KR20180126657A - A three dimension seismic isolator for maintaining easily - Google Patents

Abstract

The present invention relates to a three-dimensional (3D) seismic isolator easy to maintain, capable of ensuring safety of a building. According to the present invention, the 3D seismic isolator easy to maintain comprises a seismic isolation part (200) to reduce horizontal vibration and a vibration isolation part (200) to reduce vertical vibration. The seismic isolation part (200) comprises upper and lower plates (201, 202), and a seismic isolation material (203). The vibration isolation part (100) comprises first and second vibration isolation parts (110, 120). The first vibration isolation part (110) comprises first outer and inner plates (111, 112), and a first vibration isolation material (113). The second vibration isolation part (120) comprises second inner and outer plates (121, 122), and a second vibration isolation material (123). The first and second outer plates (111, 122) are wider than the first and second inner plates (112, 121). One or more stoppers (130) are installed on a part of the widely formed first and second outer plates (111, 122), such that horizontal movement of the first and second vibration isolation parts (110, 120) are restricted. Moreover, one or more refractory boards (300) are installed on a side surface of the first outer plate (111).

Description

[0002] A three-dimensional seismic isolator for still easily,

More specifically, the present invention relates to a three-dimensional seismic isolation device including a planar portion capable of attenuating a horizontal vibration and a dustproof portion capable of attenuating vertical vibration, The present invention relates to a three-dimensional (3-D) seismic isolation system that is improved in performance and has an excellent life span and is easy to maintain.

Isolation technology is a technique to reduce the earthquake effect on a building by inserting a special device between the building and the foundation to make the vibration period of the building long, and it is an effective technique that can greatly improve the seismic behavior of the superstructure to be. This technology has been acknowledged for its excellence as a technology that has been demonstrated and commercialized mainly in countries that have experienced earthquakes such as Japan, USA, New Zealand and China.

In addition, seismic isolation technology is a very practical technology that can effectively improve seismic performance not only in new buildings but also in existing structures, under conditions that do not impair the function or beauty of the structure itself.

However, in the case of exposure to an environment adjacent to a medium causing uncomfortable vibration such as an iron-ridged site or an artificial ground, the problem of vertical vibration in terms of usability may seriously arise. .

As a solution to this problem, methods of reducing the vibration source and blocking the transmission path such as vibration damping can be considered. However, both methods are likely to require investment over the initial cost to the target building, which is a proactive solution It is difficult to see. In addition, since the apartment house is constructed on the artificial soil, the increase of the layer shear force due to the apartment house causes the problem of increasing the thickness of the artificial soil, so that it is necessary to reduce the layer shear force of the upper apartment house.

In addition, in order to solve this problem, when the dustproof part and the seismic part are installed separately, the problem of the construction cost incurred is burdened, and in addition, the problem of air increase causes the economic burden to increase.

Japanese Unexamined Patent Publication (Kokai) No. 1996-260753 discloses an isolation device including a plurality of alternating layers of a hard plate having rigidity and a flexible plate having viscoelastic property alternately stacked and a vibration isolating pad.

However, in such a seismic isolation device, since the dustproof pad and the seismic isolation part are not separated from each other, it is difficult to maintain and repair the construction.

Japanese Unexamined Patent Publication (Kokai) No. 1994-173496 discloses a three-dimensional earthquake-proof type vibration isolation device that integrates horizontal vibration in the horizontal direction and environmental vibration in the vertical direction.

However, this also causes problems of rubber dents and deterioration of the vibration-damping material caused by the increase of the thickness of the dust-proof portion and deterioration of the performance of the vibration damping material due to difficulties in maintenance There were also many problems in.

JP 1996-006687 A JP 2002-066879 A JP 1996-047331 A JP 2001-289279 A JP 1994-069896 U JP 2003-269530 A JP 1994-173496 A

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems.

In order to solve the construction cost and the air increase problem caused by installing the planar portion and the dustproof portion separately in installing the isolation device for reducing the horizontal vibration and the vertical vibration.

In other words, the present invention provides a seismic isolation device capable of simultaneously installing a planar portion and a dust-proof portion at the same time, and improving the refractory performance, thereby providing a three-dimensional seismic isolation device having a significantly increased lifetime unlike a conventional seismic isolation device. do.

