KR101971504B1 - 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 of corresponding to the upper bracket, and arranged on a floor to face the upper bracket; and a plurality of first and second vibration absorbing units arranged between the upper bracket and the lower bracket. The first vibration absorbing unit uses a ball transfer assembly.

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. When the spring is connected to the upper bracket 10 and the lower bracket 20, the first vibration absorbing part 40 is applied with a tension spring. 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 40 and the second vibration absorbing part 30 can not adjust the tension of the spring and the tension of the spring is changed from 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.

In addition, the upper bracket 10 and the lower bracket 20 may include a linear vibration absorbing portion composed of an LM rail and an LM block in a xy direction on a diagonal frame connecting diagonal lines inside the rectangular frame. Since the linear vibration absorber can only reciprocate in the x- or y-axis direction, the LM rail must be installed in the x-axis and the y-axis so as to cross each other. Since at least two sets of the LM block and the LM rail must be included, the manufacturing cost of the isolation device is increased. The linear vibration absorber composed of the LM rail and the LM block has a problem in that the quality of the isolation device is largely deteriorated due to a large frictional force in the reciprocating movement in the x axis and the y axis due to poor assembly if there is a slight error in component alignment during assembly have. In addition, there is a limit on the size of the linear vibration absorbing portion required to have the displacement width required for attenuating the vibration of the weight that can be supported by the seismic table.

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 isolator, and it is possible to manufacture the isolator of the ball transfer structure by a simple structure and a low cost, to prevent deterioration in quality due to alignment tolerance And an object of the present invention is to provide an isolation device capable of miniaturization.

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 supporting the seismic isolation device;

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 at least one first vibration absorbing portion disposed between the upper bracket and the lower bracket,

Wherein the first vibration-

A bracket fixing block coupled to an inner surface of the upper bracket or the lower bracket, a vibration reducing material coupled to the bracket fixing block, the ball transfer fixing block engaging with the vibration reducing material, And a ball transfer moving limit block coupled to the inner surface of the other bracket, not the bracket to which the bracket fixing block is coupled.

Wherein the ball transfer comprises a rolling ball, a housing for receiving the rolling ball, and an exposure slot formed at one end of the housing to expose a portion of the rolling ball, wherein the ball transfer fixing block and the vibration- Wherein a through hole having a diameter corresponding to the outer diameter is formed, and the ball transfer is inserted through the hole through the through hole.

Wherein the bracket fixing block, the vibration reducing material, and the ball transfer fixing block are formed in a plate shape corresponding to each other and are coupled to each other one after another, and the ball transfer moving limit block is engaged with the bracket fixing block, The ball transfer fixing block being formed in a circular or rectangular frame shape spaced apart from the ball transfer fixing block by a predetermined distance around the ball transfer fixing block.

Wherein the ball transfer fixing block and the vibration reduction material are formed with the number corresponding to the number of the ball transfers, respectively.

Wherein a reinforcing compression spring having a diameter corresponding to a diameter of the through hole, one end of which is disposed at an end of the housing inserted into the through hole, is inserted into the through hole.

A plurality of second vibration absorbing portions are additionally disposed between the upper bracket and the lower bracket,

The second vibration-

A first spring which is a compression spring, and

And a spring locking block engaging with both ends of the first spring,

Wherein the spring fastening block has a cylindrical first spring coupling hole having a diameter corresponding to the diameter of the first spring formed on the plate-shaped metal block, a thread groove is formed on the inner circumferential surface of the fastening hole, So as to engage with each other.

Wherein the upper bracket and the lower bracket are formed in a quadrangular shape and the second vibration absorbing portions are respectively disposed at apexes of the quadrangle.

A second spring disposed coaxially with the first spring of the second vibration absorbing portion and having spring rings formed at both ends thereof;

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, Wherein the spring tension adjusting bolt is bolted through the upper bracket so as to be movable up and down.

