KR20220014754A - Horizontal-vertical seismic isolation device and seismic isolation facilities including the same - Google Patents

Abstract

According to an embodiment of the present invention, a horizontal-vertical vibration isolation device comprises: a vertical vibration isolation unit for preventing vertical vibration from being transmitted to an object; and a horizontal vibration isolation unit connected to a lower side of the vertical vibration isolation unit and having a laminated rubber bearing for preventing horizontal vibration from being transmitted to the object. The vertical vibration isolation unit comprises: a housing of which a lower surface is opened to allow the horizontal vibration isolation unit to penetrate the lower surface according to vertical vibration and having an inner space; an elastic member positioned in an inner space of the housing and connected to an upper surface of the horizontal vibration isolation unit and an inner surface of an upper side of the housing; and a reduction unit positioned in the inner space of the housing and provided to be connected to the upper surface of the horizontal vibration isolation unit and the inner surface of the upper side of the housing to reduce vibration of the elastic member in a vertical direction.

Description

HORIZONTAL-VERTICAL SEISMIC ISOLATION DEVICE AND SEISMIC ISOLATION FACILITIES INCLUDING THE SAME

The present invention relates to a horizontal-vertical seismic isolator and a seismic isolator including the same.

A seismic isolator is a device that can fundamentally secure the soundness of a structure against an earthquake by being installed between the upper structure and the ground or supporting layer to block seismic energy transmitted from the ground or supporting layer to the upper structure.

The seismic isolator may include a laminated rubber bearing which is generally widely used. Laminated rubber bearings are installed between the superstructure and the ground or support layer to provide excellent seismic isolation performance against horizontal earthquakes. Therefore, when an earthquake load is applied, the laminated rubber bearings perform a smooth horizontal movement to reduce the seismic load transmitted to the superstructure.

In addition, the seismic isolator may include a friction type bearing. Friction-type bearings are seismic isolators using friction plates. They do not move against weak vibrations, but when vibrations greater than the friction force of the friction plates occur, they slide and move horizontally, providing seismic isolating performance. Therefore, when an earthquake load is applied, the laminated rubber bearings perform a smooth horizontal movement to reduce the seismic load transmitted to the superstructure.

Korean Patent Publication No. 10-2020-0076058 (published on June 29, 2020)

SUMMARY OF THE INVENTION An object of the present invention is to provide a horizontal-vertical seismic isolator capable of preventing mathematical and horizontal vibrations from being transmitted to an upper structure, and a seismic isolator including the same.

A horizontal-vertical seismic isolator according to an embodiment of the present invention includes a vertical seismic isolator for preventing vertical vibration from being transmitted to an object, and is connected to a lower side of the vertical seismic isolator to prevent horizontal vibration from being transmitted to the object. A horizontal seismic isolator including a laminated rubber bearing, the vertical seismic isolator has a housing with a lower surface open so that the horizontal seismic isolator penetrates according to the vertical vibration, a housing having a space therein, and is located in the housing interior space and an elastic member connected to the upper inner surface of the housing, and a damping unit positioned in the housing inner space and provided to be connected to the upper surface of the horizontal seismic isolator and the upper inner surface of the housing to damp the vertical vibration of the elastic member may include

The horizontal seismic isolator includes a fixed plate formed to be fixed to the ground or a support layer, a lower plate provided on a lower surface of the laminated rubber bearing and fixed to the fixed plate, an upper plate provided on an upper surface of the laminated rubber bearing, and an upper surface of the upper plate. It is positioned, and may include a connection plate connected to the elastic member and the damping unit.

The housing is formed to have upper and lower surfaces open, and includes a accommodating part accommodating the elastic member and the horizontal seismic isolator and a cover covering an upper surface of the accommodating part, and an inner surface of the accommodating part may be in contact with a side surface of the connection plate. .

The housing may further include a bent portion that is bent inwardly from a lower side of the receiving portion, and is positioned below the connection plate.

The cover further includes a cover body connected to the receiving part, and an elastic pressing part protruding from a lower surface of the cover body in a direction of the horizontal seismic isolating part to be connected to the elastic member and having a groove formed therein, and the vertical seismic isolating part is the connection plate. It is formed extending from the upper surface in the direction of the cover, further comprising an elastic support for supporting the elastic member, when the horizontal seismic part is moved upward, the elastic support is inserted into the groove, and the elastic pressing part is the elastic The member can be compressed.

