JP7213766B2 - Fixed structure of seismic isolation device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a structure for fixing a seismic isolation device used in structures such as buildings, detached houses, bridges, and the like, and for a seismic isolation structure for machinery, and more particularly to a structure for fixing a seismic isolation device using sliding bearings.

2. Description of the Related Art Conventionally, there is known a seismic isolation device that reduces the seismic force (shock) transmitted to a building or the like by lengthening the period of intense short-period seismic motion when an earthquake occurs. A seismic isolation device is interposed between a building or the like (hereinafter referred to as "upper structure") and a foundation (hereinafter referred to as "lower structure") to form a seismic isolation layer. The seismic isolation system supports the upper structure and is equipped with an isolator that slowly displaces the upper structure in a long period when an earthquake occurs. Isolators include, for example, laminated rubber, sliding bearings, rolling bearings, and elastic sliding bearings that combine laminated rubber and sliding bearings.

In general, a seismic isolation device in which a sliding bearing is applied to an isolator (hereinafter referred to as a “slide bearing type seismic isolation device”) has a sliding material made of a low-friction material such as PTFE (polytetrafluoroethylene). It comprises a bearing main body and a sliding plate made of a stainless steel plate subjected to surface treatment such as polishing and/or coating (see Patent Documents 1 and 2). The bearing body and the slide plate are arranged such that the slide member slidably abuts the slide plate. For example, in Patent Documents 1 and 2, a bearing body is fixed to the lower surface of an upper structure, and a slide plate is fixed to a base as a lower structure at its peripheral edge. A sliding plate is generally fixed to a foundation by fastening members such as bolts.

When sliding bearing type seismic isolation devices are installed, the upper structure slides on the sliding plate via the sliding material, and the sliding material slides on the sliding plate while deforming in the horizontal direction. Absorbs seismic force by frictional force. As a result, the acceleration of shaking when seismic motion acts on the upper structure (so-called response acceleration) is a fraction of the acceleration of the seismic motion, so the upper structure can be protected from earthquakes.

In recent years, as the accumulation of seismic observation records and research on long-period ground motions and earthquakes beneath faults progress, it is necessary to assume larger ground motions than before in building design. An increase in the input level of seismic motion leads to an increase in the response deformation (amplitude) of the seismic isolation layer. It is necessary to improve the file sliding performance (the movable range of the superstructure).

In sliding bearing-type seismic isolation devices, by increasing the size of the sliding plate and expanding the movable range (sliding area) of the main body of the sliding bearing, the structure can be relatively easily supported against the large deformation of a large earthquake. It is possible to deform while moving, and the seismic isolation performance can be improved.

JP 2011-214677 A JP 2016-121747 A

However, in the conventional sliding bearing type seismic isolation device as described above, when long-period, long-time seismic motion beyond conventional assumptions occurs, the sliding plate, which is a stainless steel plate, becomes the sliding material on the bottom surface of the sliding It is assumed that the sliding is repeated with and out, heat is generated at a high temperature, and thermal expansion and deformation occur. As a result, there is a risk that the coefficient of friction will change due to deformation of the sliding surface, or that the sliding of the sliding bearing will be hindered.

Due to the thermal expansion of the sliding plate, stress is concentrated on the fixing members such as bolts that fix the sliding plate to the foundation, and the fixing members such as bolts are damaged, or the stainless steel plate and its reinforcing plate are deformed. As a result, there is a problem that the seismic isolation performance deteriorates.

The object of the present invention is to solve the above-mentioned problems, and it is easy to construct at the time of construction, can follow large deformation when a large earthquake occurs, and long-period and long-time seismic motion occurs. To provide a fixing structure for a seismic isolation device that has high seismic isolation performance even when the structure is fixed.

The fixed structure of the seismic isolation device according to the present invention includes:
A fixed structure for a seismic isolation device disposed between an upper structure and a lower structure for seismic isolation support of the upper structure,
a planar portion provided on the lower structure;
A sliding bearing main body, which is installed on the planar portion and is fixed to the upper structure on the upper sliding surface, is slidably mounted via a sliding member provided at the lower part of the sliding bearing main body. sliding plate,
has
A through hole penetrating in the vertical direction is provided in the outer edge of the sliding plate,
The planar portion is provided with a protruding member that protrudes upward from the planar portion and is arranged in the through hole of the slide plate,
The protruding member is fixed to the planar portion,
a tip surface of the projecting member is disposed in the through hole,
A horizontal gap is provided between the protruding member and the inner peripheral surface of the through hole to allow horizontal movement of the sliding plate with respect to the planar portion.