Wherein the first vibration absorbing portion is disposed in a central region of the upper bracket and the lower bracket and a plurality of second vibration absorbing portions are disposed in other regions between the upper bracket and the lower bracket,

Wherein the first vibration-

A third spring having a spring ring 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,

A spring tension adjusting bolt penetrating through an outer surface of the upper bracket and having a lower end fastened to the bolt fitting hole and a groove formed in the head;

A bolt loosening prevention block formed of a polygonal head and a protrusion corresponding to the shape of the protrusion, the protrusion being engaged with the protrusion to prevent the release of the spring tension adjusting bolt; And

A polygonal bolt loosening prevention member corresponding to the head of the bolt loosening block so that the bolt loosening prevention block can be seated from the upper surface of the block to the protruding side in a main body in which a plate-shaped block and a pipe- A bolt head groove having a shape corresponding to that of the head of the spring tension adjusting bolt is formed from the bottom face of the bolt release preventing block mounting groove to the bottom of the bolt head fitting groove, And a tension spring assembly block having bolt tabs formed on the inner circumferential surface thereof so as to be screwed with the bolt groove portion.

According to another embodiment of the present invention,

Wherein the upper bracket is formed with a guide block for guiding the vertex of the facility to be spliced at a position corresponding to each vertex of the equipment to be spliced,

Wherein the lower bracket is fixed to the floor, and a reinforcing frame is coupled to both sides.

According to another embodiment of the present invention,

Wherein the vibration reduction material is coupled to the vibration reduction material using the second fastening bolt and the vibration isolation material is coupled using the first fastening bolt and the ball transfer fixing block is coupled to the vibration reduction material using the second fastening bolt,

A plurality of second through holes are formed along a periphery of the first through hole of the vibration reduction material, a second fastening bolt is inserted into the upper end of the second through hole through the upper bracket, Wherein a second fastening bolt is inserted through the ball transfer fixing block, and an elastic body is connected between the first fastening bolt and the second fastening bolt to absorb an impact.

A lower spring housing having a cylindrical shell shape in which the upper spring housing is inserted into the lower end of the upper spring housing and reciprocates in a vertical direction, and a lower spring housing inserted into a space defined by the upper spring housing and the lower spring housing, And a pre-compression spring for imparting elasticity to the base member.

According to another embodiment of the present invention,

Wherein the upper bracket is formed in a rectangular shape, a coupling groove is formed at a half of each side of a quadrangle, and an upper bracket connecting frame is coupled to the coupling groove and connected to the adjacent upper bracket. do.

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.

In addition, according to the embodiment of the present invention, it is possible to provide a seismic isolation device capable of being manufactured with a simple structure and a small cost by preventing the deterioration of quality due to alignment tolerance by applying a seismic isolation device of a ball transfer structure can do.

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 a perspective view of an isolation device according to an embodiment of the present invention.
FIG. 3 is an exploded perspective view of FIG. 2. FIG.
FIG. 4 is a view showing a ball transfer assembly among the components of FIG. 2. FIG.
FIG. 5 is a view showing a first vibration absorbing unit of the components of FIG. 2. FIG.
6 is a view showing a first vibration absorber according to another embodiment of the present invention.
7 is a view illustrating a second vibration absorber according to another embodiment of the present invention.
FIG. 8 is a state diagram illustrating the isolation device according to another embodiment of the present invention. FIG.
9 is an exploded perspective view showing the isolator shown in Fig.
10 is a perspective view showing a seismic isolation apparatus according to another embodiment of the present invention.
11 is a top view showing an isolation device according to another embodiment of the present invention.
12 is a front view of the seismic isolation device of Fig.
13 is a front view showing the first vibration absorbing portion of Fig.
14 is a front view showing a spring cushion of a fastening bolt additionally included in the first vibration absorbing portion of FIG.
15 is an exploded perspective view according to another 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.