The elastic pressing part, the elastic member, and the elastic support body may be formed in plurality.

The damping unit is a damper that is formed in the vertical direction to damp the vibration of the elastic member, is formed extending from the cover in the direction of the horizontal seismic unit, is connected to one side of the damper, and rotates the damper according to the vertical movement of the horizontal seismic isolator A damper pressing part and a damper support part extending from the horizontal seismic part in the direction of the cover to support the other side of the damper, one side of the damper may be rotatably connected to the damper pressing part.

The damper pressing part may include a connection part having one side connected to the cover, a protrusion protruding from the other side of the connection part in the direction of the horizontal seismic part, and a rotating shaft passing through the protrusion part and connected to one side of the damper.

It may include an upper structure and at least one horizontal-vertical seismic isolator positioned below the upper structure.

A seismic isolator according to an embodiment of the present invention is connected to a vertical seismic isolator for preventing vertical vibration from being transmitted to an object and a lower side of the vertical seismic isolator, and a laminated rubber bearing for preventing horizontal vibration from being transmitted to the object. and a horizontal seismic isolator including It may include an elastic member to be connected and a damping unit located in the inner space of the housing, provided to be connected to an upper surface of the horizontal seismic isolator and an upper inner surface of the housing, to attenuate vibrations in the vertical direction of the elastic member.

The horizontal-vertical seismic isolator may be formed in plurality.

The horizontal seismic isolator may include a fixed plate formed to be fixed to the ground or a support layer, and a lower plate formed on a lower surface of the laminated rubber bearing and fixed to the fixed plate. It may include an upper plate provided on the upper surface of the laminated rubber bearing and a connection plate provided on a lower surface of the upper plate and connected to the elastic member and the damping unit.

The housing is formed so that upper and lower surfaces are open, and includes a cover for accommodating the elastic member and the damping unit and connected to the upper structure, and covering the upper surface of the receiving part, the inner surface of the receiving part is the connection may be in contact with the plate.

The housing may further include a bent part that is bent inwardly from the lower side of the accommodating part, and is positioned below the connection plate.

The cover further includes a cover body connected to the receiving part and an elastic pressing part protruding from a lower surface of the cover body in a direction of the horizontal seismic isolating part to be connected to the elastic member and having a groove formed therein, and the vertical seismic isolating part is the connection plate. It is formed extending from the upper surface in the direction of the cover, further comprising an elastic support for supporting the elastic member, when the horizontal seismic part is moved upward, the elastic support is inserted into the groove, and the elastic pressing part is the elastic The member can be compressed.

The horizontal-vertical seismic isolator of the present invention includes a vertical seismic isolator and a laminated rubber bearing, so that horizontal and vertical vibrations can be prevented from being transmitted to an object.

In addition, the vibration of the elastic member included in the vertical seismic isolator can be efficiently damped through the damping unit.

1 is a view showing a seismic isolation facility according to an embodiment of the present invention.
2 and 3 are views illustrating a horizontal-vertical seismic isolator according to an embodiment of the present invention.
4 is a diagram illustrating a damper according to an embodiment of the present invention.
5 is a graph showing the horizontal vibration blocking performance of the horizontal-vertical seismic isolator according to an embodiment of the present invention.
6 is a graph showing the vertical direction vibration blocking performance of the horizontal-vertical seismic isolator according to an embodiment of the present invention.

Hereinafter, specific embodiments for implementing the technical idea of the present invention will be described in detail with reference to the drawings.

In addition, in the description of the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, when it is mentioned that a component is 'connected', 'supported', 'transferred', or 'contacted' to another component, it may be directly connected, supported, transmitted, or contacted with the other component, but other components in the middle It should be understood that elements may exist.

The terminology used herein is only used to describe specific embodiments and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, in the present specification, the expressions of the upper side, the lower side, the side, etc. are described with reference to the drawings, and it is to be noted in advance that if the direction of the corresponding object is changed, it may be expressed differently. For the same reason, some components are exaggerated, omitted, or schematically illustrated in the accompanying drawings, and the size of each component does not fully reflect the actual size.

Also, terms including an ordinal number such as 1st, 2nd, etc. may be used to describe various components, but the components are not limited by these terms. These terms are used only for the purpose of distinguishing one component from another.

The meaning of "comprising," as used herein, specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component, and/or group. It does not exclude the existence or addition of

Hereinafter, with reference to the drawings, a horizontal-vertical seismic isolator 1 including a vertical seismic isolator 3 according to an embodiment of the present invention will be described.

