JP2021017779A - Seismic isolation structure - Google Patents

Abstract

To reduce the horizontal force transmitted from the roof frame to the stand during an earthquake.SOLUTION: A seismic isolation structure 10 includes a plurality of core frame portions 20 arranged on the outer circumference, a plurality of laminated rubber bearings provided on the upper portions of the plurality of core frame portions 20 respectively, a stand portion 30 arranged between adjacent strut portions, a sliding bearing provided on the upper portion of the stand portion 30, and a roof frame 40 supported by the core frame portion 20 via the laminated rubber bearing and supported by the stand portion 30 via the sliding bearing.SELECTED DRAWING: Figure 1

Description

The present invention relates to a seismic isolation structure.

Seismic isolation structures such as arenas and stadiums in which the roof frame covering the stand portion is supported by laminated rubber bearings are known (see, for example, Non-Patent Document 1 and Patent Documents 1 and 2).

Japanese Unexamined Patent Publication No. 8-326351 JP-A-2002-047827

Tatsuya Kataoka, Yasuhiko Asaoka, Kazuaki Abe, "Steel Construction Technology", August 2018 issue, VOL. 31, NO. 363, Steel Structure Publishing Co., Ltd., published in August 2018, p. 058 to 059

By the way, since roof frames such as arenas and stadiums are large, their weight tends to be large. Therefore, the cross-sectional area of the support column supporting the roof frame may increase.

As a countermeasure for this, it is conceivable to support the roof frame not only on the support column but also on the stand portion via laminated rubber bearings.

However, if the stand portion supports the roof frame via laminated rubber bearings, a horizontal force is transmitted from the roof frame to the stand portion in the event of an earthquake. Therefore, when designing the stand portion, it is necessary to consider the horizontal force transmitted from the roof frame in the event of an earthquake, which may complicate the design of the stand portion.

In consideration of the above facts, an object of the present invention is to reduce the horizontal force transmitted from the roof frame to the stand portion in the event of an earthquake.

The seismic isolation structure according to claim 1 is arranged between a plurality of support columns arranged on the outer periphery, a plurality of laminated rubber bearings provided on the upper portions of the plurality of support columns, and adjacent support columns. A stand portion, a sliding bearing provided on the upper portion of the stand portion, and a roof frame supported by the support portion via the laminated rubber bearing and supported by the stand portion via the sliding bearing. , Equipped with.

According to the seismic isolation structure according to claim 1, a plurality of support columns are arranged on the outer periphery of the seismic isolation structure. Laminated rubber bearings are provided on the upper portions of these columns. In addition, a stand portion is arranged between the adjacent strut portions. A sliding bearing is provided on the upper part of the stand portion.

Here, the roof frame is supported by the strut portion via the laminated rubber bearing and is supported by the stand portion via the sliding bearing. As a result, the roof frame is seismically isolated. Therefore, the seismic performance of the roof frame is improved.

Further, the weight of the roof frame (vertical load) is supported by a plurality of support columns and stands. Therefore, in the present invention, the cross-sectional area of the strut portion can be reduced as compared with the case where the weight of the roof load is supported only by the strut portion.

Further, as described above, the roof frame is supported by the strut portion via the laminated rubber bearing and is supported by the stand portion via the sliding bearing. Therefore, the horizontal force acting on the roof frame during an earthquake is mainly transmitted to the strut portion via the laminated rubber bearing, and is basically not transmitted to the stand portion. Therefore, the horizontal force transmitted from the roof frame to the stand portion during an earthquake is reduced, and the design of the stand portion is simplified.

The seismic isolation structure according to claim 2 is the seismic isolation structure according to claim 1, and the strut portion is made of a steel frame.

According to the seismic isolation structure according to claim 2, the strut portion is made of steel. As a result, it is possible to shorten the construction period of how to build the support column.

The seismic isolation structure according to claim 3 is the seismic isolation structure according to claim 2, wherein the stand portion is made of concrete, and the support column portion and the stand portion are structurally integrated. To.

According to the seismic isolation structure according to claim 3, the stand portion is made of concrete. On the other hand, the strut portion is made of steel. The strut portion and the stand portion are structurally integrated. Thereby, for example, the expansion joint provided between the stand portion and the support portion can be omitted. In addition, it is possible to easily secure water stopping property between the stand portion and the strut portion.

