JP7182518B2 - Seismic isolation device - Google Patents

Description

The present invention relates to a seismic isolation device.

A conventional seismic isolation device includes a laminated structure having hard material layers and soft material layers alternately laminated in the vertical direction, and the hard material layers are provided on the upper and/or lower end sides of the laminated structure. , which has a larger diameter than other hard material layers arranged axially inward with respect to the hard material layer (for example, Patent Document 1). According to Patent Document 1, with such a configuration, when the seismic isolation device is deformed in the horizontal direction, stress concentration in the vicinity of the flange plate in the laminated structure can be suppressed, and the risk of buckling can be reduced. ing.

JP 2014-47926 A

However, in the above-described seismic isolation device, when the seismic isolation device is deformed in the horizontal direction, in the laminated structure, the outer peripheral side portion of the large-diameter hard material layer and the axially outer side (flange plate side) portion thereof However, there is a risk of warping inward in the axial direction away from the flange plate (hereinafter, also referred to as "turning up").

SUMMARY OF THE INVENTION An object of the present invention is to provide a seismic isolation device capable of suppressing lifting.

The seismic isolation device of the present invention is
a laminated structure having hard material layers and soft material layers alternately laminated in the vertical direction;
an additional member;
A seismic isolation device comprising
The laminated structure has a small-diameter hard material layer, which is the hard material layer, and is adjacent to the small-diameter hard material layer on at least one of its upper and lower ends in the axial direction outside. a large-diameter hard material layer that is the hard material layer having a larger diameter than the small-diameter hard material layer,
The additional member is arranged axially inward with respect to a stepped portion of the large-diameter hard material layer located on the outer peripheral side of the small-diameter hard material layer,
When the seismic isolation device is deformed in the horizontal direction, the additional member is axially deformed with respect to the additional member of the laminated structure by a force applied to the additional member of the laminated structure from a portion on the inner peripheral side of the additional member. It is configured such that the outer portion can be pressed axially outward,
In a state where the seismic isolation device is not deformed in the horizontal direction, the axial thickness of the additional member is maximum at the position of the outer peripheral surface portion of the laminated structure located on the inner peripheral side of the additional member.
According to the seismic isolation device of the present invention, it is possible to suppress curling up.

In the seismic isolation device of the present invention,
In a state in which the seismic isolation device is not deformed in the horizontal direction, it is preferable that the axial thickness of the additional member gradually increases toward the inner peripheral side.
As a result, it is possible to further suppress curling up.

In the seismic isolation device of the present invention,
The laminated structure has a plurality of pairs of the small-diameter hard material layer and the large-diameter hard material layer on at least one end side of an upper side and a lower side thereof,
It is preferable that the additional member is arranged axially inward of at least the stepped portion having the largest radial length among the stepped portions of each of the plurality of pairs.
As a result, it is possible to further suppress curling up.

In the seismic isolation device of the present invention,
The laminated structure has a plurality of pairs of the small-diameter hard material layer and the large-diameter hard material layer on at least one end side of an upper side and a lower side thereof,
It is preferable that each of the plurality of additional members is arranged axially inward with respect to each of the stepped portions of at least two pairs of the plurality of pairs.
As a result, it is possible to further suppress curling up.

In the seismic isolation device of the present invention,
It is preferable that the plurality of additional members arranged axially inward with respect to the stepped portion having a longer radial length have a larger area in the axial cross section.
As a result, it is possible to further suppress curling up.

In the seismic isolation device of the present invention,
It is preferable that the plurality of additional members are arranged more inward in the axial direction with respect to the stepped portion having the longer radial length, and have higher hardness.
As a result, it is possible to further suppress curling up.

In the seismic isolation device of the present invention,
The additional member is
constructed from an incompressible material and/or
It is preferable that the soft material layer is made of a material having a hardness higher than that of the soft material forming the soft material layer.
As a result, it is possible to further suppress curling up.

In the seismic isolation device of the present invention,
The additional member may be made of a material having hardness lower than that of the soft material forming the soft material layer.
In this case, seismic isolation performance can be improved.

ADVANTAGE OF THE INVENTION According to this invention, the seismic isolation apparatus which can suppress a turn-up can be provided.

1 is an axial cross-sectional view showing a seismic isolation device according to an embodiment of the present invention in a state in which horizontal deformation has not occurred; FIG. 2 is an axial cross-sectional view showing an enlarged part of the seismic isolation device of FIG. 1; FIG. 2 is an axial cross-sectional view showing the seismic isolation device of FIG. 1 in a state of horizontal deformation; FIG. FIG. 2 is a perspective view showing the seismic isolation device of FIG. 1 in a state in which horizontal deformation has not occurred; FIG. 11 is a perspective view showing the seismic isolation device according to the first modified example of the present invention in a state in which horizontal deformation has not occurred. FIG. 11 is an axial cross-sectional view showing part of a seismic isolation device according to a second modification of the invention in a state in which horizontal deformation has not occurred. FIG. 11 is an axial cross-sectional view showing part of a seismic isolation device according to a third modification of the present invention in a state in which horizontal deformation has not occurred; FIG. 11 is an axial cross-sectional view showing part of a seismic isolation device according to a fourth modification of the present invention in a state in which horizontal deformation has not occurred. FIG. 11 is an axial cross-sectional view showing part of a seismic isolation device according to a fifth modification of the present invention in a state in which horizontal deformation has not occurred. FIG. 11 is an axial cross-sectional view showing a seismic isolation device according to a sixth modification of the present invention in a state in which horizontal deformation has not occurred; FIG. 11 is an axial cross-sectional view showing a seismic isolation device according to a seventh modification of the present invention in a state in which horizontal deformation has not occurred; FIG. 11 is an axial cross-sectional view showing a portion of a seismic isolation device according to an eighth modification of the present invention in a state in which horizontal deformation has not occurred; FIG. 13 is an axial cross-sectional view showing part of the seismic isolation device of FIG. 12 in a state of horizontal deformation; FIG. 20 is an axial cross-sectional view showing part of a seismic isolation device according to a ninth modification of the present invention in a state in which horizontal deformation has not occurred. FIG. 21 is an axial cross-sectional view showing a portion of a seismic isolation device according to a tenth modification of the present invention in a state in which horizontal deformation has not occurred.

The seismic isolation device of the present invention is designed to suppress the transmission of earthquake vibrations to structures (for example, buildings such as buildings, condominiums, detached houses, warehouses, bridges, etc.). It is preferred when placed between structures.
An embodiment of a seismic isolation device according to the present invention will be exemplified below with reference to the drawings. The same reference numerals are given to common components in each figure.

1 to 4 are drawings for explaining a seismic isolation device 1 according to one embodiment of the present invention. FIG. 1 is an axial cross-sectional view showing a seismic isolation device 1 according to this embodiment in a state in which horizontal deformation has not occurred. FIG. 2 is an axial cross-sectional view showing an enlarged part of the seismic isolation device 1 of FIG. FIG. 3 is an axial cross-sectional view showing the seismic isolation device 1 of FIG. 1 in a state of horizontal deformation. FIG. 4 is a perspective view showing the seismic isolation device 1 of FIG. 1 in a state in which horizontal deformation has not occurred.
As shown in FIG. 1, the seismic isolation device 1 of this embodiment includes a pair of upper and lower flange plates 21 and 22 (hereinafter also referred to as "upper flange plate 21" and "lower flange plate 22", respectively), and a laminated plate. It comprises a structure 3 and one or more additional members 7 .