Referring to FIG. 1 , the seismic isolator 1 of the present invention may include an upper structure 2 and a horizontal-vertical seismic isolator 3 .

The superstructure 2 may be located on top of the horizontal-vertical seismic isolator 3 . The upper structure 2 may be formed of a building, device, cabinet, or the like, but is not limited thereto. The upper structure 2 can be prevented from vibrating in the vertical and horizontal directions (three-dimensional direction) by the horizontal-vertical seismic isolator 3 when an earthquake occurs. In addition, it is possible to prevent the horizontal and vertical loads that may be generated in the upper structure 2 from being amplified by the horizontal-vertical seismic isolator 3 .

The horizontal-vertical seismic isolator 3 serves to prevent vibration caused by an earthquake from being transmitted to the object. Such a vertical-planar seismic device 3 is installed between the superstructure 2 and the ground or support layer (G) to prevent seismic energy transmitted from the ground or support layer (G) from being transmitted to the superstructure (2). It is a device that can ensure the stability of the upper structure (2) for the.

The horizontal-vertical seismic isolator 3 can prevent horizontal load from being amplified in the upper structure 2 by horizontal deformation in order to prevent horizontal vibration caused by an earthquake from being transmitted to the object. In addition, in order to prevent the horizontal vibration caused by the earthquake from being transmitted to the object, it is possible to prevent the vertical load from being amplified in the upper structure 2 by vertical deformation.

In addition, as shown in FIG. 1 , the horizontal-vertical seismic isolator 3 is formed in plurality, so that the plurality may be installed on the lower surface of the upper structure 2 .

The horizontal-vertical seismic isolator 3 may include a vertical seismic isolator 30 and a horizontal seismic isolator 40 .

The vertical vibration isolation unit 30 serves to prevent vertical vibration from being transmitted to the object. The vertical seismic isolator 30 may be provided between the upper structure 2 and the horizontal seismic isolator 40 . The vertical seismic isolator 30 is vertically deformed when vibration occurs in the vertical direction to prevent amplification of the vertical load of the upper structure 2 .

The vertical seismic isolator 30 may include a housing 310 , an elastic member 320 , an elastic support 330 , and a damping unit 340 .

The housing 310 may be configured to induce vertical deformation of the elastic member 320 when vertical vibration is generated. The housing 310 is connected to the lower surface of the upper structure 2 , the lower surface is opened so that the horizontal seismic isolator 40 passes through, and a space may be formed therein. An elastic member 320 , an elastic support 330 , and a damping unit 340 may be accommodated in the inner space of the housing 310 . In addition, when the vertical vibration is generated, the lower surface of the housing 310 may be penetrated by the horizontal vibration isolator 40 .

2 and 3 , the housing 310 may include an accommodating part 312 , a cover 314 , and a bent part 316 .

The receiving part 312 has upper and lower surfaces open to serve for accommodating the elastic member 320, the elastic support 330, and the damping unit 340, and a space is formed therein to accommodate the elastic member 320, the elastic support 330. , the attenuation unit 340 can be accommodated. The accommodating part 312 is formed to contact the side surface of the connection plate 450 of the horizontal seismic isolation part 40 to be described later, so that when a vertical vibration occurs, the vertical movement of the connection plate 450 can be guided. The accommodating part 312 may be relatively movable in the vertical direction with respect to the connection plate 450 . In addition, an ultra-low friction coating is formed on the side surface of the connection plate 450 so that the connection plate 450 can be moved without friction when moving in the vertical direction.

The cover 314 is connected to the open upper surface of the accommodating part 312 and serves to cover the upper surface of the accommodating part 312 . The cover 314 may include a cover body 314a, a first fastening part 314d, a second fastening part 314c, and an elastic pressing part 314d.

The cover body 314a may be connected to the open upper surface of the accommodating part 312 and be fastened to the accommodating part 312 through the first fastening part 314c. The first fastening part 314d may be formed of a bolt, but is not limited thereto. This, the cover body (314a) may be in contact with the upper building. In addition, the outer surface of the cover body 314a is formed to protrude more than the receiving part, and it may be formed as a cover coupling part, and the cover coupling part may be configured to fasten the cover 314 to the upper structure 2 . The cover coupling part may be coupled to the upper structure 2 through the second coupling part 314d. The second fastening part 314c may be formed of a bolt that passes through the cover coupling part and is inserted into the upper structure 2, but is not limited thereto.

