JP2020204356A - Base isolation structure - Google Patents

Abstract

To provide a base isolation structure capable of exerting damping performance and base isolation performance regardless of earthquake magnitude scales.SOLUTION: A base isolation structure has: a lower structure 20; a base isolation device placed on the lower structure 20; an upper structure 30 supported by the base isolation device; and a collision shock absorbing material (fender 80) deformed by being pressed from the lower structure 20 or the upper structure 30 when the lower structure 20 and the upper structure 30 are relatively displaced and the lower structure 20 or the upper structure 30 is brought into contact therewith. The base isolation device has: a first base isolation device (base isolation device 40) including a first support portion (lead plug 42, laminated rubber 44) deformed by external force and damping vibration, and a slide mechanism (slide material 46, slide plate 48) for sliding and displacing the first support portion; and a second base isolation device (base isolation device 50) including a second support portion (lead plug 52, laminated rubber 54) deformed by external force and damping vibration, and not including the slide mechanism.SELECTED DRAWING: Figure 1

Description

The present invention relates to a seismic isolation structure.

The following Patent Document 1 shows a configuration of a sliding laminated plate bearing in which a plug portion for absorbing seismic energy is inserted.

Japanese Unexamined Patent Publication No. 2008-261490 (Fig. 4)

When the sliding laminated plate bearing of Patent Document 1 is used, the seismic energy input to the structure mounted on the upper part by sliding the smoothing member while absorbing the seismic energy by the plug portion (damping performance). Can be suppressed (seismic isolation performance). However, it is difficult to exhibit sufficient damping performance when the smoothing member slides due to, for example, a large-scale earthquake.

In view of the above facts, an object of the present invention is to provide a seismic isolation structure capable of exhibiting damping performance and seismic isolation performance regardless of the scale of an earthquake.

The seismic isolation structure according to claim 1 includes a lower structure, a seismic isolation device mounted on the lower structure, an upper structure supported by the seismic isolation device, the lower structure, and the upper structure. Has a seismic isolation material having a collision buffer material that is pressed from the substructure or the superstructure and deforms to attenuate vibration when the substructure or the superstructure hits the substructure or the superstructure. The device includes a first seismic isolation device provided with a first support portion that is deformed by an external force to attenuate vibration and a sliding mechanism that slides and displaces the first support portion, and a first seismic isolation device that is deformed by an external force to attenuate vibration. It has a second seismic isolation device having a second support portion and no sliding mechanism.

In the seismic isolation structure of claim 1, the first seismic isolation device and the second seismic isolation device are used in combination. Due to the horizontal force during an earthquake, the superstructure is displaced relative to the substructure. At this time, the first support portion of the first seismic isolation device and the second support portion of the second seismic isolation device are deformed to attenuate the vibration. That is, it exhibits seismic isolation performance and damping performance during a normal earthquake.

Further, the first bearing portion of the first seismic isolation device slides and is displaced by the sliding mechanism. On the other hand, since the second seismic isolation device does not have a sliding mechanism, the second bearing portion continues to be deformed to attenuate the vibration even if the external force becomes large. As a result, seismic isolation performance and damping performance can be exhibited even in a large earthquake.

Further, when the external force becomes large and the lower structure or the upper structure hits the collision cushioning material, the collision cushioning material is pressed from the lower structure or the superstructure and deformed to attenuate the vibration. As a result, the damping performance can be further improved.

The seismic isolation structure according to claim 2 is the seismic isolation structure according to claim 1, wherein the collision cushioning material comes into contact with the lower structure or the upper structure after the first support portion starts sliding displacement.

In the seismic isolation structure of claim 2, the collision cushioning material is not pressed from the lower structure or the upper structure before the first bearing portion starts sliding displacement. Therefore, the deformation of the first bearing portion is not hindered, and the damping performance of the first bearing portion can be sufficiently exhibited.

The seismic isolation structure according to claim 3 is the seismic isolation structure according to claim 1 or 2, wherein the second bearing portion breaks when the collision cushioning material is deformed by a predetermined value or more.

In the seismic isolation structure of claim 3, when the deformation amount of the collision cushioning material is less than a predetermined value, the second bearing portion does not break. Therefore, the elastic restoring force of the second bearing makes it easy to restore the relative position of the lower structure and the upper structure after the earthquake.
Further, when the deformation amount of the collision cushioning material is equal to or more than a predetermined value, the second bearing portion is broken. Therefore, the damping performance of the second bearing can be maximized.