According to the present invention, a seismic isolation device that is easy to construct during construction, can follow large deformation when a large earthquake occurs, and has high seismic isolation performance even if long-period and long-term seismic motion occurs. A fixed structure can be provided.

1 is an external perspective view showing the configuration of a seismic isolation device according to an embodiment of the present invention; FIG. FIG. 2 is a cross-sectional view for explaining a fixing structure of a seismic isolation device according to an embodiment of the present invention; FIG. 4 is an enlarged cross-sectional view showing the relationship between the slide plate and the foundation provided with the base plate in the seismic isolation device; It is a figure which shows operation|movement of a seismic isolation apparatus.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is an external perspective view showing the configuration of a seismic isolation device 10 according to one embodiment of the present invention, and FIG. 2 is provided for explaining the fixing structure of the seismic isolation device according to one embodiment of the present invention. It is a sectional view. FIG. 3 is an enlarged cross-sectional view showing the relationship between the slide plate and the foundation provided with the base plate in the seismic isolation device.

The seismic isolation device 10 is a slide bearing including a slide bearing main body 20 and a slide plate 30 . The seismic isolation device 10 has a support function and a damping function. In this embodiment, the slide bearing main body 20 is fixed to the building 2 (upper structure), and the slide plate 30 is mounted on the foundation 3 (lower structure) with its horizontal movement restricted. In addition, the upper structure may be a building or a structure as the building 2 .

As shown in FIG. 2, it is provided as part of a seismic isolation system forming a seismic isolation layer between a building 2 as an upper structure and a foundation 3 as a lower structure. The seismic isolation device 10 constitutes a seismically isolated building together with an upper structure and a lower structure.
The seismic isolation device 10 supports a building 2, which is an upper structure, via a foundation, which is a lower structure. The seismic isolation device 10 has a support function of stably supporting the building 2 and a damping function of absorbing seismic energy to reduce shaking of the building 2 . The seismic isolation device 10 is a sliding bearing type seismic isolation device, and the seismic isolation system includes a plurality of seismic isolation devices 10 and a plurality of seismic isolation devices other than the sliding bearing type seismic isolation device. Other seismic isolation devices, for example, may have support functions, damping functions, and restoration functions such as laminated rubber bearings, or devices without support functions such as oil dampers, steel dampers, and lead dampers. may be

<Sliding bearing body 20>
As shown in FIGS. 1 and 2, the slide bearing main body 20 includes a laminated rubber body 21, a slide member 22, and a flange 27. As shown in FIG.

The laminated rubber body 21 has a structure in which rubber-like elastic plates 24 (main rubber) and intermediate steel plates 25 are alternately laminated, and connecting steel plates 23a and 23b are vulcanized and bonded to both upper and lower ends. The laminated rubber body 21 also has a protective rubber 26 excellent in weather resistance that covers the outer peripheral surface of the laminated body (reference numerals omitted) composed of the rubber-like elastic plate 24 and the intermediate steel plate 25 . The laminated rubber body 21 is a columnar member having a square columnar shape, a polygonal columnar shape, or a cylindrical columnar shape. In this embodiment, the laminated rubber body 21 has a columnar shape.

The rubber-like elastic plate 24 is made of a material mainly composed of rubber, such as natural rubber, isoprene rubber, butadiene rubber, styrene-butadiene rubber, ethylene-propylene rubber, butyl rubber, halogenated butyl rubber, chloroprene rubber, and a mixed material of rubber and synthetic resin. formed by The protective rubber 26 may be formed by applying an adhesive to the outer peripheral surface of the laminate and pasting it, or may be formed by winding a self-bonding tape made of rubber. In this embodiment, the protective rubber 26 is integrally formed with the rubber-like elastic plate 24 by simultaneously vulcanizing and molding the rubber material of the rubber-like elastic plate 24 and the protective rubber 26 .

The sliding member 22 is a plate-like member and is made of, for example, a fluorine resin such as PTFE (polytetrafluoroethylene). The sliding material 22 is fixed to the lower surface (connecting steel plate 23b) of the laminated rubber body 21 by, for example, adhesion. The sliding member 22 abuts on a sliding surface member 32 (a mating sliding member) that constitutes the sliding surface of the sliding plate 30 .

The sliding member 22 may be formed in any manner as long as it has a small coefficient of friction and is suitably slidable when it contacts and slides on the sliding surface member 32 . For example, the sliding member 22 may be a single plate member, or may be composed of a plurality of small plate members. In the present embodiment, the sliding member 22 is composed of a disc-shaped single plate. The outer diameter of the sliding material 22 is, for example, 800 mm.

