440, 1 spring 410 is pulled or loosened so that the tension of first spring 410 can be adjusted. The spring adjusting bolt 430 has a groove formed in the bolt head 431 and the protrusion 421 of the bolt release preventing block 420 having the protrusion 421 of the shape corresponding to the shape of the groove is engaged with the groove, (430) is prevented from being released. The protrusion 421 and the groove may be formed in a cross-pillar shape and corresponding grooves. The head of the bolt release prevention block 420 should be formed in a polygonal shape such as a square shape and is not rotated, thereby effectively preventing bolt loosening. The bolt loosening prevention block 420, the spring tension adjusting bolt 430, the spring adjusting cap 440 and the spring hanger 451 are coupled to both ends of the first spring 410 to connect the upper bracket 100 and the lower bracket 200 to the first spring 410.

The upper bracket 100 and the lower bracket 200 to which the first vibration absorbing unit 400 configured as described above is coupled are formed with a structure for coupling the first vibration absorbing unit 400. 3 and 5, the fastening structure of the upper bracket 100 to which the one end of the first spring 410 is coupled will be described. The lower bracket 200 to which the other end of the first spring 410 is coupled is formed in a structure corresponding to the upper bracket 100. As shown in FIG. 5, the bolt loosening prevention block 420 may be seated at the coupling position of the first vibration absorbing part 400, so that the polygonal bolt loosening prevention part 420 corresponding to the head of the bolt loosening prevention block 420 And a block seating groove 143 is formed on the outer surface of the upper bracket 100 by tapping. A bolt head groove 142 having a shape corresponding to the head of the spring tension adjusting bolt 430 is formed from the bottom face of the bolt unlocking block mounting groove 143 downwardly, Bolt tabs 144 are formed on the inner circumferential surface of the threaded portion so as to be screwed into the bolt groove portion 432 of the tension adjusting bolt 430. The bolt head groove 142 and the bolt tab 144 are formed on the outer surface of the upper bracket 100 and the lower bracket 200 in the inner surface direction and the upper bracket 100 and the lower bracket 100, When the thickness of the bracket 200 is thicker than the thickness of the bracket 200, a pipe-shaped protrusion 141 having a diameter larger than the long side of the bolt-unfastening block seating foam 143 protrudes from the bottom of the upper bracket 100 and the lower bracket 200 And a bolt head groove 142 and a bolt tap 144 may be formed inside the protrusion 141. [

6 is a view showing an example of a spring hanger 451 fastening structure according to another embodiment of the present invention. As shown in the figure, a seat groove 451a is formed at the lower end of the pin-shaped spring hanger 451 and the snap ring 453 is engaged with the spring hanger 451 as shown in FIG. 6 (a) ). According to another embodiment, a groove may be formed at the lower end of the spring hanger 451 and a U-shaped pin may be inserted into the groove to prevent the spring hanger 451 from being detached from the spring adjusting cap 440, as shown in FIG. 6 (b) have. 6 (c), a ball is provided at the lower end of the spring hanger 451 so as to be able to enter the spring hanger 451 by elasticity, so that the spring hanger 451 is inserted into the insertion hole of the spring adjusting cap 440 443, when the ball is inserted by pressing, it is not released when it is protruded by elasticity.

In the case of applying the first vibration absorbing unit according to the embodiment of the present invention having the above-described coupling structure, as shown by the dotted line in FIG. 2, unlike the conventional case, it is possible to move freely according to the direction of the force without stressing the spring in the z-axis direction.

7 is an exploded perspective view of a second vibration absorbing part 300 of a seismic isolation device according to an embodiment of the present invention. As shown in the figure, a second spring 310, which is a compression spring, and its coupling structure are added to the same tension spring coupling structure as the first vibration absorbing portion 400. That is, the third spring 330, which is a tension spring, is disposed at the coil center of the second spring 310, which is a compression spring. The structure for coupling the third spring 330 to the upper bracket 100 and the lower bracket 200 is the same as that of the embodiment shown in FIGS. 2 to 6, and thus a description thereof will be omitted.