FIG. 2 is a perspective view showing an isolation device according to an embodiment of the present invention, and FIG. 3 is an exploded perspective view of FIG. As shown, an isolation device according to an embodiment of the present invention includes an upper bracket 100 supporting an object to be surveyed, a lower bracket 200 disposed on the floor, an upper bracket 100 and a lower bracket 200 And at least one first vibration absorbing part 300 and a second vibration absorbing part 400,

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 may be formed in a rectangular frame shape. As shown in FIG. 2, the upper bracket 100 and the lower bracket 200 form a top surface, which connects the vertexes of the rectangular frame, and a vertex pointed to each side of the rectangular frame at the center of the + And a central square frame formed of a rectangular frame. The second vibration absorbing part 400 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 300 is provided at each vertex of the central rectangular frame. Can be disposed. The positions and the number of the first vibration absorbing part 300 and the second vibration absorbing part 400 can be changed according to the equipment to be segregated. 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.

3 to 5, the first vibration absorber 300 of the seismic isolation device according to the first embodiment of the present invention will be described. As shown in the figure, the first vibration absorbing part 300 includes an upper bracket fixing block 310, a z-axis vibration reducing material 320, a ball transfer fixing block 330, a ball transfer 340 And a ball transfer movement limit block 350.

The ball transfer 340 may be top-down, top-down, or terrestrial, in which top-down is used in the embodiment of FIG. The top-down ball transfer 340 includes a housing 344 having an exposed slot 342 at the bottom thereof and a space portion having a larger diameter than the exposure slot 342 is formed inside the housing 344, A ball 341 is received and one end of the rolling ball protrudes outwardly through the exposure slot to provide a rolling surface. In the embodiment of FIG. 3, the rolling ball contacts the inner surface of the lower bracket 200 to form a rolling surface. It is preferable that the limit block 350 is coupled so as to limit the rolling of the ball transfer 340 around the ball transfer on the inner surface of the lower bracket 200. The limit block 350 is preferably formed in a circular frame shape. The ball transfer 340 is preferably formed with a flange 343 having a diameter larger than the housing body on the outside of the housing. The ball transfer 340 is bolted to the ball transfer fixing block 330. The ball transfer fixing block 330 is formed in a plate shape having a through hole of a corresponding diameter and a groove having a shape corresponding to the flange 343 so as to accommodate the housing 344 of the ball transfer 340. The ball transfer fixing block 330 is coupled to the vibration reduction material 320 by a bolt. The vibration reduction material 320 may be made of polymer, rubber, silicone, or synthetic resin depending on the equipment to be subjected to seismic isolation. The vibration reducing material 320 is formed to have a height suitable for vibration reduction and a through hole having a shape corresponding to the through hole of the ball transfer fixing block 330 is formed and the body of the ball transfer 340 is inserted. The vibration reducing material 320 may be coupled to the upper bracket fixing block 310 by a bolt together with the ball transfer fixing block 330. The upper bracket fixing block 310 may be coupled to the bottom surface of the upper bracket 100. The vibration reducing material 320 is inserted between the upper bracket fixing block 310 and the ball transfer fixing block 330 and is fastened to the upper bracket fixing block 310 by bolts at the lower end of the ball transfer fixing block 330, .

3 illustrates the application of the bottom-up type ball transfer 340. When a bottom-up type ball transfer is applied, the bracket fixing block is engaged with the upper surface of the lower bracket 200, The ball transfer fixing block is coupled to the vacuum reduction material, the ball transfer fixing block is coupled to the bottom-up ball transfer, and the ball transfer limiting block is coupled to the bottom of the upper bracket 100. [ When the earth type ball transfer is applied, slots are formed at both the upper and lower ends of the housing to expose the rolling balls to the upper and lower ends. Therefore, the height of the vibration reducing material is set to expose the rolling balls, All the limit blocks are combined.