In this specification, the “central axis O” of the seismic isolation device 1 (hereinafter also simply referred to as the “central axis O”) is the central axis of the laminated structure 3 . A central axis O of the seismic isolation device 1 is oriented so as to extend in the vertical direction. In this specification, the “axial direction” of the seismic isolation device 1 is a direction parallel to the central axis O of the seismic isolation device 1 . The “axial direction inner side” of the seismic isolation device 1 refers to the side close to the axial direction center of the laminated structure 3, and the “axial direction outer side” of the seismic isolation device 1 refers to the axial direction center of the laminated structure 3. , the side farther from (the side closer to the flange plates 21, 22). Further, the “perpendicular direction” of the seismic isolation device 1 is a direction perpendicular to the axial direction of the seismic isolation device 1 . The terms "inner peripheral side", "outer peripheral side", "radial direction", and "circumferential direction" of the seismic isolation device 1 refer to "inner peripheral side", They refer to "peripheral side", "radial direction", and "circumferential direction" respectively. "Upper" and "lower" refer to "upper" and "lower" in the vertical direction, respectively.

The upper flange plate 21 has a structure (for example, buildings such as buildings, condominiums, detached houses, and warehouses, and bridges, etc.) superstructures (building bodies, etc.) placed on the upper flange plate 21. It is configured to be connected to the superstructure. The lower flange plate 22 is arranged below the upper flange plate 21 and configured to be connected to the lower structure (foundation, etc.) of the structure. The upper flange plate 21 and the lower flange plate 22 are preferably constructed of metal, more preferably steel. In this embodiment, the upper flange plate 21 and the lower flange plate 22 have a circular outer edge shape in cross section perpendicular to the axis (FIG. 4). However, the upper flange plate 21 and the lower flange plate 22 may have any outer edge shape such as a polygonal shape (such as a square shape) in the axial cross section.

The laminated structure 3 is arranged between the upper flange plate 21 and the lower flange plate 22 . The laminated structure 3 has a plurality of hard material layers 4 , a plurality of soft material layers 5 and a covering layer 6 . The hard material layers 4 and the soft material layers 5 are alternately laminated in the vertical direction. Each hard material layer 4 and each soft material layer 5 are arranged coaxially. Located on O. Soft material layers 5 are arranged at both upper and lower ends of the laminated structure 3 . A pair of soft material layers 5 arranged at both upper and lower ends of the laminated structure 3 are fixed to the upper flange plate 21 and the lower flange plate 22, respectively.

The hard material layer 4 is made of a hard material. As the hard material forming the hard material layer 4, metal is preferable, and steel is more preferable. Preferably, the axial spacing between the hard material layers 4 is uniform (constant), as in the example of FIG. Here, "the axial distance between the hard material layers 4" refers to the axial distance between the axial centers of a pair of hard material layers 4 adjacent to each other. Also, as in the example of FIG. 1, it is preferable that the hard material layers 4 have the same thickness.
The soft material layer 5 is made of a soft material having a lower hardness (softer) than the hard material layer 4 . As the soft material forming the soft material layer 5, an elastic body is preferable, and rubber is more preferable. Natural rubber or synthetic rubber (such as high damping rubber) is suitable as the rubber that can constitute the soft material layer 5 . Preferably, the thickness of each soft material layer 5 is the same as in the example of FIG.

The coating layer 6 covers the outer surfaces of the hard material layer 4 and the soft material layer 5 . The material forming the coating layer 6 is preferably an elastic body, more preferably rubber. The material forming the coating layer 6 may be the same as the soft material forming the soft material layer 5 or may be different from the soft material forming the soft material layer 5 .
The covering layer 6 is configured integrally with the soft material layer 5 .
In the present embodiment, the coating layer 6 covers the entire outer surface of the hard material layer 4 and the soft material layer 5 , and thus constitutes the entire outer surface of the laminated structure 3 . . However, the coating layer 6 may cover only a part of the outer peripheral surface of the hard material layer 4 and the soft material layer 5, and thus constitute only a part of the outer peripheral surface of the laminated structure 3. may be For example, as in the modified example shown in FIG. 15, the coating layer 6 is the inner surface in the axial direction of the stepped portion 4LM of the large-diameter hard material layer 4L among the outer peripheral surfaces of the hard material layer 4 and the soft material layer 5. may cover only Alternatively, the coating layer 6 may cover only the outer peripheral surfaces of the hard material layer 4 and the soft material layer 5 among the outer peripheral surfaces of the hard material layer 4 and the soft material layer 5 . In addition, the coating layer 6 may not be provided, in which case the outer peripheral surface of the laminated structure 3 is composed only of the outer peripheral surfaces of the hard material layer 4 and the soft material layer 5 .
In the present embodiment, the surface of the laminated structure 3 on the outer peripheral side is formed by the outer peripheral surface of the laminated structure 3 facing the outer peripheral side and the stepped surface 34 (FIG. 1) facing inward in the axial direction. Become.

In this embodiment, the hard material layer 4, the soft material layer 5, and the coating layer 6 each have a circular outer edge shape in the cross section perpendicular to the axis (FIG. 4). However, the hard material layer 4, the soft material layer 5, and the coating layer 6 may each have any non-circular outer edge shape such as a polygonal shape (such as a square) in the cross section perpendicular to the axis.
In this specification, the "outer diameter" of each of the laminated structure 3, the hard material layer 4, the soft material layer 5, and the coating layer 6 means that they have a non-circular outer edge shape in a cross section perpendicular to the axis. If so, it refers to the diameter of these circumscribed circles in the axial section.

As shown in FIG. 1, in the present embodiment, the laminated structure 3 has a hard material layer on at least one of its upper and lower sides (both in the examples of FIGS. 1 and 2). 4 and a large hard material layer 4 adjacent to the small-diameter hard material layer 4S in the axial direction and having a larger diameter (that is, a larger outer diameter) than the small-diameter hard material layer 4S. and a diameter hard material layer 4L. In the example of FIGS. 1 and 2, the laminated structure 3 has one small-diameter hard material layer 4S and one large-diameter hard material layer 4L adjacent to each other on both the upper and lower end sides thereof. has one pair 4P consisting of One pair 4P consists of one small-diameter hard material layer 4S and one large-diameter hard material layer 4L adjacent to each other. The hard material layers 4 do not constitute the pair 4P (that is, when focusing on the one pair 4P, each hard material layer 4 other than the small-diameter hard-material layer 4S and the large-diameter hard-material layer 4L is, for example, Even if they have the same diameter as the small-diameter hard material layer 4S or the large-diameter hard material layer 4L, they are not called the small-diameter hard material layer 4S or the large-diameter hard material layer 4L).
In the present embodiment, the small-diameter hard material layer 4S is located axially outside the center of the laminated structure 3 in the axial direction. The hard material layers 4 located axially inward of the small-diameter hard material layers 4S each have the same diameter (that is, the same outer diameter) as the small-diameter hard material layers 4S. The large-diameter hard material layer 4L is not the hard material layer 4 positioned furthest in the axial direction among the plurality of hard material layers 4 constituting the laminated structure 3, but the hard material layer positioned axially inner than the hard material layer 4. 4. The hard material layers 4 located axially outside the large-diameter hard material layer 4L have the same diameter (that is, the same outer diameter) as the large-diameter hard material layer 4L. However, the large-diameter hard material layer 4</b>L may be the hard material layer 4 positioned most outward in the axial direction among the plurality of hard material layers 4 forming the laminated structure 3 .
In this specification, a portion 4LM of the large-diameter hard material layer 4L, which is located on the outer peripheral side of the small-diameter hard material layer 4S, is referred to as a "stepped portion (4LM)."