The seismic isolation structure according to claim 4 is the seismic isolation structure according to any one of claims 1 to 3, and the support columns are arranged at four corners.

According to the seismic isolation structure according to claim 4, the support columns are arranged at the four corners of the seismic isolation structure. Here, since the plurality of support columns bear not only the weight of the roof frame but also the horizontal force acting on the roof frame during an earthquake, they are designed to have high rigidity and high yield strength. By arranging the high-rigidity and high-proof stress columns at the four corners of the seismic isolation structure in this way, the eccentricity of the seismic isolation structure can be reduced while the roof frame is efficiently supported by the plurality of columns. Can be done.

As described above, according to the present invention, it is possible to reduce the horizontal force transmitted from the roof frame to the stand portion at the time of an earthquake.

It is an elevation view which shows the seismic isolation structure which concerns on one Embodiment. It is a top view which shows the seismic isolation structure shown in FIG. FIG. 3 is a sectional view taken along line 3-3 of FIG. It is a cross-sectional view of line 4-4 of FIG.

Hereinafter, the seismic isolation structure according to the embodiment will be described with reference to the drawings.

(Seismic isolation structure)
FIG. 1 shows the seismic isolation structure 10 according to the present embodiment. The seismic isolation structure 10 is, for example, a large space structure (large space building) such as an arena or a stadium. The seismic isolation structure 10 includes a plurality of core frame portions (core frame portions) 20, a plurality of stand portions (stand portions) 30, and a roof frame 40. The core frame portion 20 is an example of a strut portion.

(Core frame part)
As shown in FIG. 2, the seismic isolation structure 10 is formed in a rectangular shape in a plan view. Steel-framed core frame portions 20 are provided at the four corners (corners) of the seismic isolation structure 10. These core frame portions 20 support the weight (long-term load) of the roof frame 40 and bear the horizontal force (short-term load) acting on the roof frame 40 during an earthquake.

The core frame portion 20 is formed in a triangular shape in a plan view by combining a plurality of frames 22. Each frame 22 has an adjacent steel frame column 24 and a steel frame beam 26 erected on the adjacent steel frame columns 24. Further, the frame 22 is provided with a brace (seismic brace) (not shown). As a result, the rigidity and proof stress of the core frame portion 20 are enhanced. The brace can be omitted.

(Stand part)
Stand portions 30 are provided between the adjacent core frame portions 20. The plurality of stand portions 30 together with the plurality of core frame portions 20 support the weight of the roof frame 40. Each stand portion 30 is made of reinforced concrete. Further, each stand portion 30 is arranged over the adjacent core frame portions 20. Further, each stand portion 30 is arranged so as to surround the central space 12 of the seismic isolation structure 10. A stadium, a stage, or the like is provided in the central space 12.

The stand portion 30 is formed in a rectangular shape in a plan view by combining a plurality of frames 32. The frame 32 has adjacent concrete columns 34 and concrete beams 36 erected on adjacent concrete columns 34. Further, the stand portion 30 is formed in a stepped shape that rises toward the outer periphery of the seismic isolation structure 10.

The frames 22 and 32 of the core frame portion 20 and the stand portion 30 adjacent to each other on the outer circumference of the seismic isolation structure 10 are structurally connected integral frames. Specifically, the steel beam 26 of the frame 22 is joined (rigidly joined) to the column-beam joint of the concrete column 34 of the frame 32. A roof frame 40 (see FIG. 1) covering the central space 12 is provided on the stand portion 30 and the core frame portion 20.

(Roof frame)
As shown in FIG. 1, the roof frame 40 is made of steel. Further, the roof frame 40 is formed in a rectangular shape in a plan view. The roof frame 40 is formed by combining a plurality of truss frames 42. The truss frame 42 has an upper chord member 42A and a lower chord member 42B facing each other in the vertical direction, and a bundle member 42C and an oblique member 42D connecting the upper chord member 42A and the lower chord member 42B.

As shown in FIG. 3, the roof frame 40 is supported by each core frame portion 20 via a plurality of laminated rubber bearings 60. Specifically, receiving portions 62 are provided on the steel frame columns 24 arranged on the outer periphery of the seismic isolation structure 10.

The receiving portion 62 extends from the upper part of the steel frame column 24 to the inside of the seismic isolation structure 10. Further, the tip portion of the receiving portion 62 is supported by the diagonal member 64. Laminated rubber bearings 60 are installed on the receiving portion 62, respectively.