In the above description, a plurality of the ball transfers 340 can be coupled according to the load and the center of gravity of the facilities to be seamed, and the ball transfer fixing block 330, the vibration reduction material 320 Is determined. In the embodiment of FIG. 3, the first vibration absorber 300 including the four ball transfers 340 has been described, but the numbers of the ball transfers may be smaller or larger.

FIG. 6 is a view showing a first vibration absorber 300 'of a seismic isolation device according to another embodiment of the present invention. In the embodiment of FIG. 6, in the embodiment of FIGS. 3 to 5, a reinforcing compression spring 360 for reducing the z-axis vibration is additionally disposed at the end of the housing on the side where the exposure slot of the ball transfer 300 is not formed . The reinforcing compression spring 360 is inserted into the through holes of the ball transfer fixing block 330 and the vibration reducing material 320 and is compressed between the bottom of the bracket fixing block 310 and the housing end of the ball transfer 300, It is possible to minimize the lateral shake of the vibration reinforcement formed of a material having a weaker elasticity than the elasticity of the reinforcing compression spring 360 such as rubber or silicone and maximize the z-axis vibration reduction effect. In the first vibration absorption portion 300 ' Regardless of the roughness or slope of the earthquake.

Meanwhile, one or more second vibration absorbing parts 400 may be disposed between the upper bracket 100 and the lower bracket 200 according to an embodiment of the present invention. 7 is an exploded perspective view showing a second vibration absorber 300 of the seismic isolation device according to the embodiment of the present invention. The second vibration absorbing part 300 includes a second spring 430 and a bolt loosening prevention block 441 and a spring tension adjusting bolt 442 for coupling the second spring 430 to the upper and lower brackets 100 and 200, A spring assembly cap 444, a spring hook 445, and a snap ring 446.

The second spring 430 can be applied with a tension spring, and spring rings 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 445 is fitted to spring rings at both ends of the second spring 430. The spring hanger 445 is preferably formed to have a length corresponding to the diameter of the second spring 410. At both ends of the spring hanger 445, a snap ring 446 is fitted, and the spring hanger 445 is fitted in the spring assembly cap 444. The spring assembly cap 444 has a bolt hole formed on the upper surface of the pipe-shaped body, and the spring hook 445 is inserted through the side surface of the lower body to face the side surface. An interference groove is formed by cutting in the lateral length direction so that the spring ring can pass through the pair of opposing insertion grooves at 90 degrees. The spring tension adjusting bolt 442 is engaged with the bolt fitting hole of the spring assembly cap 444. The spring tension adjusting bolt 442 passes through the upper and lower brackets 100 and 200 and is engaged with the bolt fitting hole of the spring assembly cap 444. [ The tension of the second spring 430 can be adjusted outside the brackets 100 and 200 through the rotation of the spring tension adjusting bolt 442. That is, the spring assembly cap 444 is lifted and lowered according to the ascending and descending of the spring tension adjusting bolt 442 and the spring hook is fitted to the spring hanger 445 according to the ascending and descending of the spring assembly cap 444, 430 may be pulled or loosened so that the tension of the second spring 430 can be adjusted. The spring tension adjusting bolt 442 has a groove formed in the head of the bolt and a protrusion of the bolt loosening prevention block 441 having a shape corresponding to the shape of the groove is engaged with the groove to prevent the bolt 442 from being loosened do. The projecting portion and the groove portion may be formed into a cross-pillar shape and corresponding grooves. The head of the bolt release preventing block 441 should be formed in a polygonal shape such as a square or the like so that it is not rotated so that the bolt loosening can be effectively prevented. The bolt loosening prevention block 441, the spring tension adjusting bolt 442, the spring adjusting cap 444 and the spring hanger 445 are coupled to both ends of the second spring 430 to connect the upper bracket 100 and the lower bracket 200 to the second spring 430.

