KR101984895B1 - seismic isolation system - Google Patents

Abstract

The present invention relates to a seismic isolation device comprising a sliding platform (100) having a downwardly concave spherical sliding surface (120) formed on an upper surface thereof and a sliding surface (120) which is slidable on the sliding surface The slide body 200 slides on the slide surface 120 and absorbs vibration due to an earthquake.

Description

Seismic isolation system

The present invention relates to an isolation device capable of protecting a structure from an earthquake.

In the event of an earthquake, vibrations are transmitted longitudinally or transversely to structures such as buildings or facilities. Vibrations in the lateral direction severely shake and twist the structure. If the transmitted vibration is severe, the structure is partially damaged to lower the stability and, in severe cases, to collapse the structure.

Accordingly, an isolation device is installed to prevent damage caused by an earthquake. Such an isolation device maintains the state of supporting the structure at normal times. When an earthquake occurs, it absorbs the vibration caused by the earthquake and protects the structure from earthquake.

Patent Registration No. 10-1684575 (Registered on December 2, 2016) "Isolation device"

An object of the present invention is to provide an isolation device that can effectively absorb vibrations applied to a structure in the event of an earthquake, thereby safely protecting the structure.

According to the present invention, there is provided a slide fastener comprising a slide base having a downwardly concave spherical slide surface formed on an upper surface thereof, and a slide body which is placed on the slide surface and is capable of sliding on the slide surface by the slide means, An object of the present invention is to provide an isolation device for absorbing vibrations caused by an earthquake.

According to the present invention, the vibration applied to the structure can be effectively absorbed in a situation where an earthquake occurs, so that the structure can be safely protected when an earthquake occurs.

Brief Description of Drawings Fig. 1 is a view showing a state in which a seismic isolation device according to the present invention is installed,
FIG. 2 is an exemplary view schematically showing a structure of a seismic isolation device according to the present invention,
3 is an exploded view of a main structure of an isolation device according to the present invention;
4 and 5 are views showing another embodiment of the structure for supporting the slide ball according to the present invention,
6 is a view showing another embodiment of the structure for supporting the shaft bundle according to the present invention,
FIG. 7 is a view showing another embodiment of the structure in which the slide base and the pedestal are coupled in the seismic isolation device according to the present invention,
FIG. 8 is an exemplary view showing an isolation device in which a sub slide body according to the present invention is formed; FIG.
9 is an exemplary view of a seismic isolation apparatus employing a sliding surface according to another embodiment of the present invention;
FIG. 10 is an exemplary view showing a structure in which an auxiliary slide body is formed in the seismic isolation device of FIG. 9;
FIG. 11 is an exemplary view showing a seismic isolation apparatus adopting sliding means according to another embodiment of the present invention; FIG.
FIGS. 12 and 13 illustrate examples of sliding means according to another embodiment of the present invention;

In order to obtain an isolation device for effectively absorbing vibration applied to a structure in a situation where an earthquake occurs and safely protecting the structure,

A slider having a concave spherical sliding surface formed on an upper surface thereof and a sliding body placed on the sliding surface and slidable on the slidable surface by sliding means so that the sliding body slides on the sliding surface, In the case of the present invention.

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

Fig. 1 is a diagram illustrating a state in which an isolation device according to the present invention is installed.

As shown, the isolation device (SIS) according to the present invention is installed to isolate horizontal movement of a structure and a ground, and is installed at a point where the vertical load can be resisted in the structure. It is installed in the lower part of the column of the structure.

FIG. 2 is a view schematically showing a structure of a seismic isolation device according to the present invention, FIG. 3 is an explanatory view explaining a main structure of a seismic isolation device according to the present invention, and FIGS. Fig. 6 is a view showing another embodiment of the structure for supporting the shaft bundle according to the present invention.

As shown in FIG. 2, the SIS according to the present invention includes a slide base 100 and a slide body 200 slid by the slide means on the slide base 100.

The slide base 100 has a spherical sliding surface 120 having a predetermined thickness and concave downward on the upper surface thereof. The slide base 100 may be formed in a disc shape, but is not limited thereto.

The slide body 200 has a predetermined thickness and is slid on the slide surface 120. The slide means is formed on the bottom surface of the slide body 200 or separately provided and is mounted on the slide surface 120 so that the slide body 200 slides on the slide surface 120 in all directions. Therefore, even when the slide bar 100 moves in the horizontal direction due to the vibration due to the earthquake, the slide body 200 is not moved, and as a result, the degree of transmission of vibration to the structure can be reduced.