The flange 27 is joined to the upper surface (connecting steel plate 23a) of the laminated rubber body 21 with, for example, bolts. The planar shape of the flange 27 may be any shape such as a rectangular shape, a disk shape, an elliptical shape, or a polygonal shape. In this embodiment, the flange 27 has a disc shape. The flange 27 is fixed to a portion of the building 2, which is the upper structure, facing the foundation. Further, the slide bearing main body 20 may be a rigid slide bearing and may include the slide member 22 and the flange 27 .

<Sliding plate 30>
The sliding plate 30 has a sliding surface member 32 which is a main body of the sliding plate, and a reinforcing plate 34 . The slide plate 30 is detachably mounted on the base plate 4 with its horizontal movement restricted. As a result, if the sliding surface member 32 of the sliding plate 30 is damaged or otherwise damaged, it can be replaced.

The sliding surface member 32 is formed of, for example, a metal plate (eg, stainless steel plate) subjected to surface treatment such as polishing and/or coating. The sliding surface member 32 has a shape larger than the outer shape of the sliding bearing main body 20 . In this embodiment, the sliding surface member 32 has an octagonal shape. The sliding surface member 32 is formed on the reinforcing plate 34 in advance and transported to the construction site in this state.

The sliding surface member 32 may have any shape as long as it is larger than the outer shape of the sliding bearing main body 20, and may be circular, square, polygonal, or any other shape. In addition, the sliding surface 322, which is the surface of the sliding surface material 32, is made of different materials in the central region and the outer peripheral region surrounding the center, so that the respective regions have different coefficients of friction with the sliding member 22. good too.

The reinforcing plate 34 reinforces the sliding surface member 32 from the back side (the surface opposite to the sliding surface 322 ) to ensure the mechanical strength of the sliding surface member 32 . Further, the reinforcing plate 34 can prevent the sliding surface member 32 from being deformed during transportation and construction.
The reinforcing plate 34 fixes the sliding surface member 32 to the foundation side. The reinforcing plate 34 is made of steel and is integrally formed with the sliding surface member 32 by welding or by using a fixing member such as a countersunk head screw. The reinforcing plate 34 has an outer shape equal to or slightly larger than that of the sliding surface member 32 . Note that the reinforcing plate 34 may be formed in a circular shape.

The reinforcing plate 34 has an outer edge portion 342 that protrudes outward from the outer edge of the sliding surface member 32 , and is attached to the base plate 4 by the projecting member 60 via the outer edge portion 342 .
The reinforcing plate 34 has a through hole 70 in the outer edge portion 342, into which the upper portion of the protruding member 60 is loosely fitted.

The through-hole 70 has an inner diameter larger than the outer shape of the protruding member 60 , and the through-hole 70 is formed to have a size that allows the protruding member 60 to be positioned in the center of the through-hole 70 .

<Protruding member 60>
The protruding member 60 protrudes upward from the base plate 4 and detachably holds the slide plate 30 . The protruding member 60 is a shaft-like member provided to protrude from the surface 41 of the base plate 4 . At least the outer diameter of the upper portion (the portion on the other end side) 62 of the protruding member 60 that is arranged in the through hole 70 of the reinforcing plate 34 is smaller than the inner diameter of the through hole 70 .
Also, the protruding member 60 (specifically, the upper portion of the protruding member 60 that protrudes into the through-hole 70 ) is loosely fitted in the through-hole 70 within the through-hole 70 . The end surface 60 a of the protruding member 60 is arranged flush with the sliding surface 322 or below the sliding surface 322 . In this embodiment, the upper portion of the protruding member 60 is arranged in the through hole 70 of the reinforcing plate 34 below the sliding surface member 32 . That is, the protruding member 60 is fixed to the base plate (planar portion) 4 , and the end face (tip end face) 60 a of the protruding member 60 is disposed inside the through hole 70 . In this way, the protruding member 60 does not protrude above the slide surface 322 , that is, toward the slide bearing body 20 , and does not hinder the horizontal movement of the slide bearing body 20 .

In the present embodiment, the projecting member 60 is configured by a headless shaft-shaped bolt, that is, a so-called cut bolt. The threaded bolt of this embodiment has a fitting hole 623 such as a hexagonal hole in the upper portion 62 of the shaft-like body. A jig is fitted into the fitting hole to rotate the protruding member 60 around its axis. The protruding member 60 is provided with a male screw portion that is screwed to the base 3 or the base plate 4 on the outer circumference of at least a lower portion (a portion on the one end side) 64 of the shaft-like body, and is screwed to the base plate 4 by rotating it. ing.