According to the seismic isolation structure according to the present invention, damping performance and seismic isolation performance can be exhibited regardless of the scale of the earthquake.

(A) is an elevational view showing a state before the upper structure moves relative to the lower structure in the seismic isolation structure according to the embodiment of the present invention, and (B) is an elevation view showing the state before the upper structure moves relative to the lower structure, and (B) shows the upper structure having the lower structure. It is an elevation view which shows the state which the 1st seismic isolation device and the 2nd seismic isolation device are deformed by moving relative to a body, and (C) is the 2nd seismic isolation device by sliding the 1st seismic isolation device. It is an elevation view which showed the state which the seismic isolation device is deformed, and (D) is the elevation view which showed the state which the collision buffer material is deformed. It is a top view which shows the seismic isolation structure which concerns on embodiment of this invention. It is a graph which shows the damping performance in the seismic isolation structure which concerns on embodiment of this invention.

Hereinafter, the seismic isolation structure according to the embodiment of the present invention will be described with reference to the drawings. The components shown by the same reference numerals in each drawing mean that they are the same components. The description of overlapping configurations and symbols in the drawings may be omitted. Further, the present invention is not limited to the following embodiments, and can be carried out with appropriate modifications within the scope of the object of the present invention.

(building)
The seismic isolation structure according to the embodiment of the present invention is applied to the building 10 shown in FIG. 1 (A) as an example. The building 10 is a reinforced concrete structure, a steel-framed reinforced concrete structure, or a steel-framed seismic isolation structure in which the superstructure 30 is placed on the upper part of the lower structure 20 via the seismic isolation devices 40 and 50. In addition, "reinforced concrete structure, steel frame reinforced concrete structure or steel frame structure" indicates that the column-beam structure is made of reinforced concrete, steel frame reinforced concrete or steel frame.

(1st seismic isolation device)
The seismic isolation device 40 is an example of the first seismic isolation device in the present invention, and includes a lead plug 42 as a vibration damping mechanism, a laminated rubber 44 as a seismic isolation mechanism, a sliding material 46, and a sliding plate 48.

The lead plug 42 can be plastically deformed by an external force (horizontal force acting during an earthquake) to absorb vibration energy and attenuate vibration (in other words, the lead plug 42 generates a damping force for vibration). The lead plug 42 is arranged at the center of the laminated rubber 44.

The laminated rubber 44 is formed by alternately stacking rubber plates and steel plates mainly made of natural rubber and vulcanizing and adhering them. The laminated rubber 44 has a substantially cylindrical shape, and always supports the load of the superstructure 30. The laminated rubber 44 suppresses the elastic deformation of the rubber plate by an external force (horizontal force acting at the time of an earthquake) and the input of seismic energy from the lower structure 20 to the upper structure 30.

The upper end of the laminated rubber 44 is fixed to a steel flange 49. The flange 49 is fixed to the upper structure 30 by using anchor bolts or the like.

The sliding material 46 is formed by using a PTFE (polytetrafluoroethylene) material or the like, and is fixed to the lower end portion of the laminated rubber 44. Further, the sliding member 46 is non-fixed on the upper surface of the sliding plate 48.

The sliding plate 48 is formed of a stainless plate or the like, and is fixed to the lower structure 20 so that the upper surface is substantially horizontal. The coefficient of friction between the sliding member 46 and the sliding plate 48 can be changed as appropriate. The method of setting the friction coefficient in this embodiment will be described later.

In the seismic isolation device 40, the lead plug 42 and the laminated rubber 44 are examples of the first bearing portion in the present invention, and the sliding member 46 and the sliding plate 48 are examples of the sliding mechanism in the present invention.

Further, in the present embodiment, the sliding plate 48 is fixed to the lower structure 20, but the embodiment of the present invention is not limited to this. That is, the sliding plate 48 may be fixed to the superstructure 30. In this case, the flange 49 is fixed to the lower structure by exchanging the upper and lower sides with the seismic isolation device 40 described above.

(2nd seismic isolation device)
The seismic isolation device 50 is an example of the second seismic isolation device in the present invention, and includes a lead plug 52 as a vibration damping mechanism, a laminated rubber 54 as a seismic isolation mechanism, a flange 56, and a flange 58.