The second spring 310 as a coil spring is coupled to both ends of the spring coupling block 320 and coupled to the inner surfaces of the upper and lower brackets 100 and 200 through the spring coupling block 320. The spring locking block 320 has a cylindrical second spring coupling hole having a diameter corresponding to the diameter of the second spring 310 formed in the plate-shaped metal block, a tab having the same shape as a screw groove is formed on the inner circumferential surface of the coupling hole, The end portion of the tab 310 can ride on the tab like a bolt and firmly engage. The tab has a depth and a diameter of the groove corresponding to the coil thickness of the second spring 310. The spring fastening block 320 is coupled to the inner surfaces of the upper bracket 100 and the lower bracket 200 using fastening devices such as bolts. When the upper bracket is connected to the upper bracket and the lower bracket using the spring coupling block 320 having the spring engagement tabs formed on the inner circumference thereof, when the upper bracket vibrates in x, y, z, So that the spring coupling block 320 can stably hold the movement of the spring coupling block 320.

8 and 9 are views showing the configuration of a second vibration absorber 300 of a seismic isolation device according to another embodiment of the present invention. 2 to 7, the bolt loosening prevention block receiving groove 143, the bolt head groove 142, and the bolt tab 144 are sequentially formed from the outer surface to the inner surface of the upper bracket 100 and the lower bracket 200 In the embodiment of FIGS. 8 and 9, a bolt-unlocking block receiving groove 143 is formed in the main body in which a plate-shaped block 351 and a pipe-shaped protruding portion 352 are protruded from the upper surface of the block, And a tension spring assembly block 350 having a shape corresponding to each of the head groove 142 and the bolt tab 144. The upper bracket 100 and the lower bracket 200 are provided on their outer surfaces with a plate- A through hole corresponding to the projection 352 is formed on the bottom surface of the seat groove 130 and the seat groove 130 of the corresponding shape so that the tension spring assembly block 350 is coupled to the seat groove 130 and the through hole.

9 is a view showing a coupling process. The block 351 of the tension spring assembly block 350 is seated in the seat groove 230 of the lower bracket 200 and engaged with the bolt 347. The spring tension adjusting bolt is coupled to the tension spring assembling block 350 and the bolt unlocking block is coupled to the groove of the spring tension adjusting bolt head. The spring spring is engaged with the spring assembly cap and the spring tension bolt is coupled to the bolt insertion hole of the spring assembly cap so that the third spring 330 ). Both ends of the second spring 310 are fitted to the bolt tabs on the inner circumferential surface of the spring fastening block 320 and the spring fastening block 320 is fastened to the center of the coil of the second spring 310 And a second spring coupled to both ends is disposed. The spring fastening block 320 is fastened to the inner surface of the lower bracket 200 by bolts. The spring 351 of the tension spring assembly block 350 is seated in the seat groove 130 of the upper bracket 100 and the spring hanger 451, the spring assembly cap 440, The spring tension adjusting bolt 430 and the bolt release preventing block 420 are coupled to the tension spring assembling block 350 so that the second spring 310 and the third spring 350 are inserted between the upper bracket 100 and the lower bracket 200. [ 330 is disposed on the second vibration absorbing portion 300.

10 is a perspective view showing a third vibration absorber 700 of the seismic isolation device according to the embodiment of the present invention, and Fig. 11 is an exploded perspective view of the third vibration absorber Fig. The third vibration absorbing part 700 is composed of a first linear bearing rail, a first rail block, a compression spring device 730, a second rail block, and a second linear bearing rail, And is disposed between the lower brackets 200. The first linear bearing rail and the second linear bearing rail are arranged vertically. The first linear bearing rail is implemented as an X-axis LM (Limer Motion) rail 710, the first rail block is implemented as an X-axis LM block 750, the second rail block is implemented as a Y- (760) and the second linear bearing rail is implemented as a Y-axis LM rail (720).