The second vibration absorbing part 400 is provided with a first spring 410 as a compression spring and a coupling structure thereof in the tension spring coupling structure. That is, the second spring 430, which is a tension spring, is disposed at the center of the coil of the first spring 310 as the compression spring. The first spring 410 as a coil spring is coupled to both ends of the spring fastening block 420 and coupled to the inner surfaces of the upper bracket 100 and the lower bracket 200 through the spring fastening block 420. The spring locking block 420 has a cylindrical first spring coupling hole having a diameter corresponding to the diameter of the first spring 410 formed in the plate-shaped metal block, a tab having the same shape as a screw groove is formed on the inner peripheral surface of the coupling hole, So that the end of the tab 410 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 first spring 410. The spring coupling block 420 is coupled to the inner surface of the upper bracket 100 and the lower bracket 200 using a fastening device such as a bolt. When the upper bracket is connected to the upper bracket and the lower bracket by using the spring fastening block 420 formed with the spring engagement tabs on the inner periphery, when the upper bracket vibrates in x, y, z, The spring coupling block 420 stably holds the movement of the spring coupling block 420.

The vibration isolator according to the embodiment of the present invention includes a first vibration absorbing part 300 including a ball transfer assembly and a second vibration absorbing part 400 including a tension spring and a coil spring assembly together with an upper bracket 100 and the lower bracket 200 so that they can move 360 degrees instead of the unidirectional directions of the x and y axes and the z-axis vibration is reinforced by the second vibration absorbing portion 400 and the reinforcing compression spring 360, , y, and z axes.

In the meantime, when the upper and lower brackets 100 and 200 are formed with through holes and bolt fixing taps and the upper and lower bracket fixing bolts are used, It is possible to prevent the deterioration of the product quality due to the self-weight reaching the elasticity and tensile limit point, and to provide convenience when moving the product.

Meanwhile, the isolation devices according to the embodiments of FIGS. 2 to 7 may be combined in a modular fashion to form an isolation table for large installations. However, in the case of modular combination, there is a problem that a cost is increased due to redundant components. 8 and 9 show a large facility-integrated seismic table to which the first vibration-absorbing portion 300 and the second vibration-absorbing portion 400, which are constructed as described above, are applied.

In Fig. 8, reference numeral 1000 denotes a facility to be subjected to isolation. 2000 represents the seismic table. The vibration isolating table 2000 includes an upper cover 2100, a lower cover 2200, at least one first vibration absorbing portion 2300 disposed between the upper cover and the lower cover, at least one second vibration absorbing portion 2400, Frame 2500. FIG.

The upper cover 2100 is a table on which the equipment 1000 to be seated is placed and in which a guide block 2110 for guiding the position of each corner of the seismic isolation system 1000 corresponds to each corner of the seismic isolation facility 100 . The guide block 2110 can be fixed to the facility 1000. The lower cover 2200 is formed in a shape corresponding to the upper cover 2100 with a floor fixing panel fixed to the floor, and is fixed to the floor. The lower cover 2200 can be additionally supported by the reinforcing frame 2500. [ The reinforcing frame 2500 may be a square pipe. At least one first vibration absorbing portion 2300 and a second vibration absorbing portion 2400 are disposed between the upper cover 2100 and the lower cover 2200. [ The number of first vibration absorbing parts 2300 and the number of ball transfer assemblies applied to the first vibration absorbing part 2300 can be adjusted according to the seismic isolation equipment. In the embodiment of FIG. 9, the first vibration absorber 2300 to which one ball transfer 2340 is applied is illustrated, however, at least one ball transfer 2340 may be applied. A plurality of second vibration absorbing parts 2400 including compression and tension spring assemblies may be installed depending on the weight of the equipment 1000 to be segregated. The limit block 2350 may be disposed around the entire lower cover 2200 and the first vibration absorbing portion 2300 may be disposed inside the limit block 235. Although not shown, 2300, circular or rectangular circular limit blocks may be arranged.