Like the lead plug 42, the lead plug 52 can be plastically deformed by an external force (horizontal force acting at the time of an earthquake) to absorb vibration energy and attenuate the vibration. The lead plug 52 is arranged at the center of the laminated rubber 54.

Like the laminated rubber 44, the laminated rubber 54 is formed by alternately stacking rubber plates and steel plates mainly made of natural rubber and vulcanizing and adhering them. The laminated rubber 54 has a substantially cylindrical shape and always supports the load of the superstructure 30. The laminated rubber 54 suppresses the elastic deformation of the rubber plate by an external force (horizontal force acting at the time of an earthquake) and the input of seismic energy from the lower structure 20 to the upper structure 30.

The upper and lower ends of the laminated rubber 54 are fixed to steel flanges 58 and 56, respectively. The flange 58 is fixed to the upper structure 30 by using anchor bolts or the like, and the flange 56 is fixed to the lower structure 20 by using anchor bolts or the like.

In the seismic isolation device 50, the lead plug 52 and the laminated rubber 54 are examples of the second bearing portion in the present invention.

(Collision cushioning material)
A steel frame column 70 made of H-shaped steel is installed in the lower structure 20. The lower end of the steel frame support 70 is embedded in the center of the span of the beam 22 in the lower structure 20, and protrudes upward from the beam. Further, the steel frame columns 70 are arranged so that the strong axis direction (extending direction of the web 72) is along the extending direction of the beam. Further, the steel frame column 70 is provided with a stiffening plate 76 between the flanges 74.

In both flanges 74 of the steel frame column 70, fenders 80 are attached to both outer surfaces of the portion stiffened by the stiffening plate 76 via a pedestal 82 as a collision cushioning material. The fender 80 is a rubber bearing having a substantially hollow conical shape whose diameter is reduced from the flange 74 toward the side of the steel frame column 70, and is in the compression direction (extension direction of the web 72) and the shear direction (extension of the flange 74). It can exert resistance to the input of force in the direction).

A reaction force body 90 made of concrete is installed on the beam 32 of the superstructure 30. The reaction force body 90 includes a fixing portion 92 integrally formed with the beam 32 and the footing 34, and a pressing portion 94 protruding downward from the fixing portion 92. The fixing portion 92 and the pressing portion 94 are integrally formed.

The reaction force bodies 90 are arranged on both sides of the steel frame support 70 so as to face the fender 80. Therefore, when the lower structure 20 and the upper structure 30 are relatively displaced during an earthquake, the two fenders 80 attached to both flanges 74 of the steel frame column 70 alternately come into contact with the reaction force 90. Can be done. When the fender 80 comes into contact with the reaction force body 90, the fender 80 can be pressed and deformed by the reaction force body 90 to attenuate the vibration.

In the present embodiment, the steel frame support 70 and the fender 80 are provided in the lower structure 20, and the reaction force body 90 is provided in the upper structure 30, but the embodiment of the present invention is not limited to this. .. For example, the steel frame support 70 and the fender 80 may be provided in the upper structure 30, and the reaction force 90 may be provided in the lower structure 20.

(Arrangement of seismic isolation structure)
FIG. 2 is a plan view showing an example of the arrangement of the seismic isolation devices 40 and 50, the steel frame support 70, and the fender 80 described above. In the present embodiment, as the seismic isolation device, in addition to the seismic isolation devices 40 and 50, a slip seismic isolation device 60 not provided with a lead plug (not provided with a vibration damping mechanism) is provided. The seismic isolation device 60 does not necessarily have to be provided.

The seismic isolation devices 40, 50, and 60 are arranged in a grid pattern at the lower part of the upper structure 30 just below the pillars of the upper structure 30. The seismic isolation devices 40, 50, and 60 can be appropriately arranged (position and quantity) according to the weight balance of the superstructure 30, but in the present embodiment, the seismic isolation device is an example. The seismic isolation device 40 is arranged around the seismic isolation device 40, and the seismic isolation device 50 is arranged around the seismic isolation device 40. That is, the seismic isolation device 50 is arranged on the outer peripheral portion of the building 10 where a pulling force is likely to be generated at the time of an earthquake. Therefore, the yield strength against the pulling force is improved as compared with the case where the seismic isolation device 40 and the seismic isolation device 60 are arranged on the outer peripheral portion of the building 10. In addition, in order to further improve the yield strength to the pulling force, high strength laminated rubber (HSR: High Strength Rubber Bearing) or the like may be used as the laminated rubber 54 of the seismic isolation device 50.