According to an aspect of the present invention, there is provided a three-dimensional seismic isolation system including a planar portion for reducing horizontal vibration and a vibration preventing portion for reducing vertical vibration, The chamfered portion 200 includes an upper plate 201; A lower plate 202 spaced apart from the upper plate 201; And a face gear member 203 positioned between the upper plate 201 and the lower plate 202. The vibration preventing portion 100 includes a first vibration preventing portion 200 located on the upper portion of the chamfered portion 200, (110) and a second vibration preventing part (120) positioned below the beveled part (200), wherein the first vibration preventing part (110) comprises a first outer plate (111); A first inner plate 112 spaced apart from the first outer plate 111; And a first dustproof member (113) positioned between the first outer plate (111) and the first inner plate (112), and the second dustproof portion (120) includes a second inner plate (121); A second outer plate (122) spaced apart from the second inner plate (121); And a second vibration isolator 123 positioned between the second inner plate 121 and the second outer plate 122. The first outer plate 111 and the second outer plate 122 The first outer plate 111 and the second outer plate 122 are formed to be wider than the first inner plate 112 and the second inner plate 121. One or more stoppers 130 may be formed on the wide portions of the first outer plate 111 and the second outer plate 122, The vertical movement of the first anti-vibration unit 110 and the second anti-vibration unit 120 is restricted, and one or more fire board 300 is installed on the side of the first outer plate 111 And the length of the refractory board 300 is longer than the sum of the lengths of the first dustproof portion 110, the beveled portion 200 and the second dustproof portion 120. The length of the first dustproof portion 110, And a side surface of the second anti-vibration part (120).

The stopper 130 may be detachably attached to the first outer plate 111 and the second outer plate 122 by being bolted to the first outer plate 111 and the second outer plate 122, A horizontal part 131 fastened to the second outer plate 122; And a second vibration preventing part 120 extending perpendicularly from a portion of the horizontal part 131 adjacent to the first vibration preventing part 110 and the second vibration preventing part 120. The first vibration preventing part 110 and the second vibration preventing part 120, And a vertical portion 132 that covers the upper surface of the base portion 130. [

The vertical portion 132 may extend longer than the height of the first anti-vibration portion 110 or the second anti-vibration portion 120.

It is preferable that the anti-vibration part 100 and the chamfered part 200 are one of a laminated rubber type and a steel type.

It is preferable that the laminated rubber type includes a lead-in type, a natural rubber type, or a high-attenuation type, and the steel type includes a ball type, a roller type, or a line type.

The refractory board 300 includes a refractory board fixing part 301 including a hinge and the refractory board fixing part 301 is located on a side surface of the first outside plate 111, It is preferable that the refractory board 300 is opened by the fixing part 301 so that the dustproof part 100 and the chamfered part 200 are exposed to the outside.

The height of the first anti-vibration portion 110 or the second anti-vibration portion 120 is preferably lower than the height of the chamfered portion 200.

When a three-dimensional seismic isolation system according to the present invention is used for remodeling an existing structure for vertical expansion, it is possible to secure a change in the structural form of the vertically enlarged portion of the upper portion and a variation in the plane, The safety of existing buildings and vertically enlarged buildings can be secured. This can also reduce the amount of overhead framing to build a new building.

In addition, by integrating the anti-vibration function and the seismic isolation function, both functions can be secured, and the utilization of space is increased and economical efficiency is secured.

Further, it is not necessary to separately install the seismic isolation device and the dustproof device, thereby reducing the number of construction steps.

In addition, since the three-dimensional seismic isolation device according to the present invention can construct a separate seismic layer, it is easy to maintain and repair.

In addition, it is possible to reduce the amount of seismic reinforcement due to the lowering of the lower shear force in the remodeling of the existing building, so that the shortening of air and the economical effect are excellent.

1 is a cross-sectional view of a three-dimensional isolator according to the present invention.
Fig. 2 shows a cross-sectional view of the three-dimensional seismic isolation device with the refractory board open.

Hereinafter, a three-dimensional seismic isolation apparatus according to the present invention will be described in detail with reference to the drawings. Here, the constituent elements of the present invention can be used integrally or separately from each other as needed. In addition, some components may be omitted depending on the usage form. Various modifications can be made in the form and the number of elements of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of a three-dimensional seismic isolation device according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, the definitions of these terms should be described based on the contents throughout this specification.

Hereinafter, a three-dimensional seismic isolation apparatus according to the present invention will be described with reference to FIG.

A three-dimensional seismic isolation system according to the present invention includes a dustproof portion 100, a faced portion 200, at least one stopper 130, and at least one refractory board 300.

The vibration preventing portion 100 is for reducing vertical vibration and includes a first vibration preventing portion 110 and a second vibration preventing portion 120.

The first vibration preventing portion 110 is located on the upper side of the flange portion 200 and includes a first outer plate 111, a first inner plate 112 and a first vibration isolator 113.

The first outer plate 111 is located at the uppermost portion of the first dustproof portion 110 and is formed wider than the first inner plate 112.