The X-axis LM rail 710 is disposed on the inner surface of one of the plus-shaped frames of the upper bracket 100 and the X-axis LM block 750 is movably coupled along the X-axis LM rail 710.

Axis LM rail 720 is disposed on the inner surface of the diagonal frame perpendicular to the X-axis LM rail 710 of the diagonal frame of the lower bracket 200 and the Y-axis LM block 760 is disposed on the Y- As shown in FIG.

A compression spring device 730 is disposed between the X-axis LM block 750 and the Y-axis LM block 760. The compression spring device 730 includes a mail cylinder 731, a mail cylinder 732, and a mold spring 733. [
10 and 11 show an embodiment in which the mail cylinder 731 is disposed on top and the mail cylinder 732 is disposed below and coupled to each other. As shown in Figs. 10 and 11, the e-mail cylinder 731 is formed in a cylinder shape whose opening is downward and closed upward, and a plurality of air holes are formed on the upper surface. The e-mail cylinder 732 has a larger diameter than the e-mail cylinder 731 so that the e-mail cylinder 731 is inserted through the opening in an upwardly open cylindrical shape and closed downward. A mold spring 733 is disposed in a space between the mail cylinder 731 and the cylinder 732. A plurality of air outlets are formed on the upper surface of the mail cylinder 731. After the mold springs 733 are disposed between the mail cylinder 731 and the female cylinder 732, do. The mold springs 733 are preferably compression springs having a capacity of 250 kg to 400 kg. E-mail cylinders, e-mail cylinders and mold springs are both used as metal materials and can be used semi-permanently. It is very strong against Z-axis high load or X-axis and Y-axis vibration stress, and has little influence on surrounding environment (heat, moisture, fire, etc.). Depending on the load of the target seismic isolation facility, various springs of various capacities are installed and have Z axis vibration damping effect and excellent restoring force of several mm to several tens mm.

The upper frame and the lower frame are separated from each other, but the upper and lower frames having the structure in which the first linear bearing and the second linear bearing are not separated naturally by the compression spring device 730 are not naturally separated.

FIG. 12 is a perspective view showing a third vibration absorbing unit according to another embodiment of the present invention, and FIG. 13 is an exploded perspective view thereof. 12 and 13 illustrate an embodiment in which the mail cylinder 731 is disposed below and the mail cylinder 732 is disposed above and bonded to each other. As shown in Figs. 10 to 13, the mail cylinder 731 and the mail cylinder 732 can be disposed upside down.
The embodiment will be described with reference to FIGS. 12 and 13. FIG. 12, the third vibration absorbing portion of Fig. 12 is disposed in the Y-axis LM block 760 in which the e-mail cylinder 731 is the lower portion and the X-axis LM block 750 in which the e-mail cylinder 732 is in the upper portion do. In the mail cylinder 731, a spring holding portion 731-1 is formed corresponding to the number of springs so that a plurality of springs can be placed. A compression spring guide protrusion 732-1 is inserted downward from a position corresponding to the center of each of the spring guide portions 731-1 so as to be inserted into the core of the spring 733 on the upper bottom surface of the female cylinder 732 Respectively. The rotation bolt can be fastened by passing through the compression spring guide protrusion 732-1.

The bottom corner vertices of the mail cylinder 731 are provided with a cushion rubber holding portion 731-3 protruding upward and an upper corner vertex of the cylinder 732 is projected downward to form a cushion rubber contacting portion, The cushion rubber 770 is disposed on the cushioning member 730 so that the cushioning action can be performed. The cushion rubber 770 can minimize the tilting phenomenon due to the load acting on the four corners of the female cylinder 732 and the female cylinder 731 under the condition of the horizontal plane of the X and Y axes have.