The elastic pressing portion 314d serves to vertically deform the elastic member 320 according to vertical vibration.

The elastic pressing part 314d may be connected to the elastic member 320 by protruding from the lower surface of the cover body 314a in the horizontal seismic isolating part 40 direction, and a groove into which a part of the elastic support 330 described later can be inserted. h) can be formed. The elastic pressing part 314d serves to compress the elastic member 320 when the horizontal seismic plane 40 is moved upward by the vertical vibration.

The groove (h) is formed so that a part of the elastic support 330 is inserted so that the elastic pressing part 314d effectively compresses the elastic member 320 . The groove (h) may be formed in the direction of the upper structure (2) on the lower surface of the elastic pressing portion (314d). Although it is shown in FIG. 2 that the groove (h) is formed only on the elastic pressing part 314d, the groove (h) may be formed extending from the elastic pressing part 314d to the cover body 314a.

A plurality of elastic pressing portions 314d may be formed to correspond to the number of elastic members 320 .

The bent part 316 is formed so that when the horizontal seismic isolator 40 is horizontally deformed by horizontal vibration or the elastic member 320 is vertically deformed by vertical vibration, the vertical seismic isolator 30 is separated from the horizontal seismic isolator 40 serves to prevent The bent part 316 may be bent inwardly from the lower side of the receiving part 312 to be positioned below the connection plate 450 of the horizontal seismic plane 40 . Even if the horizontal seismic isolator 40 is horizontally deformed by the bent part 316 or the elastic member 320 is vertically deformed, the bent part 316 is supported on the lower surface of the connection plate 450, so that the housing 310 is the horizontal seismic isolating part ( 40) can be prevented.

When the vertical vibration is generated, the elastic member 320 can prevent the vertical vibration from being transmitted to the upper structure 3 as it vertically deforms. The elastic member 320 may be positioned in the inner space of the housing 310 to be connected to the upper surface of the horizontal seismic isolator 40 and the upper inner surface of the housing 310 . For example, as shown in FIG. 2 , one side of the elastic member 320 may be connected to the elastic pressing part 314d, and the other side may be connected to the connection plate 450 .

The vertical deformation of the elastic member 320 may be generated by the horizontal vibration isolator 40 and the elastic pressing part 314d that are moved in the vertical direction by vertical vibration. As the elastic member 320 is vertically deformed, it is possible to prevent amplification of the vertical load in the upper structure 2 . In addition, when the vertical vibration is terminated, the elastic member 320 may be restored to a circular shape by its own elastic force and the damping unit 340 .

The elastic member 320 may be formed of a leaf spring as shown in FIG. 2 or a spring as shown in FIG. 3 , but is not limited thereto, and may be formed in plurality.

The elastic support 330 serves to support the elastic member 320 . The elastic support 330 may be formed to extend in the direction of the cover 314 from the upper surface of the horizontal seismic unit 40 , and the elastic member 320 may be formed to surround the outer surface of the elastic support 330 . When the horizontal vibration isolation unit 40 is moved upward by vibration in the vertical direction, a portion of the elastic support 330 may be inserted into the groove h of the elastic pressing unit 314d.

The elastic support 330 may be formed in plurality to correspond to the number of the elastic members 320 .

The damping unit 340 serves to absorb the vertical vibration transmitted from the vertical vibration isolation unit to damp the vibration of the elastic member 320 . The damping unit 340 is accommodated in the inner space of the housing 310 , and may be formed to be connected to the upper surface of the horizontal seismic isolator 40 and the upper inner surface of the housing 310 . In addition, since the elastic member 320 can continue to vibrate by the elastic force of the elastic member 320 even after the vertical vibration is completed, the vertical vibration of the elastic member 320 is efficiently attenuated through the damping unit 340 . can do.

The damping unit 340 may include a damper 342 , a damper pressing part 344 and a damper support part 346 , with reference to .

The damper 342 is formed in the horizontal direction and serves to damp the vibration of the elastic member 320 . One side of the damper 342 may be connected to the damper pressing part 344 , and the other side may be connected to the damper support part 346 . In addition, one side of the damper 342 may be formed to rotate on the damper pressing part 344 . The damper 342 is an elastic member 320 as one side of the damper 342 is rotated in the direction about the damper pressing part 344 when the horizontal seismic part 40 is moved in the vertical direction by vertical vibration. vibration can be damped.