A movement restricting groove 140 is formed at the center of the sliding surface 120. A movement restricting protrusion 260 corresponding to the movement restricting groove 140 is formed on the bottom surface of the slide body 200. The movement restricting protrusion 260 is formed to have a thickness smaller than the diameter of the movement restricting groove 140 so that the movement restricting protrusion 260 can move to a certain extent within the movement restricting groove 140. However, Is not released from the movement restricting groove 140 so that the slide body 200 is not released from the slide base 100. [

In the structure in which the movement restricting groove 140 is formed as described above, the check port 160 extending from the outer surface of the slide unit 100 to the movement restricting groove 140 is formed. The inside of the movement restricting groove 140 is inspected through the check port 160 to check whether the movement restricting protrusion 260 is damaged or not.

The slide means may be formed of a plurality of slide balls 222 installed on the bottom surface of the slide body 200. A housing is formed on the bottom surface of the slide body 200, and a slide ball 222 is housed inside the housing and partially rotatably received. It is needless to say that such an appropriate number of slide balls 222 should be provided to stably support the slide body 200 and an appropriate installation position should be selected so that the slide body 200 can slide with its center of gravity .

Meanwhile, an auxiliary ball 223 may be provided in the housing in which the slide ball 222 is received. In this case, the inner wall of the housing is hemispherical, and the auxiliary ball 223 is disposed along the wall surface of the housing, and the slide ball 222 is disposed adjacent to the auxiliary ball 223. This auxiliary ball 223 is disposed between the slide ball 222 and the inner wall surface of the housing and is rolled, thereby reducing friction.

The auxiliary balls 223 may be arranged in two layers (FIG. 2) or one layer (FIG. 4). Of course, it is also possible to install the slide ball 222 on the support plate 226 without the auxiliary ball 223 and install it on the housing (Fig. 5).

Here, the slide means may be formed of a ball transfer unit 220 embedded in the bottom surface of the slide body 200. In this configuration, the ball transfer unit 220 is embedded in the bottom surface of the slide body 200. At this time, the ball transfer unit 220 may be formed such that the rear portion thereof is supported by the elastic plate 230 (FIG. The elastic plate 230 is made of an elastic material such as rubber to help absorb vibrations and shocks.

The SIS according to the present invention may further include an elastic cushion 300 installed under the slide base 100 to elastically support the slide base 100. The elastic cushion 300 may be formed of a material having elasticity, for example, rubber or polyurethane. The elastic cushion 300 is formed to have a constant area and thickness, and elastically absorbs vertical vibration.

The elastic cushion 300 may be installed on the pedestal 400. The pedestal 400 has a plate shape, and the elastic cushion 300 is seated on the upper surface thereof, thereby supporting the elastic cushion 300. A groove for receiving the elastic cushion 300 may be formed on the upper surface of the pedestal 400 so that the movement of the elastic cushion 300 is restricted so that the elastic cushion 300 does not slip. The groove may be formed on the bottom surface of the slide base 100 so that the elastic cushion 300 can be held at the top and bottom.

The slide base 100 is coupled to the pedestal 400 with the bolts 500 through the elastic cushion 300. A plurality of the bolts 500 may be disposed concentrically with a predetermined interval to join the sliding platform 100 and the elastic cushion 300. At this time, the bolt 500 is fastened in a state in which the bolt 500 can move up and down, so that the slide base 100 can move up and down in accordance with the contraction and expansion of the elastic cushion 300. The bolt 500 is fastened to the slide base 100 from the pedestal 400 and the bolt 500 fastened to the pedestal 400 without threading is vertically movable.

The SIS according to the present invention may further include a structure support 600 mounted on the slide body 200 to support the structure. A shaft rod 640 having a spherical shaft bundle 642 formed at the lower end thereof is protruded downward so that the shaft rod 640 is inserted into the shaft rod 640, And is fixed to the slide body 200 in an axial coupling manner. The shaft rod 640 may be separately provided and may be coupled to the bottom of the structure support 600.

An axial groove 242 for receiving the shaft bundle 642 is formed on the upper surface of the slide body 200 so that the shaft rod 640 can be coupled to the slide body 200. The shaft 242 has a shape corresponding to that of the shaft bundle 642 formed in a spherical shape as a groove having a spherical inner wall and is configured such that the shaft bundle 642 can be coupled in a rotatable manner in the shaft groove 242 . Accordingly, the structure support table 600 is placed on the slide body 200 so as to be rotatable.