The laminated rubber bearing 60 is, for example, a laminated rubber containing a lead plug or a natural rubber-based laminated rubber. The lower flange portion 60L of the laminated rubber bearing 60 is joined to the receiving portion 62 by a bolt or the like (not shown).

On the other hand, the bundle member 42C of the roof frame 40 is placed on the upper flange portion 60U of the laminated rubber bearing 60. The bundle member 42C is joined to the upper flange portion 60U of the laminated rubber bearing 60 by a bolt or the like (not shown). The laminated rubber bearing 60 supports the roof frame 40 so as to be horizontally displaceable with respect to the core frame portion 20. Further, the horizontal force acting on the roof frame 40 at the time of an earthquake is transmitted to the core frame portion 20 via the laminated rubber bearing 60.

The core frame portion 20 is provided with a seismic isolation damper (not shown). The seismic isolation damper connects the core frame portion 20 and the roof frame 40. As a result, the horizontal displacement of the roof frame 40 at the time of an earthquake is attenuated. The seismic isolation damper can be omitted.

As shown in FIG. 4, the roof frame 40 is supported by the stand portion 30 via a plurality of sliding bearings 70. Specifically, receiving portions 72 are provided on the concrete columns 34 arranged on the outer periphery of the seismic isolation structure 10.

The receiving portion 72 extends from the upper part of the concrete pillar 34 to the inside of the seismic isolation structure 10. Further, the receiving portion 72 is supported from below by the rib-shaped wall portion 74. Sliding bearings 70 are installed on the receiving portions 72, respectively.

The sliding bearing 70 is, for example, a low friction elastic sliding bearing. The sliding bearing 70 has a sliding plate 70A fixed to the receiving portion 72 and a sliding body 70B fixed to the lower end portion of the bundle member 42C of the roof frame 40 and slidably mounted on the sliding plate 70A. doing. The roof frame 40 is supported by the sliding bearing 70 so as to be horizontally displaceable with respect to the stand portion 30.

Further, the sliding bearing 70 cuts the horizontal edge between the roof frame 40 and the stand portion 30. As a result, the horizontal force acting on the roof frame 40 at the time of an earthquake is not transmitted to the stand portion 30, but is transmitted to the core frame portion 20 via the plurality of laminated rubber bearings 60.

The stand portion 30 is provided with a rolling bearing (not shown) that resists the pulling force acting on the roof frame 40 due to the wind load. The rolling bearing is, for example, a linear rolling bearing or the like. This rolling bearing connects the stand portion 30 and the roof frame 40. The rolling bearing may be provided as needed and can be omitted as appropriate.

(Action)
Next, the operation of this embodiment will be described.

As shown in FIG. 2, a plurality of core frame portions 20 are arranged on the outer periphery of the seismic isolation structure 10. Laminated rubber bearings 60 (see FIG. 3) are provided above the core frame portions 20. Further, a stand portion 30 is arranged between the adjacent core frame portions 20. A sliding bearing 70 (see FIG. 4) is provided on the upper portion of the stand portion 30.

Here, the roof frame 40 is supported by the core frame portion 20 via the laminated rubber bearing 60, and is supported by the stand portion 30 via the sliding bearing 70. As a result, the roof frame 40 is seismically isolated. Therefore, the seismic performance of the roof frame 40 is improved.

Further, the weight of the roof frame 40 is supported by a plurality of core frame portions 20 and stand portions 30. Therefore, in the present embodiment, the cross-sectional area of the core frame portion 20 can be reduced as compared with the case where the weight of the roof frame 40 is supported only by the core frame portion 20.

Further, as described above, the roof frame 40 is supported by the core frame portion 20 via the laminated rubber bearing 60 and is supported by the stand portion 30 via the sliding bearing 70. Therefore, the horizontal force acting on the roof frame 40 at the time of an earthquake is mainly transmitted to the core frame portion 20 via the laminated rubber bearing 60, and is basically not transmitted to the stand portion 30. Therefore, the horizontal force transmitted from the roof frame 40 to the stand portion 30 at the time of an earthquake is reduced, so that the design of the stand portion 30 is simplified.