For example, when the damper support part 346 is moved upward by the horizontal seismic isolator 40, the damper 342 is rotated in one direction, so that one side of the damper 342 is located below the other side of the damper 342. can Conversely, when the damper support 346 is moved downward by the horizontal seismic isolator 40 , the damper 342 may be formed horizontally as it rotates in the other direction. The rotation in the other direction may be formed in a direction opposite to the rotation in the one direction.

The damper pressing part 344 serves to rotate the damper 342 in order to damp the vibration of the elastic member 320 . The cover 314 is formed to extend in the direction of the horizontal seismic isolation unit 40 , and is connected to one side of the damper 342 , and the damper 342 can be rotated according to the vertical movement of the horizontal seismic isolation unit 40 .

4 , the damper pressing part 344 may include a connection part 344a, a protrusion part 344b, and a rotation shaft 344c. The upper surface connection part 344a may be formed to extend from the cover 314 in the horizontal seismic part 40 direction, and one side may be connected to the cover 314 . The protrusion 344b may be formed to protrude toward the horizontal seismic portion 40 from the other side of the connecting portion 344a of the connecting portion 344a. A plurality of protrusions 344b may be formed, and a damper 342 may be positioned between the plurality of protrusions 344b. The rotation shaft 344c may pass through the protrusion 344b and be connected to one side of the damper 342 . As the damper 342 is rotated about the rotation shaft 344c by the damper pressing part 344 , the vibration of the elastic member 320 may be attenuated.

The damper support part 346 is formed to extend in the direction of the cover 314 from the horizontal seismic part 40 and serves to support the other side of the damper 342 . When the horizontal vibration isolation unit 40 is moved upward by the vertical vibration, the damper support unit 346 may be moved upward to move the other side of the damper 342 upward. Conversely, when the horizontal seismic isolator 40 is moved in the downward direction, the damper support part 346 may be moved downward to move the other side of the damper 342 downward.

The horizontal seismic unit 40 serves to prevent horizontal vibration from being transmitted to the object. The vertical seismic isolator 30 is horizontally deformed when horizontal vibration is generated to prevent amplification of the horizontal load of the upper structure 2 . The horizontal seismic isolator 40 is connected to the lower side of the vertical seismic isolator 30 , and when a vertical vibration is generated, the horizontal seismic isolator 40 may be formed to pass through the lower surface of the housing 310 by moving in the vertical direction.

The horizontal seismic part 40 may include a laminated rubber bearing 410 , a fixed plate 420 , a lower plate 430 , an upper plate 440 , and a connection plate 450 .

The laminated rubber bearing 410 serves to prevent horizontal vibration from being transmitted to the object. The laminated rubber bearing 410 may be formed by laminatingly bonding elastic rubber and steel or inserting lead into such a laminated structure. . When the horizontal vibration of the laminated rubber bearing 410 is generated, the laminated rubber bearing 410 is horizontally deformed to prevent the horizontal vibration from being transmitted to the upper structure 2, and Horizontal load amplification can be prevented. In addition, when the horizontal vibration is terminated, the laminated rubber bearing 410 may be restored to a circular shape by its own elastic force.

The fixing plate 420 serves to fix the horizontal seismic part 40 to the ground or the support layer (G). When the vertical vibration occurs, the fixed plate 420 may move the horizontal seismic isolator 40 in the vertical direction as it moves up and down like the ground or the support layer G. In addition, when horizontal vibration is generated, the fixing plate 420 may cause horizontal deformation of the laminated rubber bearing 410 as the fixed plate 420 moves horizontally like the ground or the support layer (G).

The lower plate 430 is provided on the lower side of the laminated rubber bearing 410 to fix the laminated rubber bearing 410 to the fixing plate 420 . Due to the lower plate 430 , the laminated rubber bearing 410 may be horizontally deformed according to the horizontal movement of the fixed plate 420 .

The upper plate 440 is located on the upper side of the laminated rubber bearing 410 and serves to fix the laminated rubber bearing 410 to the connection plate 450 . The upper plate 440 and the connecting plate 450 may be fastened by a fastener 460, and the fastener 460 may be formed of a bolt penetrating the upper plate 440 and the connecting plate 450, but is limited thereto. no.

The connection plate 450 is positioned on the upper surface of the upper plate 440 and may be formed to be connected to the elastic member 320 , the damping unit 340 , and the elastic support 330 . The side surface of the connection plate 450 may be formed to contact the inner surface of the receiving part 312 .