The laminated structure 3 has a stepped surface 34 that is an outer surface facing inward in the axial direction, on the inner side in the axial direction with respect to the stepped portion 4LM of the large-diameter hard material layer 4L. In the present embodiment, the stepped portion 4LM of the large-diameter hard material layer 4L is covered on the inner side in the axial direction with the coating layer 6, and the coating layer 6 forms a stepped surface 34 (FIG. 2). .
However, the stepped portion 4LM of the large-diameter hard material layer 4L does not have to be covered with the coating layer 6 . In that case, for example, the stepped portion 4LM of the large-diameter hard material layer 4L has a part or all of its axially inner surface exposed to the outside, and the surface of the stepped portion 4LM exposed to the outside causes the stepped portion 4LM to be exposed to the outside. A surface 34 may be configured.
In the example of FIGS. 1 and 2, the step surface 34 extends in the axial direction. However, in an axial cross-sectional view, the step surface 34 may extend linearly or curvedly in a direction that intersects the direction perpendicular to the axis. In this case, it is preferable that the step surface 34 extends gradually inward in the axial direction toward the inner peripheral side.
In the example of FIGS. 1 and 2, the outer peripheral surface portion of the laminated structure 3 extending axially outward from the outer peripheral end of the stepped surface 34 extends axially. However, in an axial cross-sectional view, the outer peripheral surface portion of the laminated structure 3 extending axially outward from the outer peripheral end of the stepped surface 34 is straight or curved in a direction intersecting the axial direction. May be extended. In that case, it is preferable that the outer peripheral surface portion of the laminated structure 3 extending axially outward from the outer peripheral end of the stepped surface 34 gradually extends outward in the axial direction toward the outer peripheral side. is.
1 and 2, the outer peripheral surface portion 33 of the laminated structure 3 extending axially inward from the inner peripheral end of the stepped surface 34 extends axially. However, in an axial cross-sectional view, the outer peripheral surface portion 33 of the laminated structure 3 extending axially inward from the inner peripheral end of the stepped surface 34 is straight or curved in a direction intersecting the axial direction. may extend to In this case, the outer peripheral surface portion 33 of the laminated structure 3 extending axially inward from the inner peripheral end of the stepped surface 34 gradually extends toward the inner peripheral side as it extends axially inward. and is preferred.

The additional member 7 is arranged axially inside the stepped portion 4LM of the large-diameter hard material layer 4L. In the example of FIGS. 1 and 2, the additional member 7 is provided on the stepped surface 34 located inside the stepped portion 4LM of the large-diameter hard material layer 4L in the axial direction. It is arranged axially inward and is in contact with the step surface 34 . 1 and 2, the additional member 7 radially faces the outer peripheral surface portion 33 of the laminated structure 3 extending axially inward from the inner peripheral end of the stepped surface 34. We are in contact with each other.
In a state where the seismic isolation device 1 is not deformed in the horizontal direction, the axial thickness T (FIG. 2) of the additional member 7 is the position of the outer peripheral surface portion 33 of the laminated structure located on the inner peripheral side of the additional member 7. (radial position). In other words, the portion of the additional member 7 where the thickness T in the axial direction is maximum is located on the outer peripheral surface portion 33 of the laminated structure located on the inner peripheral side of the additional member 7 . Regarding the thickness T of the additional member 7 in the axial direction, "the maximum at the position of the outer peripheral surface portion 33 of the laminated structure located on the inner peripheral side of the additional member 7" means only the position of the outer peripheral surface portion 33. In addition to the position of the outer peripheral surface portion 33, it is also maximized at a position on the outer peripheral side of the outer peripheral surface portion 33 (i.e., the axial thickness at the position of the outer peripheral surface portion 33 A location having the same axial thickness T as the length T is also located on the outer peripheral side of the outer peripheral surface portion 33).
When the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 is axially aligned with the additional member 7 of the laminated structure 3 due to the force applied from the portion 31 on the inner peripheral side of the additional member 7 of the laminated structure 3 . It is configured such that the direction outer portion 32 can be pressed axially outward. More specifically, as shown in FIG. 3, in the present embodiment, when the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 of the laminated structure 3 is partially deformed in the circumferential direction. The circumferential portion 31 falls (in other words, approaches) toward the additional member 7 and presses the additional member 7 radially outward. Then, the additional member 7 presses the portion 32 of the laminated structure 3 axially outside the additional member 7 axially outward. In this way, the additional member 7 transmits the force applied from the inner peripheral side portion 31 of the additional member 7 of the laminated structure 3 to the axially outer portion 32 of the laminated structure 3 with respect to the additional member 7 . acts like As a result, the portion 32 of the laminated structure 3 on the axially outer side of the additional member 7 is pressed axially outward (toward the flange plates 21 and 22).

The effects of the seismic isolation device 1 of this embodiment will be described below.
First, in the seismic isolation device 1 of the present embodiment, as described above, the laminated structure 3 has an edge on at least one of its upper and lower sides (both in the example of FIGS. 1 and 2). , a small-diameter hard material layer 4S that is the hard material layer 4, and a large-diameter hard material layer that is the hard material layer 4 that is adjacent to the small-diameter hard material layer 4S on the outer side in the axial direction and has a larger diameter than the small-diameter hard material layer 4S. 4L and. As a result, compared to the case where all the hard material layers 4 of the laminated structure 3 have the same diameter as the small-diameter hard material layer 4S, the hard material layers 4 are arranged in the axial direction when the seismic isolation device 1 is horizontally deformed. In addition, since the laminated structure 3 is supported more firmly in the axial direction, the seismic isolation device 1 is less likely to buckle (in other words, the buckling resistance of the seismic isolation device 1 can be improved. ). Moreover, compared with the case where all the hard material layers 4 of the laminated structure 3 have the same diameter as the large-diameter hard material layer 4L, the seismic isolation performance of the seismic isolation device 1 can be improved.
Here, if the seismic isolation device 1 does not have the additional member 7, there is nothing inside the stepped portion 4LM of the large-diameter hard material layer 4L in the axial direction to suppress the warping deformation of the stepped portion 4LM. Therefore, when the seismic isolation device 1 is deformed in the horizontal direction, the stepped portion 4LM of the large-diameter hard material layer 4L and the portion 32 axially outward therefrom in the laminated structure 3 are axially inward. The acting repulsive force may warp (turn up) inward in the axial direction away from the flange plates 21 , 22 . As a result, for example, the soft material layer 5 may be fatigued or damaged in the stepped portion 4LM and the axially outer portion 32 thereof.
On the other hand, in the present embodiment, as described above, the additional member 7 is arranged inside the step portion 4LM of the large-diameter hard material layer 4L in the axial direction. When the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 of the laminated structure 3 is deformed by the force applied to the additional member 7 of the laminated structure 3 from the portion 31 on the inner peripheral side. It is configured such that the portion 32 on the outer side in the axial direction can be pressed outward in the axial direction. As a result, when the seismic isolation device 1 is deformed in the horizontal direction, it is possible to suppress the stepped portion 4LM of the large-diameter hard material layer 4L and the portion 32 axially outward thereof from being turned up. Therefore, it is possible to reduce the risk of fatigue or damage to the soft material layer 5 at the stepped portion 4LM and the axially outer portion 32, thereby improving the durability of the seismic isolation device 1.
Further, in the present embodiment, as described above, when the seismic isolation device 1 is not deformed in the horizontal direction, the axial thickness T (FIG. 2) of the additional member 7 is located on the inner peripheral side of the additional member 7. It is maximum at the position of the outer peripheral surface portion 33 of the laminated structure 3 where the As a result, immediately after the seismic isolation device 1 starts to deform in the horizontal direction, the additional member 7 receives the force applied from the portion 31 on the inner peripheral side of the additional member 7 of the laminated structure 3 to It can be transmitted to the portion 32 axially outside the additional member 7 . Therefore, it is possible to effectively suppress curling up.

