JP2014020097A - Seismic isolator supporting structure and construction method for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a seismic isolator supporting structure capable of simplifying positional adjustment and level adjustment in installation, and a construction method for the same.SOLUTION: A seismic isolator supporting structure 1 supports a seismic isolator 10 installed between lower and upper structures 21 and 22 of a structure, and includes a concrete pedestal 2 which is provided in the lower or upper structure 21 or 22, and a cylindrical anchor 3 which has a cylindrical body part 4 fixed to the pedestal 2 and which has an axial-direction end of the body part 4 connected to the seismic isolator 10.

Description

  The present invention relates to a seismic isolation device support structure and a construction method of the seismic isolation device support structure.

The seismic isolation device is, for example, laminated rubber in which rubber and iron plates are alternately stacked. In a structure such as a general building or plant equipment, between a lower structure such as a base plate and an upper structure on the building side. Installed.
For example, as shown in Patent Literature 1, the seismic isolation device is fixed to an upper structure or a lower structure by a plurality of anchor bolts. Patent Documents 2 and 3 disclose an example in which an anchor bolt is used for a foundation structure, although a seismic isolation device is not used.

JP 2011-231574 A JP-A-2005-9902 JP-A-1-304220

  When fixing the seismic isolation device using anchor bolts, it is necessary to adjust the position so that the anchor bolts do not interfere with the reinforcing bars placed inside the foundation concrete (pedestal). Since multiple anchor bolts are installed to fix the seismic isolation device, the position must be adjusted multiple times. Also, since the horizontal surface of the foundation concrete will be uneven, grout is injected between the upper surface of the foundation concrete and the lower surface of the seismic isolation device to level the contact surface between the foundation concrete and the seismic isolation device, It is necessary to adjust the level. Therefore, the fixing method of the seismic isolation device using the anchor bolt has been a factor that the construction period becomes longer and the cost increases.

  Furthermore, in a structure where a large number of seismic isolation devices such as a reactor building need to be installed, sufficient plane space for the foundation concrete is required to ensure reaction force. Each seismic isolation device is fixed to one foundation concrete, and if the required cross-sectional area of the foundation concrete increases, it may become difficult to establish the structure of the structure.

  The present invention has been made in view of such circumstances, and provides a seismic isolation device support structure and a construction method for the seismic isolation device support structure that can simplify position adjustment and level adjustment during installation. The purpose is to do.

In order to solve the above problems, the seismic isolation device support structure and the construction method of the seismic isolation device support structure of the present invention employ the following means.
That is, the seismic isolation device support structure according to the present invention is a seismic isolation device support structure that supports a seismic isolation device installed between a lower structure and an upper structure of the structure, wherein the lower structure or A concrete support provided on the upper structure, and a tubular main body is fixed to the support, and an axial end of the main body is connected to the seismic isolation device. .

  According to this invention, the seismic isolation device is connected to the axial end of the main body portion of the anchor portion, and the main body portion is fixed to the lower structure of the structure or the concrete support provided in the upper structure. Therefore, the seismic isolation device is supported by the structure via the anchor portion and the support portion. Since the main body portion of the anchor portion has a cylindrical shape, the anchor portion can play the same role as a plurality of anchor bolts arranged along the circumferential shape of the seismic isolation device. Moreover, since it is sufficient to install one anchor portion, it is easier to adjust the position of the seismic isolation device than when a plurality of anchor bolts are installed. Furthermore, since the seismic isolation device can be directly connected to the axial end of the cylindrical main body, there is no need to inject grout between the support and the seismic isolation device, making it easy to adjust the level of the seismic isolation device become.

In the above invention, the main body portion of the anchor portion may be installed inside the support portion.
According to this invention, the main body part of the anchor part is installed inside the support part made of concrete provided in the lower structure or the upper structure of the structure, and by setting the diameter of the main body part to the required minimum diameter, The cross-sectional area of the support portion can be suppressed.

In the above invention, the main body portion of the anchor portion may be installed on an outer periphery of the support portion.
According to this invention, the main body portion of the anchor portion is installed on the outer periphery of the concrete support portion provided in the lower structure or the upper structure of the structure. By forming the support part by placing concrete inside the anchor body, it is possible to create a support structure for the seismic isolation device, which eliminates the need for formwork for concrete placement and shortens the construction period. Can be

In the above invention, the main body portion of the anchor portion may be provided with a rod-shaped stud on an outer surface or an inner surface.
According to the present invention, the contact surface area between the concrete and the anchor portion is increased, the fixing force is increased, and the pulling resistance force of the anchor portion with respect to the support portion can be increased.