Since the upper and lower covers can be manufactured simply by bending the steel plate, the manufacturing cost can be reduced. The manufacturing cost can be reduced by minimizing the use of the ball transfer. The amount of use of the second vibration absorbing part can be optimized according to the weight of the installation subject to be seaweed, and the manufacturing cost can be reduced. Since the outer periphery of a general isolation unit is formed in a predetermined size, there is a problem that it is difficult to apply the space narrowly in a structure in which the size of a facility subject to seismic isolation is small or a large number of wires and communication lines are omitted from the lower portion of the facility. However, The seismic table has the advantage of being customizable regardless of the size and application space of the equipment subject to seismic isolation.

10 is a perspective view illustrating a seismic isolation apparatus according to another embodiment of the present invention. 10, a wire 600 may be additionally coupled to one side of the upper bracket 100 and the lower bracket 200 to be further fixed. The upper and lower brackets 100 and 200 are each provided with a bolt fixing tapped hole and the upper bracket 100 detachment prevention wire 600 is fastened to the outer surfaces of the upper and lower brackets 100 and 200 with fixing bolts using bolt fixing taps, The limit block 350 may block the phenomenon that the ball transfer and the upper bracket 100 are separated from each other and the secondary wire 600 may block the vibration.

11 to 14 show an isolation table according to another embodiment of the present invention. FIG. 11 is a top view showing an isolation table according to another embodiment of the present invention, and FIG. 12 is a front view of the isolation table of FIG. As shown, at least one first vibration absorbing portion 2300 and at least one second vibration absorbing portion 2400 are disposed between the upper cover 2100 and the lower cover 2200. The structures of the first vibration absorbing portion 2300 and the second vibration absorbing portion 2400 are the same as those of the first vibration absorbing portion 300 and the second vibration absorbing portion 2300 applied to the seismometer or the seismic table of the embodiment disclosed in Figs. (400, 2400).

The vibration reducing material 2320 of the first vibration absorbing part 2300 is joined to the upper cover 2100 by using the first fastening bolt 2374 and the ball transfer fixing block 2330 is fixed to the vibration reducing material A plurality of second through holes 2322 are formed around the first through holes 2321 of the vibration reducing material 2320 while the second through holes 2322 are coupled using the second through bolts 2375, A second fastening bolt 2375 is inserted through the upper bracket and a second fastening bolt 2375 is inserted through the ball transfer fastening block 2330 at the lower end of the second through hole 2322, And an elastic body 2370, that is, a fastening bolt spring cushion is connected between the first fastening bolt and the second fastening bolt to absorb the impact.

11 to 14, the structure of the fastening bolt spring cushion 2370 is added to the first vibration absorbing portion 2300. [ Fig. 13 is an enlarged view of the first vibration absorbing portion 2300, and Fig. 14 is an enlarged view of the fastening bolt spring cushion 2370. Fig. Fig. 13 is a front view showing the first vibration absorbing portion 2300 of Fig. 11, and Fig. 14 is a front view showing a spring cushion further included in the first vibration absorbing portion 2300 of Fig. As shown, the first vibration absorbing portion 2300 includes a ball transfer 2340, a vibration reducing material 2320, a ball transfer fixing block 2330, a reinforcing compression spring 2360 for reducing z-axis vibration, And a bolt spring cushion 2370. A vibration reduction material 2320 is disposed between the upper cover 2100 and the ball transfer 2340. The vibration reduction material 2320 has a first through hole in the central region and a ball transfer 2340 in the first through hole. And a reinforcing compression spring 2360 for reducing vibration of the z-axis is disposed between the upper end of the housing body and the upper cover 2100. A plurality of second through holes are formed around the body of the vibration reduction material 2320, and a spring cushion 2370 is disposed in the second through hole. The spring cushion 2370 has an upper spring housing 2371 and a lower spring housing 2372 having different diameters in the shape of a cylindrical shell as shown in Fig. 14. The lower portion of the upper spring housing 2371 is connected to the lower spring housing 2372 ), Or vice versa, to be slid and to reciprocate up and down. A free compression spring 2373 is inserted into the space formed by the upper and lower spring housings 2371 and 2372 inserted into each other. The degree of insertion of the upper spring housing 2371 and the lower spring housing 2372 is adjusted by the pre-compression spring 2373 to perform the reciprocating motion in the vertical direction. The upper spring housing 2371 is fixed to the upper cover 2100 by fixing bolts or the like and the lower spring housing 2372 is fixed to the housing flange 2343 outside the periphery of the housing of the ball transfer fixing block 2330 or the ball transfer 2340. [ Lt; / RTI > When the upper cover 2100 is directly connected to the ball transfer flange 2343, the head of the bolt moves to the upper side of the upper cover 2100 according to the tension stroke of the mold spring, A problem that can not be generated occurs. The present embodiment solves such a problem.