In the present embodiment, the protruding member 60 is configured such that the lower portion 64 is fitted in the fixing hole 80 provided at the position corresponding to the outer edge portion 342 at the four corners of the sliding plate 30 in the base plate 4 so that the upper portion protrudes. are placed.

<Base plate (planar portion) 4>
A slide plate 30 is mounted on the base plate 4, and the base plate 4 is provided integrally with the foundation 3 so that the slide surface of the slide plate 30 can secure a smooth horizontal surface. The base plate 4 is a planar portion in the present invention. In the present embodiment, the base plate 4 is embedded with its upper surface on which the slide plate 30 is placed exposed.

The base plate 4 is plate-shaped in this embodiment, and is configured using a rectangular steel plate. The base plate 4 is configured such that the sliding plate 30 is arranged in the region of the upper surface, and preferably has a shape in which the same region spreads radially from the center in plan view. The shape of the base plate 4 may be formed in any shape of a disk shape, a disk shape, and a polygonal shape including a square shape. Also, a so-called ring plate, which is a plate member having these shapes and has an opening in the center, may be used as the base plate 4 .

The base plate 4 is provided so as to be placed on the semi-dry foundation 3 and embedded and integrated when the foundation 3 is constructed by pouring concrete. When the base plate 4 is a ring plate, the central opening is filled with concrete when the foundation is laid. The surface of the concrete portion within this central portion is formed to be a horizontal smooth surface that is flush with the surface of the ring plate. The ring plate may be configured as a divided body, brought into the site, and joined together by welding or the like to form a ring-shaped ring plate. It may be provided so as to be embedded in the foundation 3 .

The coefficient of friction between the base plate 4 and the reinforcing plate 34 of the slide plate 30 is made larger than the coefficient of friction between the slide member 22 and the slide surface 322, which is the surface of the slide surface member 32 as the slide plate main body. It is configured. As a result, even if a small-scale earthquake occurs, the base plate 4 and the slide plate 30 do not slide, and the slide bearing main body 20 slides on the slide plate 30, so that the building 2, which is the upper structure, can be moved. can be seismically isolated according to the scale of the earthquake.

A fixing hole 80 is provided in the base plate 4 and the foundation 3 so as to be continuous with the through hole 70 of the sliding plate 30 and for fixing the protruding member 60 . In the present embodiment, the projecting member 60 is fixed to the fixing hole 80 so that the upper part of the projecting member 60 projects above the base plate 4 .

The fixing hole 80 is a bolt hole into which a threaded bolt is screwed since the protruding member 60 is a threaded bolt in this embodiment. That is, the inner peripheral wall of at least one of the upper fixing hole 42 of the base plate 4 and the lower fixing hole 3b of the foundation 3 is provided with a female threaded portion into which the male threaded portion of the threaded bolt is screwed. The upper fixing hole 42 is a through hole formed in the base plate 4, and the lower fixing hole 3b of the base 3 is formed by, for example, an embedded nut 3a. In this embodiment, the upper fixing hole 42 and the lower fixing hole 3b are provided with internal threads on their inner peripheral surfaces.

In a configuration in which the base plate 4 is a ring plate, placed on the foundation 3, and concrete is placed in the central opening, the concrete surface generally has a higher coefficient of friction than the steel plate serving as the base plate 4. Therefore, when the sliding plate 30 is installed on the ring plate, the sliding plate 30 can be installed in a less slippery manner than a rectangular base plate without openings.

The through-hole 70 and the protruding member 60 are configured such that a horizontal gap G, which is a gap formed in the horizontal direction, is provided between the through-hole 70 and the protruding member 60 positioned inside the through-hole 70 . ing.

As a result, when the sliding plate 30 receives a force larger than the coefficient of friction of the base plate 4 with respect to the base plate 4 , the sliding plate 30 can horizontally move in the horizontal gap G.

<Operation of seismic isolation device 10>
FIG. 4 is a diagram schematically showing the operation of the seismic isolation device 10 of this embodiment.