Further, among the plurality of steel frame columns 70 provided, some of them are provided so that the fender 80 fixed to both flanges 74 (see FIG. 1) is arranged along the X direction. In addition, the other part is provided so that the fender 80 fixed to both flanges 74 is arranged along the Y direction. The X direction and the Y direction are directions substantially orthogonal to each other, and are extending directions of the beam 22 of the lower structure 20 (see FIG. 1) and the beam 32 of the upper structure 30.

Further, the reaction force body 90 is provided so as to face each fender 80. Therefore, when the lower structure 20 and the upper structure 30 are relatively displaced not only in the X direction but also in the Y direction, the fender 80 comes into contact with the reaction force body 90.

In addition, in FIGS. 1A to 1D, the seismic isolation devices 40 and 50 and the fender 80 are shown adjacent to each other. These figures outline the main components of the present invention and do not consider consistency with FIG. That is, as described above, the arrangement of the seismic isolation devices 40 and 50 and the fender 80 is not particularly limited and can be adjusted as appropriate.

(Action / effect)
The damping performance and the seismic isolation performance of the seismic isolation structure according to the embodiment of the present invention will be described with reference to FIGS. 1 (B) to 1 (D) and FIG.

FIG. 1B shows a state in which the superstructure 30 is displaced relative to the substructure 20 by a distance X1 due to an external force P1 acting on the building 10 during an earthquake.

When the external force acting on the building 10 at the time of an earthquake is less than the external force P1, the relative displacement amount of the superstructure 30 with respect to the substructure 20 is less than the distance X1. At this time, the laminated rubber 44 in the seismic isolation device 40 and the laminated rubber 54 in the seismic isolation device 50 are sheared and deformed. As a result, the vibration and seismic energy input to the superstructure 30 are suppressed. That is, seismic isolation performance is exhibited.

Further, the lead plugs 42 and 52 are plastically deformed as the laminated rubbers 44 and 54 are deformed. As a result, seismic energy is converted into thermal energy and vibration is attenuated. That is, the damping performance is exhibited.

In addition, in FIG. 3, regarding the damping performance by the seismic isolation device 40, the shear stress (internal stress) and the amount of deformation (the amount of displacement of the superstructure 30 with respect to the substructure 20) generated inside the lead plug 42 by an external force). The relationship with is shown by the dotted line T1. Regarding the damping performance of the seismic isolation device 50, one point is the relationship between the shear stress (internal stress) generated inside the lead plug 52 due to an external force and the amount of deformation (the amount of relative displacement of the superstructure 30 with respect to the substructure 20). It is indicated by the chain line T2.

Further, in FIG. 3, regarding the damping performance of the fender 80, the compressive stress (internal stress) and the amount of deformation (relative displacement of the superstructure 30 with respect to the substructure 20) generated inside the fender 80 due to an external force are shown. ) Is shown by the alternate long and short dash line T3.

Furthermore, regarding the damping performance of the seismic isolation structure (combination of seismic isolation devices 40, 50 and fender 80) according to the embodiment of the present invention, the seismic force acting on the building 10 (seismic isolation device 40 generated by the seismic force). , 50, the sum of the internal stresses of the barrier material 80) and the amount of deformation (the amount of relative displacement of the upper structure 30 with respect to the lower structure 20) are shown by the solid line T4. The damping performance (absorption amount of seismic energy) can be calculated by integrating the solid line T4.

As shown in FIG. 3, when the relative displacement amount of the upper structure 30 with respect to the lower structure 20 is less than the distance X1, both the laminated rubber 44 in the seismic isolation device 40 and the laminated rubber 54 in the seismic isolation device 50 have damping performance. Demonstrate.

Next, FIG. 1C shows a state in which the superstructure 30 is displaced relative to the substructure 20 by a distance X2 due to an external force P2 acting on the building 10 during an earthquake. The external force P2 is a larger external force than the external force P1. When the external force P2 acts and the relative displacement amount becomes the distance X2, the fender 80 comes into contact with (hits) the reaction force body 90.