Here, the auxiliary ball 643 may be provided in the shaft groove 242 (FIG. 6). An auxiliary ball 643 is disposed along the inner wall surface of the axial groove 242 and an axial bundle 642 is provided adjacent to the auxiliary ball 643. Accordingly, the auxiliary ball 643 is disposed between the shaft bundle 642 and the inner wall surface of the shaft 242 and is rolled, thereby reducing the friction.

The shaft groove 242 is formed in the buried body 240 and the upper surface buried body 240 of the slide body 200 is embedded and fixed so that the shaft groove 242 can be formed on the upper surface of the slide body 200 . 6). The elastic plate 230 is made of elastic material such as rubber. The elastic plate 230 is made of an elastic material, It helps to absorb.

The SIS according to the present invention may further include a protection film 700 for receiving and protecting the slide base 100 and the slide body 200 therein. When the elastic cushion 300 and the pedestal 400 and the structural support 600 are provided, the protective film 700 is fixed to the pedestal 400 and the upper end is fixed to the structural support 600, . The objects to be protected are dust, foreign matter, heat, flame, moisture, etc., and protect various structures from various external pollutants, so that they can function in any environment and maximize their service life.

The protective film 700 is formed to be stretchable. For this purpose, it is possible to adopt a configuration in which a part is formed as a corrugated tube so that it can be expanded and contracted. When the protective film 700 is expanded and contracted, the protective film 700 is naturally expanded and contracted to prevent absorption of the vibration, so that the designed isolation performance can be realized.

In the SIS according to the present invention, the slide body 200 absorbs the horizontal vibration, the elastic cushion 300 absorbs the vertical vibration, and the structure support 600 vibrates in the rotation direction As a result, it is possible to selectively or entirely form an SIS to realize an optimal seismic performance.

Hereinafter, various embodiments of the respective components constituting the isolation device (SIS) according to the present invention will be described based on the basic structure as described above.

7 is a view showing another embodiment of a structure in which a slide pin and a pedestal are coupled in the seismic isolation device according to the present invention.

A bolt 500 for coupling the pedestal 400 and the slide base 100 may be inserted into the pedestal 400 through the slide base 100. In this case, At this time, the threaded portion is not formed on the slide base 100, so that the bolted body 500 can move up and down. Accordingly, the bolt 500 is fastened in a vertically movable state. As the elastic cushion 300 shrinks and expands, the slide base 100 can be moved up and down. As a result, the vertical vibration can be smoothly absorbed .

On the other hand, the spring is fastened to the bolt 500, so that the vibration absorbing capacity can be improved by shrinking and expanding the spring.

FIG. 8 is an exemplary view showing an isolation device in which a sub slide body according to the present invention is formed.

The SIS according to the present invention may include a sub slide body 250 and may have a multistage structure together with the slide body 200.

The auxiliary slide body 250 has a concave slide surface 120 formed on the upper surface thereof and is disposed between the slide base 100 and the slide body 200. The slide body 200 or the sub slide body 250 is placed on the slide surface 120 to form a multi-stage structure. When the sub slide body 250 is provided with one slide body 200, the slide body 200 is placed . In a case where two or more sub slide bodies 250 are provided, the sub slide body 250 is stacked and the slide body 200 is placed on the sub slide body 250 disposed on the top, .

The auxiliary slide body 250 is supported by the sliding means and can be slid. Since this sliding means has been described above, the description thereof will be omitted again.

FIG. 9 is a view illustrating an example of a seismic isolation system employing a sliding surface according to another embodiment of the present invention, and FIG. 10 is an exemplary view illustrating a structure in which a secondary slide body is formed in the seismic isolation system of FIG.

The SIS according to the present invention can be configured differently from the sliding surface 120 in the construction described above. The slide surface 120 is formed on the upper surface of the slide base 100 and the auxiliary slide body 250 as described above. In this embodiment, the slide surface 120 is formed in a concave spherical shape, (180) is formed.

In this configuration, the slide body 200 is placed on the slide surface 120 in a state of being accommodated inside the transfer agent stop 180. When the sub slide body 250 having the slide surface 120 formed on the upper surface thereof is provided, the transfer agent tip 180 is formed on the edge of the slide surface 120 formed on the sub slide body 250, The auxiliary slide body 250 is placed in a state in which it is accommodated inside the transfer agent rest 180 on the slide surface 120 formed on the slide table 100 and then transferred from the slide surface 120 formed on the auxiliary slide body 250 to the transfer agent step So that the slide body 200 is accommodated in the inside of the body 180 so as to have a multi-stage structure.

According to the above description, when the slide body 200 or the sub slide body 250 slides on the slide surface 120 due to vibration, the slide range is limited by the transfer agent stop 180. As a result, Or the auxiliary slide body 250 is not separated from the slide surface 120. [

On the other hand, a check hole 160 is formed in the transfer agent 180. The inside of the transfer agent tip 180 can be checked from the outside through the inspection port 160.