It should be noted that the additional member 7 in each example described in this specification, including each modified example described below, is attached to the additional member 7 of the laminated structure 3 when the seismic isolation device 1 is deformed in the horizontal direction. On the other hand, the force applied from the inner peripheral side portion 31 is configured to press the axially outer portion 32 of the laminated structure 3 against the additional member 7 axially outwardly. In a state where no horizontal deformation occurs, the axial thickness T of the additional member 7 is maximum at the position of the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 .

The additional member 7 may be made of any material.
For example, it is suitable if the additional member 7 is made of an incompressible material. In this case, when the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 more effectively absorbs the force applied to the additional member 7 from the inner peripheral side portion 31 of the laminated structure 3 . Of these, it becomes easier to transmit to the axially outer portion 32 with respect to the additional member 7, so that it is possible to further suppress curling up. Examples of the incompressible material that can constitute the additional member 7 include rubber and the like. Natural rubber or synthetic rubber (such as high damping rubber) is preferable as the rubber that can constitute the additional member 7 .
And/or it is preferable that the additional member 7 is made of a material having hardness equal to or higher than the hardness of the material (soft material) forming the soft material layer 5 . In this case, when the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 makes it easier to more effectively transmit the force applied from the inner peripheral side portion 31 to the additional member 7 of the laminated structure 3 to the axially outer portion 32 of the laminated structure 3 with respect to the additional member 7. Therefore, it is possible to further suppress curling up. In this case, examples of the material that constitutes the additional member 7 include elastic bodies, plastics, metals, wood, etc., with elastic bodies being preferred, and rubber being more preferred. Natural rubber or synthetic rubber (such as high damping rubber) is preferable as the rubber that can constitute the additional member 7 . From the same point of view, it is more preferable for the additional member 7 to be made of a material having hardness higher than that of the soft material forming the soft material layer 5 .
In this specification, the "hardness" of the additional member 7, the soft material layer 5, the hard material layer 4, and the like specifically means that the additional member 7, the soft material layer 5, the hard material layer 4, and the like respectively constitute When one longitudinal end of a rectangular parallelepiped sample piece made of material of 10 mm long × 10 mm wide × 5 mm thick is fixed, the thickness of the sample piece is 1% ( The load (external force) required to give a displacement of 0.05mm) shall be evaluated. The larger the load (external force), the higher (harder) the "hardness".
Therefore, in other words, from the viewpoint of suppressing the curling up, one end in the longitudinal direction of the first rectangular parallelepiped sample piece of 10 mm long x 10 mm wide x 5 mm thick made of the material constituting the additional member 7 was fixed. Sometimes, the load (external force) required to give a displacement of 1% (0.05 mm) of the thickness of the first sample piece in the thickness direction to the other longitudinal end of the first sample piece constitutes the soft material layer 5 When fixing one longitudinal end of the second sample piece of a rectangular parallelepiped of 10 mm long × 10 mm wide × 5 mm thick made of a material that It is preferably the same or larger than the load (external force) required to give a displacement of 1% of the thickness (0.05 mm), and more preferably larger.
In the above case, the additional member 7 may be made of the same material as the soft material forming the soft material layer 5, or may be made of a different material. Further, the additional member 7 may be made of the same material as the material forming the coating layer 6, or may be made of a different material.

However, the additional member 7 may be made of a material having hardness lower than that of the soft material forming the soft material layer 5 . In other words, when one longitudinal end of a rectangular parallelepiped first sample piece of 10 mm long×10 mm wide×5 mm thick made of the material constituting the additional member 7 is fixed, the other longitudinal end of the first sample piece The load (external force) required to give a displacement of 1% (0.05 mm) of the thickness of the first sample piece in the thickness direction is a rectangular parallelepiped of 10 mm long × 10 mm wide × 5 mm thick made of the material constituting the soft material layer 5. Required to give a displacement of 1% (0.05 mm) of the thickness of the second sample piece in the thickness direction to the other longitudinal end of the second sample piece when one longitudinal end of the second sample piece is fixed It may be smaller than the load (external force). In this case, the seismic isolation performance of the seismic isolation device 1 can be improved compared to the case where the additional member 7 is made of a material having a hardness higher than that of the soft material forming the soft material layer 5 . In this case, the material forming the additional member 7 is preferably an elastic body, more preferably rubber.

Alternatively, the additional member 7 may be made of a material having hardness greater than (or higher than) the hardness of the hard material forming the hard material layer 4 . In other words, when one longitudinal end of a rectangular parallelepiped first sample piece of 10 mm long×10 mm wide×5 mm thick made of the material constituting the additional member 7 is fixed, the other longitudinal end of the first sample piece The load (external force) required to give a displacement of 1% (0.05 mm) of the thickness of the first sample piece in the thickness direction is a rectangular parallelepiped of 10 mm long x 10 mm wide x 5 mm thick made of the material constituting the hard material layer 4. Required to give a displacement of 1% (0.05 mm) of the thickness of the third sample piece in the thickness direction to the other longitudinal end of the third sample piece when one longitudinal end of the third sample piece is fixed It may be the same or larger than the load (external force). In this case, curling up can be further suppressed. In this case, examples of materials that constitute the additional member 7 include elastic bodies, plastics, metals, and wood. Rubber is an example of an elastic material that can form the additional member 7 .
However, from the viewpoint of seismic isolation performance, etc., it is preferable that the additional member 7 is made of a material having a hardness lower than that of the hard material forming the hard material layer 4 . That is, when one longitudinal end of a rectangular parallelepiped first sample piece of 10 mm long, 10 mm wide, and 5 mm thick made of the material constituting the additional member 7 is fixed, the thickness of the other longitudinal end of the first sample piece is The load (external force) required to give a displacement of 1% (0.05 mm) of the thickness of the first sample piece in the direction of the The load required to apply a displacement of 1% (0.05 mm) of the thickness of the third sample piece in the thickness direction to the other longitudinal end of the third sample piece when one longitudinal end of the third sample piece is fixed. (external force), it is preferable that it is small.
Similarly, the additional member 7 may be made of metal, as described above. In this case, curling up can be further suppressed. However, from the viewpoint of seismic isolation performance, etc., it is preferable that the additional member 7 is made of a material (such as rubber) that is softer than metal.

The additional member 7 may be configured integrally with the laminated structure 3 . For example, the additional member 7 may be formed integrally with the laminated structure 3 by being vulcanized together with the laminated structure 3 when the seismic isolation device 1 is manufactured.
Alternatively, the additional member 7 may be configured separately from the laminated structure 3 . In this case, the additional member 7 is fixed to the outer peripheral surface of the laminated structure 3 (specifically, the step surface 34 and/or the outer peripheral surface portion 33 of the laminated structure 3) with an adhesive. may Alternatively, the additional member 7 is not fixed to the outer peripheral surface of the laminated structure 3, but simply attached to the outer peripheral surface of the laminated structure 3 (specifically, the stepped surface 34 and/or the laminated structure 3). 3 may be arranged on the outer peripheral surface portion 33) of . When the additional member 7 is configured separately from the laminated structure 3 , the seismic isolation device 1 can be manufactured more easily than when the additional member 7 is configured integrally with the laminated structure 3 .