When the external force is P1 or more, the sliding member 46 in the seismic isolation device 40 slides on the sliding plate 48. That is, the slip material 46 and the slide plate are made so that the slide material 46 slides on the slide plate 48 by a force equal to or higher than the component force P4 (see FIG. 3) input to the seismic isolation device 40 by the external force P1 at the time of an earthquake. The coefficient of static friction with 48 has been adjusted. As a result, the vibration and seismic energy input to the superstructure 30 are suppressed. That is, seismic isolation performance is exhibited.

On the other hand, the laminated rubber 54 in the seismic isolation device 50 undergoes shear deformation even when the external force is P1 or more. As a result, the vibration and seismic energy input to the superstructure 30 are suppressed. That is, the seismic isolation device 50 also exhibits seismic isolation performance.

Further, the lead plug 52 is plastically deformed as the laminated rubber 54 is deformed. As a result, seismic energy is converted into thermal energy and vibration is attenuated. That is, the damping performance is exhibited.

Next, FIG. 1D shows a state in which the superstructure 30 is displaced relative to the substructure 20 by a distance X3 due to an external force P3 acting on the building 10 during an earthquake. The external force P3 is a larger external force than the external force P2. When the external force P3 acts and the relative displacement amount becomes the distance X3 (when the deformation amount of the fender 80 becomes a predetermined value (X3-X2) or more), the lead plug 52 of the seismic isolation device 50 breaks. (Plastic limit). At this time, the fender 80 continues to be deformed.

When the external force is P2 or more, the sliding member 46 in the seismic isolation device 40 slides on the sliding plate 48. As a result, the vibration and seismic energy input to the superstructure 30 are suppressed. That is, seismic isolation performance is exhibited.

On the other hand, the laminated rubber 54 in the seismic isolation device 50 undergoes shear deformation even when the external force is P2 or more. As a result, the vibration and seismic energy input to the superstructure 30 are suppressed. That is, the seismic isolation device 50 also exhibits seismic isolation performance.

Further, the lead plug 52 is plastically deformed as the laminated rubber 54 is deformed. As a result, seismic energy is converted into thermal energy and vibration is attenuated. That is, the damping performance is exhibited.

Further, the fender 80 is pressed from the reaction force body 90 and is plastically deformed. As a result, seismic energy is converted into thermal energy and vibration is attenuated. That is, the damping performance is also exhibited by the fender 80.

Arbitrary values are set for the displacement (distance X1) at which the sliding material 46 in the seismic isolation device 40 starts to slide on the sliding plate 48 and the displacement (distance X2) at which the fender 80 comes into contact with the reaction force body 90. can do. In other words, the seismic force (external force P1) at which the sliding member 46 in the seismic isolation device 40 begins to slide on the sliding plate 48 and the seismic force (external force P2) at which the fender 80 comes into contact with the reaction force 90 are arbitrary. The value of can be set.

In this embodiment, as shown in FIG. 3, a ground motion exceeding the medium-scale seismic motion “earthquake ground motion level 1” (displacement L1) and the large-scale earthquake ground motion “earthquake ground motion level 2” (displacement L2) (The external force P1 and the external force acting on the seismic isolation device 40 are the component forces P4) so that the sliding material 46 starts to slide on the sliding plate 48.

As a result, in an earthquake of about "earthquake motion level 2", the seismic isolation performance and damping performance of both the seismic isolation devices 40 and 50 can be exhibited (FIG. 1 (B)). Further, in a seismic motion of a scale exceeding "earthquake ground motion level 2", the seismic isolation performance of the seismic isolation devices 40 and 50 can be exhibited while the damping performance of the seismic isolation device 50 can be exhibited (FIG. 1 (C)). ..

In addition, the fender 80 comes into contact with the reaction force 90 in an earthquake motion of a scale exceeding the “earthquake motion level 3” (displacement L3), which is an unexpected earthquake motion larger than the “earthquake motion level 2”. As a result, in a seismic motion of a scale exceeding "earthquake ground motion level 3", the seismic isolation performance by the seismic isolation devices 40 and 50 can be exhibited, and the damping performance by the seismic isolation device 50 and the fender 80 can be exhibited ( FIG. 1 (D).