When the vertical vibration is generated, the connection plate 450 may move in the vertical direction as it comes into contact with the inner surface of the receiving part 312 . In addition, when the connection plate 450 is moved in the upward direction, the elastic member 320 may be compressed and the elastic support 330 may be moved in the upward direction. In addition, even if the connection plate 450 is excessively moved in the vertical direction due to vertical vibration, the lower surface of the connection plate 450 is in contact with the bent portion 316 so that the vertical vibration isolation unit 30 is separated from the horizontal vibration isolation unit 40 . can prevent

Hereinafter, the operation of the horizontal-vertical seismic isolator 3 having the above-described configuration and the seismic isolator 1 including the same will be described.

In the horizontal-vertical seismic isolator 3 included in the seismic isolator 1, as the elastic member 320 of the vertical seismic isolator 30 is vertically deformed and vibrates with respect to vertical vibration, the vertical vibration is generated by the upper structure 3 transmission can be prevented. In addition, as the laminated rubber bearing 410 of the horizontal vibration isolation unit 40 is horizontally deformed with respect to the horizontal vibration, it is possible to prevent the horizontal vibration from being transmitted to the upper structure. In this way, the horizontal-to-vertical seismic isolator 1 including the vertical seismic isolator 3 according to an embodiment of the present invention can prevent vertical and horizontal vibrations from being transmitted to the upper structure.

5 is a graph showing the horizontal vibration blocking performance of the horizontal-vertical seismic isolator 3 included in the seismic isolator 1 of the present invention. As shown in FIG. 5 , it can be seen that the horizontal vibration response R1 of the horizontal-vertical seismic isolator 3 of the present invention is greatly reduced than the input earthquake P by the horizontal seismic isolator 40 .

6 is a graph showing the vertical vibration blocking performance of the horizontal-vertical seismic isolator 3 included in the seismic isolator 1 of the present invention. As shown in FIG. 6 , it can be seen that the vertical vibration response R2 of the horizontal-vertical seismic isolator 3 of the present invention is also greatly reduced than the input earthquake P by the vertical seismic isolator 30 . In addition, it can be seen that the frequency of the vertical vibration response (R2) is reduced more efficiently than the frequency of the input earthquake (P).

Although the embodiments of the present invention have been described as specific embodiments, these are merely examples, and the present invention is not limited thereto, and should be construed as having the widest scope according to the technical idea disclosed in the present specification. A person skilled in the art may implement a pattern of a shape not specified by combining/substituting the disclosed embodiments, but this also does not depart from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, and it is clear that such changes or modifications also fall within the scope of the present invention.

1: Seismic isolation equipment 2: Superstructure
3: horizontal-vertical seismic isolator 30: vertical seismic isolator
400: horizontal seismic part 310: housing
312: receiving portion 314: cover
314a: cover body 314b: first fastening part
314c: second fastening part 314d: elastic pressing part
316: bent part 320: elastic member
330: elastic support 340: damping unit
342: damper 344: damper pressing part
344a: connection part 344b: protrusion
344c: rotation shaft 346: damper support
410: laminated rubber bearing 420: fixed plate
430: lower plate 440: upper plate
450: connection plate 460: fixture

Claims (14)