In this embodiment, the additional member 7 extends along the entire circumference in the circumferential direction, that is, is configured in an annular shape (FIG. 4). In this case, even if the horizontal deformation of the seismic isolation device 1 occurs in any radial direction, it is possible to suppress the lifting up to the same extent.
However, as in the first modification shown in FIG. 5, the additional member 7 may be discontinuous at one point in the circumferential direction, that is, may be configured in a C shape. In this case, for example, when the additional member 7 is configured separately from the laminated structure 3, the additional member 7 can be easily wrapped around the laminated structure 3 by winding it around the laminated structure 3. can be placed. In this case, it is preferable that the additional member 7 is arranged over the entire circumferential direction by keeping the circumferential ends of the additional member 7 in contact with each other. In this case, even if the horizontal deformation of the seismic isolation device 1 occurs in any radial direction, it is possible to suppress the lifting up to the same degree. However, the additional member 7 may be arranged only partially in the circumferential direction. Even in this case, when horizontal deformation occurs toward the circumferential position where the additional member 7 is arranged, it is possible to suppress the curling up.
Alternatively, the additional member 7 may be discontinuous at multiple points in the circumferential direction. Also in this case, for example, when the additional member 7 is configured separately from the laminated structure 3 , the additional member 7 can be easily arranged around the laminated structure 3 . In addition, the case where the additional members 7 are discontinuous at a plurality of locations in the circumferential direction refers to the case where the plurality of additional members 7 are arranged along the circumferential direction. In this case, the circumferential ends of the plurality of additional members 7 are brought into contact with each other, so that when the plurality of additional members 7 are viewed as one additional member 7, the additional member 7 can be viewed as one additional member 7 in the circumferential direction. It is preferred if they are arranged all over. In this case, even if the horizontal deformation of the seismic isolation device 1 occurs in any radial direction, it is possible to suppress the lifting up to the same degree. However, since the plurality of additional members 7 are spaced apart from each other in the circumferential direction, when the plurality of additional members 7 are viewed as one additional member 7, the additional member 7 is circumferentially spaced. It may be arranged over only part of the direction. Even in this case, when horizontal deformation occurs toward the circumferential position where the additional member 7 is arranged, it is possible to suppress the curling up.

In each example described in this specification, the axial thickness T (FIG. 2) of the additional member 7 is located on the inner peripheral side of the additional member 7 when the seismic isolation device 1 is not deformed in the horizontal direction. The shape of the additional member 7 in the cross section in the axial direction may be arbitrary as long as it is maximum at the position of the outer peripheral surface portion 33 of the laminated structure 3 . 2 and 6 to 9, in a state in which the seismic isolation device 1 is not deformed in the horizontal direction, the thickness T of the additional member 7 in the axial direction is The shape of the additional member 7 in the axial cross-section, which is maximum at the position of the outer peripheral surface portion 33 of the laminated structure 3, will be described by way of example. FIGS. 2 and 6 to 9 show a part (lower and outer peripheral part) of the seismic isolation device 1 according to different examples, respectively, in a state where the seismic isolation device 1 is not deformed in the horizontal direction. showing.

In the example of FIG. 2, the additional member 7 has a triangular shape in the axial cross section. The inner peripheral surface of the additional member 7 is in contact with the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 and extends in the axial direction. The axially outer surface of the additional member 7 is in contact with the stepped surface 34 and extends in the axial direction. The surface of the additional member 7 on the outer peripheral side extends in a straight line so as to gradually move toward the inner peripheral side as it goes inward in the axial direction.

In the second modification shown in FIG. 6, the additional member 7 has a substantially triangular shape in the axial cross section. The inner peripheral surface of the additional member 7 is in contact with the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 and extends in the axial direction. The axially outer surface of the additional member 7 is in contact with the stepped surface 34 and extends in the axial direction. The axially inner surface of the additional member 7 extends along a curved line protruding axially inward so as to gradually move inward as it extends axially inward. Although not shown, the axially inner surface of the additional member 7 extends along a curved line protruding axially outward so as to gradually move toward the inner peripheral side as it goes axially inward. may exist.

In the third modification shown in FIG. 7, the additional member 7 has a triangular shape in the axial cross section. The inner peripheral surface of the additional member 7 is in contact with the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 and extends in the axial direction. The axially outer surface of the additional member 7 does not contact the stepped surface 34 , except for the inner peripheral end thereof, and is spaced axially inwardly of the stepped surface 34 . The inner peripheral end of the axially outer surface of the additional member 7 is in point contact with the stepped surface 34 . Further, the axially outer surface of the additional member 7 extends linearly so as to gradually move toward the outer peripheral side toward the axially inner side. However, the axially outer surface of the additional member 7 extends along a curved line protruding axially outwardly or axially inwardly so as to gradually move toward the outer peripheral side as it extends axially inwardly. may The axially inner surface of the additional member 7 extends linearly so as to gradually move toward the inner peripheral side as it goes axially inward. However, the axially inner surface of the additional member 7 extends along a curved line protruding axially outwardly or axially inward so as to gradually move toward the inner peripheral side as it goes axially inward. may be

In the fourth modification shown in FIG. 8, the additional member 7 has a side surface 7a extending in the axial direction and facing the outer peripheral side in the axial cross section. A portion of the additional member 7 on the outer peripheral side of the side surface 7a and a portion of the additional member 7 on the inner peripheral side of the side surface 7a each have a constant (uniform) thickness T in the axial direction. A portion of the additional member 7 on the outer peripheral side of the side surface 7a has an axial thickness T smaller than a portion of the additional member 7 on the inner peripheral side of the side surface 7a. The inner peripheral surface of the additional member 7 is in contact with the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 and extends in the axial direction. The axially outer surface of the additional member 7 is in contact with the stepped surface 34 and extends in the axial direction.

In the fifth modification shown in FIG. 9, the additional member 7 has a rectangular cross section in the axial direction. The inner peripheral surface of the additional member 7 is in contact with the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 and extends in the axial direction. The axially outer surface of the additional member 7 is in contact with the stepped surface 34 and extends in the axial direction. A surface on the outer peripheral side of the additional member 7 extends in the axial direction. The axial inner surface of the additional member 7 extends in the axial direction.

In each example described in this specification, when the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 extends in a direction intersecting the axial direction, the additional member The inner peripheral surface of 7 may also contact the outer peripheral surface portion 33 and extend along the extending direction of the outer peripheral surface portion 33 . In this case, the axial thickness T of the additional member 7 is maximized at at least a portion of the radial position of the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 .
Further, in each example described in this specification, when the additional member 7 is in contact with the stepped surface 34 as in the examples of FIGS. When extending in a direction intersecting the vertical direction, the axially outer surface of the additional member 7 is in contact with the stepped surface 34 and extends along the extending direction of the stepped surface 34. good too.
In addition, in each example described in this specification, the additional member 7 does not have to be in contact with the step surface 34 .

In each example described in this specification, the thickness T of the additional member 7 in the axial direction is , gradually increasing toward the inner circumference. As a result, immediately after the seismic isolation device 1 starts to deform in the horizontal direction, the additional member 7 receives the force applied from the portion 31 on the inner peripheral side of the additional member 7 of the laminated structure 3 to It can be transmitted more effectively to the portion 32 on the axially outer side with respect to the additional member 7 . Therefore, it is possible to effectively suppress curling up.
Here, "gradual increase" is not limited to the case where the increase is always smooth without becoming constant in some areas, as in each example of FIGS. In addition, it also includes the case where it becomes constant in part (the case where it increases step by step).
However, in each example described in this specification, the thickness T of the additional member 7 in the axial direction is equal to It may be constant (uniform) throughout. In this case as well, it is possible to effectively suppress curling up.