FIG. 14 is a perspective view showing a third vibration absorbing unit according to another embodiment of the present invention, and FIG. 15 is an exploded perspective view thereof. As shown in the figure, the cylinder 732 and the cylinder 131 are disposed in the X-axis LM block 750 and the Y-axis LM block 760, respectively. Prevention bolt groove 731-2 is formed in the side surface of the mail cylinder 731 in a shape corresponding to the position corresponding to the rotation prevention bolt hole 732-2, And the rotation preventing bolt 780 passing through the rotation preventing bolt hole 732-2 and inserted into the rotation preventing bolt groove 731-2 is engaged to connect the female cylinder 732 and the mail cylinder 731 can be prevented from being separated even when the magnitude of the vertical vibration is large. It is preferable that the rotation prevention bolt hole 732-2 and the rotation prevention bolt groove 731-2 are formed on opposite side surfaces of the e-mail cylinder 731 and the e-mail cylinder 730, respectively. The facility load and seismic vibration also prevent separation of the mail cylinder and the mail cylinder.

16 is a view showing an isolation table provided with a seismic isolation device according to an embodiment of the present invention.

One or more first vibration absorbing parts 400, second vibration absorbing parts 300 and / or third vibration absorbing parts 700 are disposed between the upper bracket 100 and the lower bracket 200 as described above A plurality of seismic isolation devices are connected to constitute an seismic isolation table. 12, the side walls of the upper bracket 100 or the lower bracket 200 are provided with coupling grooves for connection with the neighboring brackets, and each corner of the neighboring brackets is connected by the coupling frame 510 do. A cover plate 610 is coupled on a pair of connected isolation devices to complete a set of seismic tables. When the short side of the side of the isolation table is connected to the short side of the adjacent side of the isolation table by the connection frame 510, an isolation table capable of supporting one computer rack can be completed.

Claims (5)

An upper bracket having a rectangular shape for supporting the object to be measured;
A lower bracket formed in a shape corresponding to the upper bracket and disposed on the floor so as to face the upper bracket; And
And a third vibration absorbing portion disposed at a position where the diagonal line of the rectangle meets between the upper bracket and the lower bracket,
The third vibration absorbing portion may include a first linear bearing rail disposed along one diagonal line of the diagonal line, a first rail block movably disposed along the first linear bearing rail, a second rail block disposed along the second diagonal line of the diagonal line, A second rail block movably disposed along the second linear bearing rail, and a compression spring device disposed between the first rail block and the second rail block,
Wherein the compression spring device comprises a cylinder to be pushed downwardly and closed in a cylinder shape and having a plurality of air holes formed on the upper surface thereof, an upper opening and a lower closed cylinder shape, A mail cylinder formed to be inserted. And a spring disposed in a space between the mail cylinder and the e-mail cylinder, wherein the e-mail cylinder and the e-mail cylinder are coupled using rotation and vertical separating fastening bolts,
Wherein a spring seat portion is formed in the mail cylinder so as to accommodate a plurality of compression springs corresponding to the number of the compression springs and a compression spring guide protrusion Is protruded downward at a position corresponding to the center of each of the spring inner teeth portions,
Wherein each of the bottom corner vertexes of the mail cylinder is formed with a cushion rubber seat portion protruding upward and an upper corner vertex of the cylinder is projected downward to form a cushion rubber contact portion and a cushion rubber is disposed on the cushion rubber seat portion Characterized by an isolation device. The method according to claim 1,
The anti-rotation bolt groove is formed in the side surface of the mail cylinder in a shape corresponding to the position corresponding to the anti-rotation bolt hole, And an anti-rotation bolt inserted through the bolt hole and inserted into the anti-rotation bolt groove. delete The method according to claim 1,
Wherein the rotation and vertical separation preventing bolts are coupled through the compression spring guide projections. The method according to claim 1,
Wherein the upper bracket is formed in a rectangular shape, a coupling groove is formed at a half position of each side of a quadrangle, and an upper bracket connection frame is coupled to the coupling groove and connected to the adjacent upper bracket.

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