a vertical vibration isolation unit for preventing vertical vibration from being transmitted to the object;
a horizontal seismic isolator connected to a lower side of the vertical seismic isolator and including a laminated rubber bearing for preventing horizontal vibration from being transmitted to the object;
The vertical seismic part
a housing having an open lower surface so that the horizontal seismic portion passes through according to the vertical vibration and having a space therein;
an elastic member positioned in the inner space of the housing and connected to an upper surface of the horizontal seismic unit and an upper inner surface of the housing; and
It is located in the inner space of the housing, and is provided to be connected to the upper surface of the horizontal seismic unit and the upper inner surface of the housing, comprising a damping unit for damping the vibration in the vertical direction of the elastic member,
Horizontal-vertical seismic isolators. The method of claim 1,
The horizontal seismic part
A fixing plate formed to be fixed to the ground or support layer;
a lower plate provided on a lower surface of the laminated rubber bearing and fixed to the fixed plate;
an upper plate provided on an upper surface of the laminated rubber bearing; and
It is located on the upper surface of the upper plate, comprising a connection plate connected to the elastic member and the damping unit,
Horizontal-vertical seismic isolators. 3. The method of claim 2,
the housing is
a accommodating part formed so that upper and lower surfaces are open and receiving the elastic member and the horizontal seismic part; and
and a cover covering the upper surface of the receiving part,
The inner surface of the receiving part is in contact with the side surface of the connection plate,
Horizontal-vertical seismic isolators. 4. The method of claim 3,
the housing is
Formed to be bent inward from the lower side of the accommodating part, further comprising a bent part located below the connection plate,
Horizontal-vertical seismic isolators. 4. The method of claim 3,
the cover is
a cover body connected to the receiving part; and
The cover body further includes an elastic pressing part which protrudes in the direction of the horizontal seismic part from the lower surface of the cover body and is connected to the elastic member and has a groove formed therein;
The vertical seismic part
It is formed extending in the direction of the cover from the upper surface of the connection plate, further comprising an elastic support for supporting the elastic member,
When the horizontal seismic part is moved in the upward direction, the elastic support is inserted into the groove, and the elastic pressing part compresses the elastic member,
Horizontal-vertical seismic isolators. 6. The method of claim 5,
The elastic pressing portion, the elastic member and the elastic support is formed in plurality,
Horizontal-vertical seismic isolators. 4. The method of claim 3,
The attenuation unit is
a damper formed in the vertical direction to damp vibration of the elastic member;
a damper pressing part extending from the cover in the direction of the horizontal seismic isolator, connected to one side of the damper, and rotating the damper according to the vertical movement of the horizontal seismic isolating part;
and a damper support part extending from the horizontal seismic part in the direction of the cover to support the other side of the damper,
One side of the damper is rotatably connected to the damper pressing part,
Horizontal-vertical seismic isolators. 8. The method of claim 7,
The damper pressing part
a connection part having one side connected to the cover;
a protrusion protruding from the other side of the connecting part in the direction of the horizontal seismic part; and
and a rotation shaft connected to one side of the damper through the protrusion,
Horizontal-vertical seismic isolators. superstructure; and
At least one horizontal-vertical seismic isolator positioned below the superstructure,
The horizontal-vertical seismic isolator comprises:
a vertical vibration isolator for preventing vertical vibration from being transmitted to the upper structure; and
and a horizontal seismic isolator connected to a lower side of the vertical seismic isolator and including a laminated rubber bearing for preventing horizontal vibration from being transmitted to the object;
The vertical seismic portion,
a housing having an open lower surface to allow the horizontal seismic part to pass therethrough and having an internal space;
an elastic member positioned in the inner space of the housing and connected to an upper surface of the horizontal seismic unit and an upper inner surface of the housing; and
It is located in the inner space of the housing, and is provided to be connected to the upper surface of the horizontal seismic unit and the upper inner surface of the housing, comprising a damping unit for damping the vibration in the vertical direction of the elastic member,
seismic isolation equipment. 10. The method of claim 9,
The horizontal-vertical seismic isolator is formed in plurality,
seismic isolation equipment. 10. The method of claim 9,
The horizontal seismic part,
A fixing plate formed to be fixed to the ground or support layer;
a lower plate formed on a lower surface of the laminated rubber bearing and fixed to the fixed plate;
an upper plate provided on an upper surface of the laminated rubber bearing; and
It is provided on the lower surface of the upper plate, comprising a connection plate connected to the elastic member and the damping unit,
Horizontal-vertical seismic isolators. 12. The method of claim 11,
The housing is
The upper and lower surfaces are formed to be opened, the receiving portion for accommodating the elastic member and the damping unit; and
and a cover connected to the upper structure and covering the upper surface of the accommodating part,
The inner surface of the receiving portion is in contact with the connection plate,
seismic isolation equipment. 13. The method of claim 12,
the housing is
It is bent inward from the lower side of the accommodating part, further comprising a bent part located below the connection plate,
seismic isolation equipment. 13. The method of claim 12,
the cover is
a cover body connected to the receiving part; and
The cover body further includes an elastic pressing part which protrudes in the direction of the horizontal seismic part from the lower surface of the cover body and is connected to the elastic member and has a groove formed therein;
The vertical seismic part
It is formed extending in the direction of the cover from the upper surface of the connection plate, further comprising an elastic support for supporting the elastic member,
When the horizontal seismic part is moved in the upward direction, the elastic support is inserted into the groove, and the elastic pressing part compresses the elastic member,
seismic isolation equipment.

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