In each example described in this specification, as in the example shown in FIG. It is preferable that a pair 4P and an additional member 7 are provided. In this case, compared to the case where the pair 4P and the additional member 7 are provided only at one of the upper and lower ends of the laminated structure 3, the buckling resistance of the seismic isolation device 1 is reduced. can improve performance.
However, as in the sixth modification shown in FIG. 10, the pair 4P consisting of the small-diameter hard material layer 4S and the large-diameter hard material layer 4L and the additional member 7 are provided only on the lower end side of the laminated structure 3. may be provided, or, as in the seventh modification shown in FIG. 11, only on the upper end side of the laminated structure 3, the A pair 4P and an additional member 7 may be provided. In these cases, compared to the case where the pair 4P and the additional member 7 are provided on both the upper and lower end sides of the laminated structure 3 (FIG. 1), the seismic isolation device 1 is manufactured. , the work of laminating the hard material layers 4 and the soft material layers 5 constituting the laminated structure 3 and the work of arranging the additional members 7 are facilitated, so that the productivity of the seismic isolation device 1 can be improved. In these cases, the hard material layers 4 have the same diameter at the end of the laminated structure 3 where the pair 4P is not provided, and the stepped portion 4LM does not exist. As a result, there is no possibility of the sheet being turned up when it is deformed in the horizontal direction. Therefore, if the additional member 7 is provided only on the end portion side where the pair 4P is provided between the upper side and the lower side of the laminated structure 3, it is sufficient from the viewpoint of suppressing the curling up.

In each example described in this specification, like the eighth modification shown in FIGS. 12 to 13 and the ninth modification shown in FIG. On the end side of either one (at least the lower side in each example of FIGS. 12 to 14), a plurality of pairs 4P each composed of a small-diameter hard material layer 4S and a large-diameter hard material layer 4L are formed (as shown in FIGS. 12 to 14). In each example, there may be three). In the examples of FIGS. 12 and 13, the radial lengths L of the stepped portions 4LM of each pair 4P are the same. FIG. 12 shows a state in which horizontal deformation has not occurred, and FIG. 13 shows a state in which horizontal deformation has occurred. In the example of FIG. 14, the radial lengths L of the stepped portions 4LM of each pair 4P are different from each other. More specifically, the radial length L of the stepped portions 4LM of each pair 4P is longer as the stepped portions 4LM are positioned further outward in the axial direction. FIG. 14 shows a state in which no horizontal deformation has occurred.
In this case, on at least one end side of the upper side and the lower side of the laminated structure 3, the additional member 7 is attached to at least one stepped portion 4LM among the stepped portions 4LM of each of the plurality of pairs 4P. , is preferably arranged axially inward. As a result, it is possible to suppress curling up.
Here, if the additional member 7 is not provided, the longer the radial length L of the stepped portion 4LM, the more the stepped portion 4LM and , and the axially outward portion thereof is likely to be warped (turned up) axially inward. From this point of view, the laminated structure 3 has a plurality of pairs 4P each formed of a small-diameter hard material layer 4S and a large-diameter hard material layer 4L on at least one of its upper and lower ends. 12 to 14, the additional member 7 is attached to at least the stepped portion 4LM having the maximum radial length L among the stepped portions 4LM of the plurality of pairs 4P. , is preferably arranged axially inward. As a result, if the additional member 7 is arranged axially inward of only the stepped portions 4LM other than the stepped portions 4LM having the maximum radial length L among the stepped portions 4LM of the plurality of pairs 4P. It is possible to further suppress the curling-up as compared with the case where it is formed.
In addition, when the laminated structure 3 has a plurality of pairs 4P formed of the small-diameter hard material layer 4S and the large-diameter hard material layer 4L on at least one end side of the upper side and the lower side, 12 to 14, each of the plurality of additional members 7 is axially aligned with respect to the respective stepped portions 4LM of at least two (more preferably all) pairs 4P of the plurality of pairs 4P. It is preferred if they are arranged respectively on the inside. As a result, compared to the case where the additional member 7 is arranged axially inward of only one stepped portion 4LM among the stepped portions 4LM of each of the plurality of pairs 4P, the turning-up is further prevented. can be suppressed.

The larger the area of the additional member 7 in the axial cross section, the more effectively the force applied to the additional member 7 from the inner peripheral side portion 31 of the laminated structure 3 when the seismic isolation device 1 is deformed in the horizontal direction. In addition, there is a tendency that it becomes easier to transmit to the portion 32 of the laminated structure 3 on the outer side in the axial direction with respect to the additional member 7 (and thus, the curling-up suppressing performance increases). From this point of view, in each example described in this specification, the laminated structure 3 has a small-diameter hard material layer 4S and a large-diameter hard material layer 4S on at least one of its upper and lower ends. It has a plurality of pairs 4P made of layers 4L, and each of the plurality of additional members 7 is attached to the stepped portion 4LM of each of at least two (more preferably all) pairs 4P among the plurality of pairs 4P. On the other hand, when each of the additional members 7 is arranged axially inward, as in the example of FIG. , a large area in axial cross-section. As a result, it is possible to dispose the additional member 7 having a higher ability to suppress curling up in the stepped portion 4LM, which is more prone to curling up, so that the curling up can be further suppressed.
In the example of FIG. 14, on the end side of at least one of the upper side and the lower side of the laminated structure 3, a plurality (more specifically, three) of the stepped portions 4LM of the pairs 4P are arranged in the axial direction. The radial length L of the additional member 7 is longer as it is positioned further outside, and the plurality (more specifically, three) of the additional members 7 are arranged axially inside the stepped portion 4LM having the longer radial length L. The closer they are, the larger the area in the axial cross-section, ie, the more axially outward they are located, the larger the area in the axial cross-section.
However, in each example described in this specification, the size relationship of the areas of the plurality of additional members 7 in cross sections in the axial direction may be arbitrary. For example, as in the example of FIG. 14, on the end side of at least one of the upper side and the lower side of the laminated structure 3, a plurality (more specifically, three) of stepped portions 4LM of pairs 4P are In the case where the radial length L of each additional member 7 increases as it is positioned further outward in the axial direction, the areas of the additional members 7 in the cross section in the axial direction may be the same. Alternatively, as in the examples of FIGS. 12 and 13, at least one of the upper and lower sides of the laminated structure 3 has a plurality of (more specifically, three) stepped portions of the pairs 4P. The 4LMs may have the same radial length L, and the additional members 7 may have the same cross-sectional area in the axial direction.