Moreover, the core frame portions 20 are arranged at the four corners of the seismic isolation structure 10. Here, as described above, the plurality of core frame portions 20 are designed to have high rigidity and high yield strength because they bear not only the weight of the roof frame 40 but also the horizontal force acting on the roof frame 40 at the time of an earthquake. By arranging the core frame portions 20 having high rigidity and high yield strength at the four corners of the seismic isolation structure 10 in this way, the seismic isolation structure 10 is efficiently supported by the plurality of core frame portions 20 while the roof frame 40 is efficiently supported. Eccentricity can be reduced.

The core frame portion 20 is made of steel. As a result, in the present embodiment, the deformation performance of the core frame portion 20 that bears the horizontal force of the roof frame 40 at the time of an earthquake is enhanced as compared with the case where the core frame portion 20 is made of reinforced concrete. Therefore, the seismic performance of the seismic isolation structure 10 is improved.

Further, in the present embodiment, the construction period of the core frame portion 20 can be shortened as compared with the case where the core frame portion 20 is made of reinforced concrete.

On the other hand, the stand portion 30 is made of reinforced concrete. As a result, in the present embodiment, the vertical rigidity of the stand portion 30 is increased as compared with the case where the stand portion 30 is made of steel. Therefore, for example, when a concert is performed in the seismic isolation structure 10, the vibration of the stand portion 30 due to the jumping of the audience is reduced. As a result, the vibration propagated to the neighboring facilities of the seismic isolation structure 10 is reduced.

Further, the stand portion 30 and the core frame portion 20 are structurally integrated. Thereby, for example, the expansion joint provided between the stand portion 30 and the core frame portion 20 can be omitted. Further, it is possible to easily secure water stopping property between the stand portion 30 and the core frame portion 20.

(Modification example)
Next, a modified example of the above embodiment will be described.

In the above embodiment, the frames 22 and 32 of the adjacent core frame portion 20 and the stand portion 30 are structurally connected to form an integrated frame. However, the frames 22 and 32 of the core frame portion 20 and the stand portion 30 do not have to be structurally integrally connected. In this case, for example, the frames 22 and 32 of the core frame portion 20 and the stand portion 30 may be connected by a vibration damping damper to absorb seismic energy.

When the frames 22 and 32 of the adjacent core frame portions 20 and the stand portions 30 are not structurally integrally connected, for example, the frames 22 and 32 are appropriately connected by an expansion joint or the like.

Further, in the above embodiment, the core frame portions 20 are arranged at the four corners of the seismic isolation structure 10. However, the core frame portion 20 may be arranged on the outer peripheral portion other than the four corners of the seismic isolation structure 10. At this time, the stand portion 30 is appropriately arranged between the adjacent core frame portions 20.

Further, in the above embodiment, the seismic isolation structure 10 is formed in a rectangular shape in a plan view. However, the shape of the seismic isolation structure may be a polygonal shape having a triangular shape or more in a plan view, or may be formed into a circular shape or an elliptical shape in a plan view.

Further, in the above embodiment, the core frame portion 20 as an example of the strut portion is made of a steel frame. However, the strut portion may be made of reinforced concrete, steel-framed reinforced concrete, or the like. In addition, the shape and arrangement of the support columns can be changed as appropriate.

Further, in the above embodiment, the stand portion 30 is made of reinforced concrete. However, the stand portion may be made of steel-framed reinforced concrete or steel-framed. Further, the shape and arrangement of the stand portion 30 can be changed as appropriate.

Further, the seismic isolation structure 10 according to the above embodiment is applicable not only to arenas, stadiums, and the like, but also to various seismic isolation structures.

Although one embodiment of the present invention has been described above, the present invention is not limited to such an embodiment, and one embodiment and various modifications may be used in combination as appropriate. Of course, it can be carried out in various modes as long as it does not deviate.

10 Seismic isolation structure 20 Core frame (support)
30 Stand 40 Roof frame 60 Laminated rubber bearing 70 Sliding bearing

Claims (4)

With multiple columns arranged on the outer circumference,
A plurality of laminated rubber bearings provided on the upper portions of the plurality of columns, and
A stand portion arranged between the adjacent strut portions and
A sliding bearing provided on the upper part of the stand and
A roof frame supported by the strut portion via the laminated rubber bearing and supported by the stand portion via the sliding bearing.
Seismic isolation structure with. The strut portion is made of steel.
The seismic isolation structure according to claim 1. The stand is made of concrete.
The strut portion and the stand portion are structurally integrated.
The seismic isolation structure according to claim 2. The strut portions are arranged at the four corners.
The seismic isolation structure according to any one of claims 1 to 3.