15 is a perspective view according to another embodiment of the present invention. 15 is an embodiment in which the upper spring housing 2371 and the lower spring housing 2372 can more easily reciprocate up and down in the fastening bolt spring cushion 2370 of the seismic table of Figs. 15, the upper spring housing 2371 is formed with a predetermined length cut portion in the longitudinal direction, and the lower spring housing 2372 inserted into the upper spring housing 2371 passes through the side of the insertion end, 2376). The connection pin passes through the cutout of the upper spring housing 2371 and the side of the insertion end of the lower spring housing 2372. The connection pin 2376 is coupled to the end of the connection pin 2376, 2376 are movably coupled along the incision so that the insertion end of the lower spring housing 2372 is inserted into the upper spring housing 2372 and is vertically moved by the elasticity of the precompression spring 2373 when an external impact is received It is possible to prevent the problem that the connection bolts 2374 and 2375 are protruded to the outside of the upper cover 2100 and the lower cover 2200 or separated from each other when an impact such as an earthquake is absorbed.

Claims (15)

An upper bracket supporting the seismic isolation device;
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 at least one first vibration absorbing portion disposed between the upper bracket and the lower bracket,
Wherein the first vibration-
A bracket fixing block coupled to an inner surface of the upper bracket or the lower bracket, a vibration reduction material composed of a vibration reduction material having a predetermined thickness and coupled to the bracket fixing block, a ball transfer fixing block coupled to the vibration reduction material, And a ball transfer moving limit block coupled to the inner surface of the other bracket, not the bracket to which the bracket fixing block is coupled,
Wherein the ball transfer comprises a rolling ball, a housing for receiving the rolling ball, and an exposure slot formed at one end of the housing to expose a portion of the rolling ball, wherein the ball transfer fixing block and the vibration- And a through hole having a diameter corresponding to the outer diameter is formed, the ball transfer is inserted in the housing through the through hole,
And the ball transfer fixing block, the vibration reducing member, and the ball transfer fixing block are formed in a plate shape corresponding to each other and are in turn engaged with each other, and the ball transfer moving limit block is fixed to the bracket fixing block, Wherein the spacer is formed in a circular frame shape spaced apart from the transfer fixing block and a predetermined distance around the ball transfer. delete The method according to claim 1,
Wherein the ball transfer fixing block and the vibration reduction material are formed with the number corresponding to the number of the ball transfers, respectively. The method according to claim 1,
Wherein a reinforcing compression spring having a diameter corresponding to a diameter of the through hole, one end of which is disposed at an end of the housing inserted into the through hole, is inserted into the through hole. The method according to claim 1,
A plurality of second vibration absorbing portions are additionally disposed between the upper bracket and the lower bracket,
The second vibration-
A first spring which is a compression spring, and
And a spring locking block engaging with both ends of the first spring,
Wherein the spring fastening block has a cylindrical first spring coupling hole having a diameter corresponding to the diameter of the first spring formed on the plate-shaped metal block, a thread groove is formed on the inner circumferential surface of the fastening hole, So as to engage with each other. 6. The method of claim 5,
Wherein the upper bracket and the lower bracket are formed in a quadrangular shape and the second vibration absorbing portions are respectively disposed at apexes of the quadrangle. 6. The method of claim 5,
A second spring disposed coaxially with the first spring of the second vibration absorbing portion and having spring rings formed at both ends thereof;
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, Wherein the spring tension adjusting bolt is bolted through the upper bracket so as to be movable up and down. The method according to claim 1,