FIG. 11 is a view illustrating an example of an anti-vibration device employing sliding means according to another embodiment of the present invention, and FIGS. 12 and 13 are illustrations showing sliding means according to another embodiment of the present invention.

The sliding means to which the present invention is applied may be provided separately and may be mounted on the sliding surface 120. To this end, a configuration is proposed in which a plurality of slide balls 222 are rotatably mounted on a plate-shaped cage 228 as shown in the figure. The cage 228 may be formed to be convex downward with a curvature corresponding to the slide surface. If necessary, the central portion may be perforated to form a ring.

The slide balls 222 are disposed at regular intervals on a concentric circle with respect to the center of the cage 228. It is a configuration for adjusting the center of gravity. Further, they may be arranged in two or more rows on concentric circles having different diameters. As the number of the slide balls 222 increases, the ability to withstand loads increases. Therefore, the number and position of the slide balls 222 are determined in consideration of this.

In addition to the structure in which the slide support body 250 is mounted on the slide support 100 and the slide body 200 is mounted thereon (FIG. 11), the auxiliary slide body 250 is adopted But can be applied to all configurations.

100: sliding platform, 120: sliding surface,
140: movement restriction groove, 160: check port,
180: transfer agent, 200: slide body,
222: slide ball, 223, 643: auxiliary ball,
230: elastic plate, 240: buried material,
242: axial groove, 260: movement restricting projection,
300: elastic cushion, 400: pedestal,
500: bolt, 600: structure support,
640: shaft rod, 642: shaft rod,
700: Shield.

Claims (14)

A sliding platform 100 having a concave spherical sliding surface 120 formed on its upper surface,
And a plurality of slide balls 222 having a bottom surface convexly downwardly corresponding to the slide surface 120 so as to be movable in all directions on the slide surface 120 A slide body 200 capable of absorbing vibration caused by sliding and earthquake,
A shaft rod 640 having a spherical shaft bundle 642 formed at its lower end is protruded downward to support the structure on the slide body 200 and the axial groove 242 formed on the upper surface of the slide body 200, (600) rotatably installed on the slide body (200) by receiving the slide member (642). The method according to claim 1,
A transfer agent stopper 180 is formed at the edge of the slide surface 120 and the slide body 200 is placed on the slide pin 100 in a state of being accommodated inside the transfer agent tip 180,
And the sliding range of the sliding body 200 is limited by the moving agent threshold 180 so that it is not separated from the sliding platform 100. 3. The method of claim 2,
Wherein an inspecting hole (160) is formed in the transfer agent ceiling (180) to inspect the inside of the transfer agent ceiling (180). The method according to claim 1,
Wherein the slide means is formed of a plurality of slide balls (222) installed on a bottom surface of the slide body (200). 5. The method of claim 4,
The slide ball (222) is housed in the housing, and an auxiliary ball (223) is provided in the housing to roll the slide ball (222) to reduce friction. The method of claim 1, wherein
Wherein the slide unit is a ball transfer unit 220 embedded in a bottom surface of the slide body 200 and the ball transfer unit 220 is supported by an elastic plate 230. The method according to claim 1,
Wherein the sliding means comprises a plurality of slide balls (222) rotatably mounted on a plate-shaped cage (228). The method according to claim 1,
At least one of which is disposed between the slide base 100 and the slide body 200 and which is slidably supported by the slide means and has a concave sliding surface 120 formed on the upper surface thereof, Including an isolation device. The method according to claim 1,
And an elastic cushion (300) installed below the slide base (100) to elastically support the slide base (100) to absorb vibration. 10. The method of claim 9,
And a pedestal 400 for supporting the elastic cushion 300. The sliding platform 100 is coupled to the pedestal 400 with the bolts 500 via the elastic cushion 300,
The bolt 500 can be moved up and down so that the slide bar 100 can be moved up and down in accordance with the contraction and expansion of the elastic cushion 300. The method according to claim 1,
An auxiliary ball (643) is provided in the shaft groove (242) to contact the slide ball (222) and to reduce friction while rolling. 12. The method of claim 11,
The shaft 242 is formed in the body 240 and the shaft 242 is formed on the upper surface of the slide body 200 by the upper body 240 embedded in the slide body 200, Is supported by the elastic plate (230). The method according to claim 1,
And a protective film 700 for receiving and protecting the sliding platform 100 and the sliding body 200. The protective film 700 is stretched and contracted.
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