Normally, the slide bearing main body 20 is positioned in the central portion of the slide surface member 32 (indicated by solid line 20 in FIG. 4). When an earthquake occurs and horizontal seismic force is applied to the building 2, first, the laminated rubber body 21 (see FIG. 2) of the slide bearing main body 20 undergoes horizontal shear deformation. Then, when the friction limit is exceeded, slippage occurs and the slide bearing body 20 slides on the slide surface 322 of the slide face member 32 (indicated by dashed line 20). Note that the coefficient of friction between the base plate 4 and the slide plate 30 is greater than the coefficient of friction between the slide plate 30 and the slide member 22 . As a result, even if the seismic isolation device 10 receives seismic motion, the sliding plate 30 does not start to slide on the base plate 4, that is, the sliding bearing main body 20 does not move to the sliding plate 30 according to the seismic motion. You can slide against it.

In addition, it is conceivable that the assumed seismic ground motion becomes gigantic, for example, an unexpected large-scale earthquake such as the Nankai Trough earthquake or the Uemachi fault earthquake occurs.
In the fixed structure of the seismic isolation device 10 of the present embodiment, unlike the conventional sliding support type seismic isolation device, there are bolt heads and the like above the sliding plate 30 (specifically, the sliding surface member 32). There is no obstruction that hinders the horizontal movement of the sliding surface material. As a result, even if a large-scale earthquake occurs, the slide bearing main body 20 of the seismic isolation device 10 can slide to a position where it protrudes from the slide plate 30 while being deformed. Further, the slide bearing main body 20 moves back to its original position while being attenuated by the restoring force, thereby attenuating the seismic force.

In this way, the sliding bearing main body 20 deforms and slides on the sliding plate 30, thereby reducing the response acceleration acting on the building 2 to a fraction of the original, and reducing the seismic force acting on the building 2. and protect buildings and structures from earthquakes.

In addition, when a large-scale earthquake occurs due to the assumed increase in seismic motion, slow and large shaking with a long period (long-period seismic motion) occurs.

When long-period vibration occurs in this manner, the slide bearing main body 20 repeats long-period sliding on the sliding plate 30 . As a result, it is conceivable that the sliding surface member 32 generates heat, the heat is transferred to the reinforcing plate 34, and the sliding plate 30 itself becomes hot and thermally expands. In particular, since the sliding surface material 32 is a stainless steel plate and the reinforcing plate 34 is a steel plate, the entire sliding plate heats up due to the long-period vibration, and the entire sliding plate 30 thermally expands. 4 shows the length of the slide plate 30 (reinforcement plate 34) before thermal expansion and the length of the slide plate 30 (reinforcement plate 34) after thermal expansion.

When an earthquake of such an unexpectedly large scale occurs, the slide plate 30 that slides on the slide bearing main body 20 thermally expands, and the slide plate 30 itself may be extended. At this time, in the conventional sliding support type seismic isolation device, stress is concentrated on the bolts that fix the slide plate, and it is conceivable that the bolts may be damaged or the sliding surface of the slide plate may be curved.

However, in the fixing structure of the seismic isolation device 10 of the present embodiment, the slide plate 30 can move horizontally within a predetermined range, that is, within the horizontal gap G, with respect to the base plate 4, unlike the conventional sliding support type seismic isolation device. It is held like this. In other words, the sliding plate 30 is not fixed to the base plate 4 but is provided on the base plate 4 so as to allow deformation of the sliding plate 30 .

That is, even if the slide plate 30 on the base plate 4 is deformed and stretched, the stretch is limited to the horizontal gap G between the bolt as the protruding member 60 and the through hole 70 into which the bolt is inserted. is acceptable. Accordingly, the sliding plate 30 can be maintained horizontally on the base plate 4 without impairing the flatness of the sliding surface 322 due to deformation such as warping of the sliding plate 30 due to the bolt itself. That is, as shown in FIG. 4, the slide plate 30 is preferably maintained on the foundation 3 via the base plate 4 both before and after thermal expansion.

In the present embodiment, the slide plate 30 on which the slide bearing main body 20 slides is attached to the base plate 4 provided on the foundation 3 via the projecting member 60 so as to be horizontally movable within the range of the horizontal gap G. there is Further, since the slide plate 30 is provided on the base plate 4 by the protruding member 60 having no bolt head, it is not constrained in the pull-out direction. Thus, the sliding plate 30 does not need to be attached to the base plate 4 in the drawing direction, and the sliding plate 30 can be easily laid on the base plate 4 .

Moreover, since the protruding member 60 does not protrude upward from the sliding surface 322 of the sliding plate 30, it slides on the sliding surface 322 compared to the conventional seismic isolation device in which the bolt head protrudes upward from the sliding surface. The sliding range of the slide bearing main body 20 can be widened.