Similarly, the longer the radial length W of the additional member 7 is, the more the force applied to the additional member 7 from the inner peripheral side portion 31 of the laminated structure 3 when the seismic isolation device 1 is deformed in the horizontal direction. More effectively, there is a tendency that it becomes easier to transmit to the portion 32 of the laminated structure 3 on the outer side in the axial direction with respect to the additional member 7 (and thus, the curling-up suppressing performance increases). From this point of view, in each example described in this specification, the laminated structure 3 has a small-diameter hard material layer 4S and a large-diameter hard material layer 4S on at least one of its upper and lower ends. It has a plurality of pairs 4P made of layers 4L, and each of the plurality of additional members 7 is attached to the stepped portion 4LM of each of at least two (more preferably all) pairs 4P among the plurality of pairs 4P. On the other hand, when each of the additional members 7 is arranged axially inward, as in the example of FIG. , a large radial length W is preferred. As a result, it is possible to dispose the additional member 7 having a higher ability to suppress curling up in the stepped portion 4LM, which is more prone to curling up, so that the curling up can be further suppressed.
In the example of FIG. 14, on the end side of at least one of the upper side and the lower side of the laminated structure 3, a plurality (more specifically, three) of the stepped portions 4LM of the pairs 4P are arranged in the axial direction. The radial length L of the additional member 7 is longer as it is positioned further outside, and the plurality (more specifically, three) of the additional members 7 are arranged axially inside the stepped portion 4LM having the longer radial length L. The radial length W is longer the closer to the center, that is, the radial length W is longer the further axially outward.
However, in each example described in this specification, the size relationship of the radial length W between the plurality of additional members 7 may be arbitrary. For example, as in the example of FIG. 14, on the end side of at least one of the upper side and the lower side of the laminated structure 3, a plurality (more specifically, three) of stepped portions 4LM of pairs 4P are In the case where the radial length L of each additional member 7 increases as it is positioned further outward in the axial direction, the radial lengths W of the additional members 7 may be the same. Alternatively, as in the examples of FIGS. 12 and 13, at least one of the upper and lower sides of the laminated structure 3 has a plurality of (more specifically, three) stepped portions of the pairs 4P. 4LM may have the same radial length L, and the radial length W of each additional member 7 may be the same.

The higher the hardness of the additional member 7, the more effectively the force applied to the additional member 7 from the inner peripheral side portion 31 of the laminated structure 3 when the seismic isolation device 1 is deformed in the horizontal direction. There is a tendency that it becomes easier to transmit to the portion 32 of the structure 3 on the outer side in the axial direction with respect to the additional member 7 (and thus, the curling-up suppressing performance increases). From this point of view, in each example described in this specification, as in the example of FIG. 14, the laminated structure 3 has a small-diameter hard It has a plurality of pairs 4P consisting of the material layer 4S and the large-diameter hard material layer 4L, and each of the plurality of additional members 7 has at least two (more preferably all) pairs of the plurality of pairs 4P. When each of the additional members 7 is arranged axially inward with respect to each stepped portion 4LM of 4P, the more the plurality of additional members 7 are arranged axially inwardly with respect to the stepped portion 4LM, the longer the radial length L is. , high hardness is preferred. As a result, it is possible to dispose the additional member 7 having a higher ability to suppress curling up in the stepped portion 4LM, which is more prone to curling up, so that the curling up can be further suppressed.
However, in each example described in this specification, the hardness magnitude relationship between the plurality of additional members 7 may be arbitrary. For example, as in the example of FIG. 14, on the end side of at least one of the upper side and the lower side of the laminated structure 3, a plurality (more specifically, three) of stepped portions 4LM of pairs 4P are In the case where the radial length L of the additional member 7 increases as it is positioned further outward in the axial direction, the hardness of each additional member 7 may be the same. Alternatively, as in the examples of FIGS. 12 and 13, at least one of the upper and lower sides of the laminated structure 3 has a plurality of (more specifically, three) stepped portions of the pairs 4P. In the case where the 4LMs have the same radial length L, the hardness of each additional member 7 may be the same.

In each example described in this specification, the laminated structure 3 is provided with each rigid body on at least one end side of its upper side and lower side, as in each example of FIGS. Each material layer 4 has an outer diameter equal to or greater than the outer diameter of another hard material layer 4 adjacent to the hard material layer 4 on the inner side in the axial direction (that is, the outer diameter of each hard material layer 4 is gradually increasing towards the outside in the axial direction) is preferred. In other words, the laminated structure 3, as in each example of FIGS. It is expedient if it does not have an outer diameter less than the outer diameter of another hard material layer 4 which is adjacent to it axially inwards. As a result, compared to the case where any one of the hard material layers 4 has an outer diameter smaller than the outer diameter of the other hard material layer 4 adjacent to the hard material layer 4 on the inner side in the axial direction, The buckling resistance performance of the seismic isolation device 1 can be improved.
In addition, in each example described in this specification, the laminated structure 3 has a plurality of hard material layers 4 positioned most axially outward on at least one of its upper and lower ends, Each of the hard material layers 4 has an outer diameter larger than the outer diameter of the other hard material layers 4 adjacent to the hard material layer 4 in the axial direction (that is, the outer diameters of the plurality of hard material layers 4 are It is preferable that it always increases smoothly toward the outside without becoming constant in some areas). In this case, in addition to being able to improve the buckling resistance performance and the seismic isolation performance of the seismic isolation device 1, it is possible to further suppress the lamination structure 3 from being turned up.
1, 10, and 11, the plurality of hard material layers 4 may have the same diameter at the central portion in the axial direction of the laminated structure 3, Alternatively, in the central portion of the laminated structure 3, the plurality of hard material layers 4 each have an outer diameter larger than the outer diameter of the other hard material layers 4 adjacent to the hard material layer 4 on the inner side in the axial direction. (That is, the outer diameters of the plurality of hard material layers 4 may always increase smoothly toward the outside in the axial direction without becoming constant in some areas). For example, in the laminated structure 3, in the entire axial direction of the laminated structure 3, a plurality of hard material layers 4 are arranged so that the outer diameter of the other hard material layer 4 adjacent to the hard material layer 4 on the inner side in the axial direction is increased. (that is, the outer diameters of these hard material layers 4 always increase smoothly toward the outside in the axial direction without becoming constant in some areas).
In these cases, the small-diameter hard material layer 4S of each pair 4P can become the large-diameter hard material layer 4L of another pair 4P adjacent to the pair 4P on the inner side in the axial direction. Similarly, the large-diameter hard material layer 4L of each pair 4P can be the small-diameter hard material layer 4S of another pair 4P adjacent to the pair 4P in the axial direction outside.

In each example described in this specification, the laminated structure 3 has a pair 4P consisting of a small-diameter hard material layer 4S and a large-diameter hard material layer 4L on at least one of its upper and lower ends. , as in the example of FIG. 14, it is preferable that the radial length L of the stepped portion 4LM of each pair 4P is longer as the stepped portion 4LM is positioned further outward in the axial direction. As a result, compared to the case where the radial lengths L of the stepped portions 4LM of each pair 4P are the same as in the example of FIGS. can.

1, 10, and 11, each hard material layer 4 and each soft material layer 5 of the laminated structure 3 are solid rather than annular, and the central axis of the laminated structure 3 Although the hard material layer 4 and the soft material layer 5 are positioned on O, the present invention is not limited to this. For example, the laminated structure 3 is configured such that each hard material layer 4 and each soft material layer 5 are annularly formed, and the central hole of each hard material layer 4 and the central hole of each soft material layer 5 form a laminated structure. The body 3 has an axially extending central hole on its central axis O, in which a columnar body may be arranged. It is preferable that the columnar body be configured to absorb vibration energy by plastic deformation. The pillars can be made of, for example, lead, tin, tin alloys, or thermoplastic resin.

In each example described in this specification, as in the examples of FIGS. 2 and 6 to 14, the maximum value of the axial thickness T of the additional member 7 (that is, Advantageously, the axial thickness T) at the position of the outer peripheral surface portion 33 of the laminate structure 3 where it is located is greater than the axial spacing between the hard material layers 4 . As a result, the force applied to the additional member 7 of the laminated structure 3 from the portion 31 on the inner peripheral side of the additional member 7 can be more effectively transferred to the axially outer side of the additional member 7 of the laminated structure 3 . It becomes easier to convey to the portion 32 . Therefore, it is possible to further suppress curling up. Here, "the axial distance between the hard material layers 4" refers to the axial distance between the axial centers of a pair of hard material layers 4 adjacent to each other.
In addition, when the seismic isolation device 1 has a plurality of additional members 7, only a part of the additional members 7 among the plurality of additional members 7 may satisfy this configuration. More preferably, all additional members 7 of 7 satisfy this configuration.