As shown in FIGS. 1B to 1D, the fender 80 is not pressed by the reaction force body 90 before the sliding member 46 starts sliding on the sliding plate 48. That is, after the lead plug 42 in the seismic isolation device 40 is sufficiently deformed to exhibit damping performance, the sliding material 46 begins to slide on the sliding plate 48, and the fender 80 comes into contact with the reaction force body 90. , Pressed by the reaction force body 90. Therefore, in the present embodiment, the damping performance of the lead plug 42 can be sufficiently exhibited.

Further, in the present embodiment, when the external force P3 acts and the relative displacement amount becomes the distance X3, the lead plug 52 of the seismic isolation device 50 breaks. At this time, the fender 80 continues to be deformed. As a result, the damping performance of the lead plug 52 can be fully exhibited.

In the present embodiment, the case where the lead plug 52 breaks has been described, but the embodiment of the present invention is not limited to this. For example, the superstructure 30 may come into contact with a retaining wall (not shown) provided around the building 10 before the lead plug 52 breaks. That is, even when the amount of relative displacement of the superstructure 30 with respect to the substructure 20 reaches the limit of the seismic isolation clearance, the damping performance of the lead plug 52 may be exhibited. As a result, the momentum of collision of the superstructure 30 with respect to the retaining wall can be reduced.

As for the fender 80, the breaking strength can be appropriately set as in the lead plug 52. As an example, the fender 80 may be broken before the lead plug 52 is broken. As another example, the fender 80 may be broken after the lead plug 52 is broken. As another example, the superstructure 30 may come into contact with a retaining wall (not shown) provided around the building 10 before the fender 80 breaks.

Further, when the fender 80 is broken, the steel column 70 may yield (elastic limit) and break (plastic limit) after the fender 80 is broken. As a result, the damping performance can be exhibited even by the steel frame support 70.

Further, in FIG. 3, the dotted line T1 is drawn above the alternate long and short dash line T2. That is, the rigidity of the lead plug 42 in the seismic isolation device 40 is larger than the rigidity of the lead plug 52 in the seismic isolation device 50, and the internal stress generated in the lead plug 42 is larger than the internal stress generated in the lead plug 52. However, the embodiment of the present invention is not limited to this.

For example, the rigidity of the lead plug 42 may be larger than the rigidity of the lead plug 52, or the respective rigidity may be equal. The rigidity of the lead plugs 42 and 52 can be changed by adjusting the rigidity of the material itself forming the lead plugs 42 and 52 and adjusting the number of seismic isolation devices 40 and 50 installed.

Further, in the present embodiment, the damping performance of the seismic isolation devices 40 and 50 is exhibited by the lead plugs 42 and 52, but the embodiment of the present invention is not limited to this. For example, even if the rubber constituting the laminated rubbers 44 and 54 is formed of the high damping rubber in place of or in addition to the lead plugs 42 and 52, the seismic isolation devices 40 and 50 can be provided with damping performance. As described above, the present invention can be carried out in various aspects.

20 Substructure 30 Superstructure 40 Seismic isolation device (first seismic isolation device)
50 Seismic isolation device (second seismic isolation device)
80 Fender (collision cushioning material)
42 Lead plug (1st bearing)
44 Laminated rubber (1st bearing)
46 Sliding material (sliding mechanism)
48 Slip plate (slip mechanism)
52 Lead plug (2nd bearing)
54 Laminated rubber (second bearing)

Claims (3)

Substructure and
The seismic isolation device mounted on the substructure and
The superstructure supported by the seismic isolation device and
When the substructure and the superstructure are relatively displaced and hit the substructure or the superstructure, the collision buffer material is pressed from the substructure or the superstructure and deformed to attenuate vibration. And have
The seismic isolation device is
A first seismic isolation device including a first bearing portion that is deformed by an external force to attenuate vibration, and a sliding mechanism that slides and displaces the first bearing portion.
A second seismic isolation device that has a second bearing that deforms due to external force and damps vibrations and does not have a sliding mechanism.
Seismic isolation structure with. The seismic isolation structure according to claim 1, wherein the collision cushioning material comes into contact with the lower structure or the upper structure after the first support portion starts sliding displacement. The seismic isolation structure according to claim 2, wherein the second bearing portion breaks when the collision cushioning material is deformed by a predetermined value or more.