The first inner plate 112 is spaced apart from the first outer plate 111, and the first dustproof member 113 is positioned between the first inner plate 112 and the first outer plate 111.

The first dustproof member 113 is located between the first outer plate 111 and the first inner plate 112.

The second vibration preventing portion 120 is located below the chamfered portion 200 and includes a second inner plate 121, a second outer plate 122 and a second vibration preventing member 123.

The second inner plate 121 is located at the uppermost portion of the second dustproof portion 120 and is formed to be narrower than the second outer plate 122. And is preferably formed in the same area as the first inner plate 112.

The second outer plate 122 is spaced apart from the second inner plate 121, and the second dustproof material 123 is positioned between the second outer plate 122 and the second inner plate 121.

The second dustproof member 123 is positioned between the second inner plate 121 and the second outer plate 122.

The first outer plate 111 and the second outer plate 122 corresponding to the outer plate of the three-dimensional isolator according to the present invention may include a first inner plate 112 and a second inner plate 112, 2 inner side plate 121. [0051] As shown in FIG.

The first and second outer plates 111 and 112 are designed to prevent the upper and lower bolts from being tightened when the vibration isolation device is installed together with the vibration isolation device. Are formed to be wider than the first inner plate 112 and the second inner plate 121, so that stable bolt fastening is possible.

The stopper 130 is installed in the first vibration preventing part 110 and the second vibration preventing part 120 to limit horizontal movement of the first vibration preventing part 110 and the second vibration preventing part 120.

The stopper 130 is installed in a part of the first outer plate 111 and the second outer plate 122 formed to be wider than the first inner plate 112 and the second inner plate 121. Specifically, The horizontal portion 131 and the vertical portion 132 are provided at portions of the outer plates 111 and 122 that are formed wider than the first and second plates 112 and 121.

The vertical portion 132 of the stopper 130 is located outside the first and second vibration preventing portions 110 and 120 and is provided at the outer side of the first inner plate 112 and the second inner plate 121 with a stopper 130 extend perpendicularly from the horizontal portion 132 of the stopper 130 such that the vertical portion 132 of the stopper 130 has an adjacent distance.

The stopper 130 may be detached by being bolted to the first outer plate 111 and the second outer plate 122. Specifically, when the horizontal portion 132 of the stopper 130 contacts the outer plates 111 and 122 To be detached therefrom.

The stopper 130 includes a first inner plate 112 and a horizontal portion that is fastened to portions of the first outer plate 111 and the second outer plate 122 that are wider than the second inner plate 121 131 and a vertical portion 132 extending vertically in the horizontal portion 131. [ The vertical part 132 is adjacent to the first vibration preventing part 110 and the second vibration preventing part 120 excluding the first outer plate 111 and the second outer plate 122 of the horizontal part 131, It may be desirable to extend vertically on the side that may be somewhat spaced apart from the inner plate 112 and the second inner plate 121.

The stopper 130 includes the horizontal portion 131 and the vertical portion 132 so that the stopper 130 can be tightened to the first outer plate 111 and the second outer plate 122 . The stopper 130 includes the horizontal portion 131 having a predetermined area so that the stopper 130 can effectively restrict the horizontal movement of the first dustproof portion 110 and the second dustproof portion 120 without being detached. The vertical portion 132 of the stopper 130 may be longer than the height of the first vibration preventing portion 110 or the second vibration preventing portion 120 in the horizontal portion 131.

The planar portion 200 is for reducing horizontal vibration and includes an upper plate 201, a lower plate 202, and a face gear 203.

The upper plate 201 is located at the top of the beveled portion 200 and faces the lower portion of the first inner plate 112 of the first anti-vibration portion 110.

The lower plate 202 is spaced apart from the upper plate 201, and the face gear 203 is located between the spaced apart.

The face member 203 is positioned between the upper plate 201 and the lower plate 202.

On the other hand, in another embodiment, a laminated rubber type or a steel type may be adopted for each of the dustproof portion 100 and the planar portion 200. [

Specifically, the laminated rubber type may include a lead-in type, a natural rubber type, and a high-attenuation type, but is not limited thereto, and any laminated rubber type used in the same technical field may be included.

The steel type may include a ball type, a roller type, and a line type. However, the steel type is not limited thereto and may be all of the laminated rubber type used in the same technical field.

In another embodiment, the height of the first anti-vibration part 110 or the second anti-vibration part 120 is formed to be lower than the height of the beveled part 200. Generally, the anti- And the shape factor is relatively thin, which is less than 3.0.

Also, in one embodiment, the vibration-proof portion 100 and the flange portion 200 are bolted together, thereby replacing the end-of-life components included in the vibration-proof portion 100 and the flange portion 200.