Wherein the first vibration absorbing portion is disposed in a central region of the upper bracket and the lower bracket and a plurality of second vibration absorbing portions are disposed in other regions between the upper bracket and the lower bracket,
The second vibration-
A third spring having a spring ring 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,
A spring tension adjusting bolt penetrating through an outer surface of the upper bracket and having a lower end fastened to the bolt fitting hole and a groove formed in the head;
A bolt loosening prevention block formed of a polygonal head and a protrusion corresponding to the shape of the protrusion, the protrusion being engaged with the protrusion to prevent the release of the spring tension adjusting bolt; And
A polygonal bolt loosening prevention member corresponding to the head of the bolt loosening block so that the bolt loosening prevention block can be seated from the upper surface of the block to the protruding side in a main body in which a plate-shaped block and a pipe- A bolt head groove having a shape corresponding to that of the head of the spring tension adjusting bolt is formed from the bottom face of the bolt release preventing block mounting groove to the bottom of the bolt head fitting groove, And a tension spring assembly block having bolt tabs formed on the inner circumferential surface thereof so as to be screwed with the bolt groove portion. 6. The method of claim 5,
Wherein the upper bracket is formed with a guide block for guiding the vertex of the facility to be spliced at a position corresponding to each vertex of the equipment to be spliced,
Wherein the lower bracket is fixed to the floor, and a reinforcing frame is coupled to both sides. 9. The method according to any one of claims 1 and 3 to 8,
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. The method according to claim 1,
Wherein the upper bracket and the lower bracket are connected by a wire. An upper bracket supporting the seismic isolation device;
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 at least one first vibration absorbing portion disposed between the upper bracket and the lower bracket,
Wherein the first vibration-
A ball transfer fixing block formed of a vibration reducing material having a predetermined thickness and disposed on the bottom surface of the upper bracket, a ball transfer fixing block coupled to the vibration reduction material, a ball transfer coupling to the ball transfer fixing block, A ball transfer movement limit block,
Wherein the ball transfer comprises a rolling ball, a housing for receiving the rolling ball, and an exposure slot formed at one end of the housing to expose a portion of the rolling ball, wherein the ball transfer fixing block and the vibration- A first through hole having a diameter corresponding to the outer diameter is formed,
A reinforcing compression spring for reducing the z-axis vibration is disposed between the upper end of the housing body and the upper bracket, and a second compression spring for reducing vibration of the z-axis is disposed between the upper end of the housing body and the upper bracket. A plurality of through holes are formed, a spring cushion is disposed in the second through hole,
Wherein the spring cushion has a cylindrical shape with a different diameter and is inserted into one end of the spring cushion and is reciprocated up and down. delete 13. The method of claim 12,
Wherein the vibration reduction material is coupled to the vibration reduction material using the second fastening bolt and the vibration isolation material is coupled using the first fastening bolt and the ball transfer fixing block is coupled to the vibration reduction material using the second fastening bolt,
A plurality of second through holes are formed along a circumference of the first through hole of the vibration reduction material, the first fastening bolt is inserted into the upper end of the second through hole through the upper bracket, And a second fastening bolt is inserted through the ball transfer fixing block at the lower end thereof, and an elastic body is connected between the first fastening bolt and the second fastening bolt to absorb shock. The method of claim 14, wherein
A lower spring housing having a cylindrical shell shape in which the upper spring housing is inserted into the lower end of the upper spring housing and reciprocates in a vertical direction, and a lower spring housing inserted into a space defined by the upper spring housing and the lower spring housing, And a pre-compression spring for imparting elasticity to the base member.

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