Further, since the projecting member 60 is a threaded bolt and can be attached and detached from the base plate 4, it can be easily removed for maintenance of the slide plate 30 such as when the slide surface 322 of the slide plate 30 is damaged. .
Moreover, if an existing seismic isolation device can have a structure similar to that of the present embodiment, the present embodiment can be applied to the fixing structure of the existing seismic isolation device.

That is, in the case of an existing seismic isolation device in which a base plate and a slide plate on the base plate are fixed with bolts through through-holes in the slide plate, a shaft-like member having a diameter smaller than that of the through-holes is used instead of the bolts. It is good also as a fixed structure of the seismic isolation apparatus of this Embodiment by using. By fixing the lower portion 64 of the protruding member 60 to the base plate and locating the upper portion, which is the small diameter portion, in the through hole, the same effects as in the present embodiment can be obtained. As a result, the movable range of the main body of the slide bearing in the slide plate can be easily expanded even for the existing slide bearing type seismic isolation device so as to be able to cope with the scale of the earthquake. Therefore, it is possible to realize a seismic isolation structure that can cope with large deformation of the seismic isolation layer even in repair work of existing buildings.

As described above, according to the present embodiment, it is possible to suppress an increase in the cost of each process of manufacturing, transportation, and construction, facilitate construction at the time of construction, be able to follow large deformation when a large earthquake occurs, and High seismic isolation performance can be achieved even when long-period and long-term seismic motion occurs. In addition, it can be applied to both new construction and seismic retrofitting.

Although the invention made by the inventor of the present invention has been specifically described above based on the embodiments, the present invention is not limited to the above embodiments, and can be changed without departing from the scope of the invention. In this embodiment, the protruding member 60 is a threaded bolt. However, the protruding member 60 is not limited to this, and may protrude from the base plate 4 and be inserted into the through hole of the sliding plate 30 with a horizontal gap G therebetween. Any rod-like member such as a pin may be applied. Moreover, this embodiment may be applied to a building, and thereby the same effects as those described above can be obtained.

It should be considered that the embodiments disclosed this time are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all modifications within the meaning and range of equivalents of the scope of the claims.

2 Buildings (superstructures)
3 Foundation (lower structure)
3a embedded nut 3b lower fixing hole 4 base plate (planar portion)
REFERENCE SIGNS LIST 10 seismic isolation device 20 slide bearing main body 21 laminated rubber body 22 slide member 23a, 23b connecting steel plate 24 rubber-like elastic plate 25 intermediate steel plate 26 protective rubber 27 flange 30 slide plate 32 slide surface member 34 reinforcing plate 42 upper fixing hole 60 protruding member 62 upper part (other end)
64 lower part (one end)
70 through hole 80 fixing hole 322 sliding surface 342 outer edge

Claims (5)

A fixed structure for a seismic isolation device disposed between an upper structure and a lower structure for seismic isolation support of the upper structure,
a planar portion provided on the lower structure;
A sliding bearing main body, which is installed on the planar portion and is fixed to the upper structure on the upper sliding surface, is slidably mounted via a sliding member provided at the lower part of the sliding bearing main body. sliding plate,
has
A through hole penetrating in the vertical direction is provided in the outer edge of the sliding plate,
The planar portion is provided with a protruding member that protrudes upward from the planar portion and is arranged in the through hole of the slide plate,
The protruding member is fixed to the planar portion,
a tip surface of the projecting member is disposed in the through hole,
A horizontal gap is provided between the protruding member and the inner peripheral surface of the through hole to allow horizontal movement of the sliding plate with respect to the planar portion.
Fixed structure of seismic isolation device. The sliding plate is
a slide plate body forming the slide surface on which the slide member slides;
a reinforcing plate integrally fixed to the slide plate body on a surface opposite to the slide surface and having an end projecting from at least a portion of the outer circumference of the slide plate body;
has a
The fixing structure of the seismic isolation device according to claim 1. the edge of the reinforcing plate forms the outer edge;
The fixing structure of the seismic isolation device according to claim 2. a coefficient of friction between the sliding plate and the planar portion is greater than a coefficient of friction between the sliding member and the sliding surface;
A fixing structure for a seismic isolation device according to any one of claims 1 to 3. the substructure is a foundation;
The planar portion is a base plate that is a steel plate provided on the foundation,
The protruding member is a shaft-shaped threaded bolt, and a lower portion of the threaded bolt is fixed to the base plate.
A fixing structure for a seismic isolation device according to any one of claims 1 to 4.

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