Similarly, in each of the examples described herein, such as in the examples of FIGS. (ie at the same axial position as the at least two hard material layers 4). As a result, the force applied to the additional member 7 of the laminated structure 3 from the portion 31 on the inner peripheral side of the additional member 7 can be more effectively transferred to the axially outer side of the additional member 7 of the laminated structure 3 . It becomes easier to convey to the portion 32 . Therefore, it is possible to further suppress curling up.
In addition, when the seismic isolation device 1 has a plurality of additional members 7, only a part of the additional members 7 among the plurality of additional members 7 may satisfy this configuration. More preferably, all additional members 7 of 7 satisfy this configuration.

In each example described in this specification, the radial length W of the additional member 7 is greater than the axial distance between the hard material layers 4, as in the examples of FIGS. 2 and 6 to 14. and is preferred. As a result, when the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 can more effectively suppress warping of the stepped portion 4LM positioned on the outer side of the additional member 7 in the axial direction. Therefore, it is possible to further suppress curling up. From the same point of view, the radial length W of the additional member 7 is more preferably 1.5 times or more the axial distance between the hard material layers 4, and more preferably 2 times or more. is. From the standpoint of seismic isolation performance, etc., the radial length W of the additional member 7 is preferably 7.5 times or less, more preferably 5 times or less, the distance between the hard material layers 4 in the axial direction. It is more suitable.
In addition, when the seismic isolation device 1 has a plurality of additional members 7, only a part of the additional members 7 among the plurality of additional members 7 may satisfy this configuration. More preferably, all additional members 7 of 7 satisfy this configuration.

In each example described in this specification, the radial length W of the additional member 7 is the maximum value of the axial thickness T of the additional member 7 ( That is, it is preferable that the thickness is equal to or greater than the axial thickness T) at the position of the outer peripheral surface portion 33 of the laminated structure 3 located on the inner peripheral side of the additional member 7 . As a result, when the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 can more effectively suppress warping of the stepped portion 4LM positioned on the outer side of the additional member 7 in the axial direction. Therefore, it is possible to further suppress curling up. From the same point of view, it is more preferable that the radial length W of the additional member 7 is greater than the maximum value of the axial thickness T of the additional member 7 .
In addition, when the seismic isolation device 1 has a plurality of additional members 7, only a part of the additional members 7 among the plurality of additional members 7 may satisfy this configuration. More preferably, all additional members 7 of 7 satisfy this configuration.

In each example described in this specification, as in each example of FIGS. It is preferable that it is 0.7 times or more the radial length L of 4LM. As a result, when the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 can more effectively suppress warping of the stepped portion 4LM positioned on the outer side of the additional member 7 in the axial direction. Therefore, it is possible to further suppress curling up. From the same point of view, it is more preferable that the radial length W of the additional member 7 is 0.9 times or more the radial length L of the stepped portion 4LM positioned axially outside of the additional member 7. . From the standpoint of seismic isolation performance, etc., the radial length W of the additional member 7 should be 1.3 times or less the radial length L of the stepped portion 4LM positioned axially outside of the additional member 7. 1.1 times or less is more preferable.
In addition, when the seismic isolation device 1 has a plurality of additional members 7, only a part of the additional members 7 among the plurality of additional members 7 may satisfy this configuration. More preferably, all additional members 7 of 7 satisfy this configuration.

In each example described in this specification, the additional member 7 is arranged over the entire stepped surface 34 positioned axially outside thereof in the axial cross section, as in the examples of FIGS. 2 and 6 to 14. (that is, the radial length W of the additional member 7 is equal to or longer than the radial length of the step surface 34). As a result, when the seismic isolation device 1 is deformed in the horizontal direction, the additional member 7 can more effectively suppress warping of the stepped portion 4LM positioned on the outer side of the additional member 7 in the axial direction. Therefore, it is possible to further suppress curling up.
However, in the axial cross-section, the additional member 7 may be arranged over only a portion of the stepped surface 34 located on the axially outer side (that is, the radial length W of the additional member 7 is equal to the stepped surface 34 (may be less than the radial length of

The seismic isolation device of the present invention is designed to suppress the transmission of earthquake vibrations to structures (for example, buildings such as buildings, condominiums, detached houses, warehouses, bridges, etc.). It is preferred when placed between structures.

1: seismic isolation device,
21: upper flange plate (flange plate), 22: lower flange plate (flange plate),
3: laminated structure, 31: portion of the laminated structure on the inner peripheral side with respect to the additional member, 32: portion of the laminated structure on the axially outer side with respect to the additional member, 33: located on the inner peripheral side of the additional member (the outer peripheral surface portion of the laminated structure extending axially inward from the inner peripheral end of the step surface), 34: step surface
4: Hard material layer 4S: Small diameter hard material layer (hard material layer) 4L: Large diameter hard material layer (hard material layer) 4LM: Step portion 4P: Pair
5: soft material layer,
6: a coating layer,
7: additional member, 7a: side surface,
O: central axis

Claims (8)

a laminated structure having hard material layers and soft material layers alternately laminated in the vertical direction;
an additional member;
A seismic isolation device comprising
The laminated structure has a small-diameter hard material layer, which is the hard material layer, and is adjacent to the small-diameter hard material layer on at least one of its upper and lower ends in the axial direction outside. a large-diameter hard material layer that is the hard material layer having a larger diameter than the small-diameter hard material layer,
The additional member is arranged axially inward with respect to a stepped portion of the large-diameter hard material layer located on the outer peripheral side of the small-diameter hard material layer,
When the seismic isolation device is deformed in the horizontal direction, the additional member is axially deformed with respect to the additional member of the laminated structure by a force applied to the additional member of the laminated structure from a portion on the inner peripheral side of the additional member. It is configured such that the outer portion can be pressed axially outward,
In a state where the seismic isolation device is not deformed in the horizontal direction, the thickness of the additional member in the axial direction is maximum at the position of the outer peripheral surface portion of the laminated structure located on the inner peripheral side of the additional member. Seismic isolation device. 2. The seismic isolation device according to claim 1, wherein in a state in which said seismic isolation device is not deformed in the horizontal direction, the axial thickness of said additional member gradually increases toward the inner peripheral side. The laminated structure has a plurality of pairs of the small-diameter hard material layer and the large-diameter hard material layer on at least one end side of an upper side and a lower side thereof,
3. The additional member according to claim 1, wherein the additional member is arranged axially inward of at least the stepped portion having the largest radial length among the stepped portions of each of the plurality of pairs. seismic isolation device. The laminated structure has a plurality of pairs of the small-diameter hard material layer and the large-diameter hard material layer on at least one end side of an upper side and a lower side thereof,
The plurality of additional members according to any one of claims 1 to 3, wherein each of the plurality of additional members is arranged axially inward with respect to each of the stepped portions of at least two pairs of the plurality of pairs. seismic isolation device. 5. The seismic isolation device according to claim 4, wherein the plurality of additional members arranged axially inward with respect to the step portion having a longer radial length have a larger area in an axial cross section. 6. The seismic isolation device according to claim 4, wherein said plurality of additional members have higher hardness as they are arranged axially inward with respect to said stepped portion having a longer radial length. The additional member is
constructed from an incompressible material and/or
The seismic isolation device according to any one of claims 1 to 6, wherein the base isolation device is made of a material having a hardness higher than that of the soft material forming the soft material layer. The seismic isolation device according to any one of claims 1 to 6, wherein the additional member is made of a material having hardness lower than that of the soft material forming the soft material layer.

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