The operation of the refractory board 300 and the refractory board 300 will be described with reference to FIG.

The refractory board 300 is installed on the side of the first outer plate 111. The first dustproof portion 110, the chamfered portion 200, and the second dustproof portion 120 (not shown) may be formed to cover the first dustproof portion 110, the second dustproof portion 120, As shown in Fig.

The refractory board 300 may be provided on the side of the first outer plate 111 so as to cover the sides of the first dustproof portion 110, the beveled portion 200 and the second dustproof portion 120 .

The refractory board 300 may further include a refractory board fixing part 301 located at a portion of the first outside plate 111. And may be a side surface of the first outer plate 111.

The refractory board fixing portion 301 includes a hinge, and the refractory board 300 can be opened by the hinge of the refractory board fixing portion 301. At this time, the dustproof portion 100 and the planar portion 200 located inside thereof are exposed to the outside.

The anti-vibration performance of the three-dimensional isolator according to the present invention can be enhanced by the refractory board 300. The anti-vibration performance of the three- It is possible to prevent the refractory that may be worn by the dustproof part 100 by the refractory board 300 located outside the refractory board 300.

While the present invention has been described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. It will be appreciated that embodiments are possible. Accordingly, the scope of protection of the present invention should be determined by the claims.

100:
110: first anti-vibration part
111: first upper panel
112: first lower panel
113: first dustproof member
120: second anti-vibration part
121: second upper panel
122: second lower panel
123: the second dustproof material
130: Stopper
131:
132:
200: Cotton
201: upper plate
202: Lower plate
203: Cotton thread
300: Refractory board
301: Refractory board fixing section

Claims (7)

A three-dimensional seismic isolation system including a planar portion (200) for reducing horizontal vibration and a vibration preventing portion (100) for reducing vertical vibration,
The chamfered portion (200)
An upper plate 201;
A lower plate 202 spaced apart from the upper plate 201; And
And a face rim (203) positioned between the upper plate (201) and the lower plate (202)
The dustproof portion 100 includes a first dustproof portion 110 located at an upper portion of the chamfered portion 200 and a second dustproof portion 120 located at a lower portion of the chamfered portion 200,
The first anti-vibration unit (110)
A first outer plate 111;
A first inner plate 112 spaced apart from the first outer plate 111; And
And a first dustproof member (113) positioned between the first outer plate (111) and the first inner plate (112)
The second anti-vibration part (120)
A second inner plate 121;
A second outer plate (122) spaced apart from the second inner plate (121); And
And a second vibration isolator (123) positioned between the second inner plate (121) and the second outer plate (122)
The first outer plate 111 and the second outer plate 122 are formed wider than the first inner plate 112 and the second inner plate 121,
At least one stopper 130 is installed at a wide portion of the first outer plate 111 and the second outer plate 122 so that the first and second vibration dampers 110 and 120 ) Is limited,
One or more refractory boards 300 are installed on the side surfaces of the first outer plate 111 and the length of the refractory board 300 is longer than the lengths of the first and second dustproof parts 110, (200) and the side surface of the second dustproof portion (120), which is longer than the sum of the lengths of the first dustproof portion (110), the dustproof portion (120)
Three - dimensional isolator.
The method according to claim 1,
The stopper 130 is detachable by being bolted to the first outer plate 111 and the second outer plate 122.
The stopper (130)
A horizontal part 131 fastened to the first outer plate 111 and the second outer plate 122; And
The first and second dustproof parts 110 and 120 may extend vertically from the horizontal part 131 adjacent to the first and second dustproof parts 110 and 120, And a vertical portion (132)
Three - dimensional isolator.
3. The method of claim 2,
The vertical portion 132 may extend longer than the height of the first dustproof portion 110 or the second dustproof portion 120,
Three - dimensional isolator.
The method according to claim 1,
The anti-vibration part (100) and the beveled part (200) are each formed of a laminated rubber type or a steel type,
Three - dimensional isolator.
5. The method of claim 4,
In the laminated rubber type,
A lead-in type, a natural rubber type, or a high-attenuation type,
In the steel type,
Including ball type, roller type or line type,
Three - dimensional isolator.
The method according to claim 1,
The refractory board 300 includes a refractory board fixing part 301 including a hinge,
The refractory board fixing part 301 is located on the side of the first outer plate 111 and the refractory board 300 is opened by the refractory board fixing part 301, And the beveled portion 200 is exposed to the outside,
Three - dimensional isolator.
The method according to claim 1,
The height of the first anti-vibration part 110 or the second anti-vibration part 120 may be,
The height of the beveled portion 200,
Three - dimensional isolator.

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