  Further, the construction method of the base isolation device support structure according to the present invention is a construction method of the base isolation device support structure for supporting the base isolation device installed between the lower structure and the upper structure of the structure. In the lower structure or the upper structure, a step of installing an anchor portion having a cylindrical main body portion in advance at a position where a support portion is provided, and the lower structure or the upper structure in which the anchor portion is installed Producing a support made of concrete on the body, and connecting the seismic isolation device to an axial end of the anchor part.

  According to this invention, the main body portion of the anchor portion has a cylindrical shape, and can play the same role as a plurality of anchor bolts arranged along the circumferential shape of the seismic isolation device. When installing the anchor part on the lower structure or upper structure, it is only necessary to install one anchor part. Therefore, it is easier to adjust the position of the seismic isolation device than when multiple anchor bolts are installed. Become. Further, since the seismic isolation device can be directly connected to the axial end of the cylindrical main body, the level adjustment of the seismic isolation device is facilitated.

  According to the present invention, the anchor portion has the cylindrical main body portion, and the main body portion is fixed to the concrete support portion. Therefore, position adjustment and level adjustment at the time of installation can be simplified.

It is a longitudinal cross-sectional view which shows the seismic isolation apparatus support structure which concerns on 1st Embodiment of this invention. It is a cross-sectional view which shows the seismic isolation apparatus support structure cut | disconnected by the II-II line | wire of FIG. It is a cross-sectional view which shows the seismic isolation apparatus support structure cut | disconnected by the III-III line | wire of FIG. It is a longitudinal cross-sectional view which shows the cylindrical anchor of the seismic isolation apparatus support structure which concerns on 1st Embodiment of this invention. It is a longitudinal cross-sectional view which shows the seismic isolation apparatus support structure which concerns on 2nd Embodiment of this invention. It is a cross-sectional view which shows the seismic isolation apparatus support structure cut | disconnected by the VI-VI line of FIG. It is a cross-sectional view which shows the seismic isolation apparatus support structure cut | disconnected by the VII-VII line of FIG.

Embodiments according to the present invention will be described below with reference to the drawings.
[First Embodiment]
Hereinafter, the seismic isolation device support structure 1 which concerns on 1st Embodiment of this invention is demonstrated using FIGS. 1-4.
The seismic isolation device 10 supported by the seismic isolation device support structure 1 includes a laminated rubber 11, and the laminated rubber 11 is formed by alternately laminating rubber and iron plates. In the seismic isolation device 10, plate-like flange portions 12 are installed at the upper and lower portions so as to sandwich the laminated rubber 11. The upper and lower flange portions 12 are parallel to each other. The diameter of the flange portion 12 is larger than that of the laminated rubber 11, and a through hole for the bolt 13 is formed in a portion of the flange portion 12 that protrudes from the laminated rubber 11. The bolt 13 also passes through the through-hole 7 (see FIG. 4) formed in the tubular anchor 3 and is tightened by a nut, whereby the seismic isolation device 10 and the tubular anchor 3 are connected. Although FIG. 1 shows an example in which a nut is fastened to the bolt 13 later, a cap nut is previously installed on one side of the through hole 7 of the cylindrical anchor 3 and the bolt 13 is fastened there. You may make it do.

  The seismic isolation device support structure 1 is provided in the lower structure 21 or the upper structure 22 of the structure and supports the seismic isolation device 10. Here, the structure is a general building such as a building or a plant such as a power generation facility. The lower structure 21 is a foundation plate provided on the ground, and the upper structure 22 is a floor, column, beam, wall, or the like of a building or the like installed on the upper part of the lower structure 21.

The seismic isolation device support structure 1 includes a concrete pedestal 2 formed on the lower structure 21 or the upper structure 22, a cylindrical steel tubular anchor 3, and the like. Although FIG. 1 shows the case where the seismic isolation device support structure 1 is provided in both the lower structure 21 and the upper structure 22, the present invention is not limited to this example, and is provided in only one of them. It may be done.
The pedestal 2 is an example of a support portion, and has a rectangular parallelepiped shape, for example, and is erected in a direction perpendicular to the horizontal plane portion of the lower structure 21 or the upper structure 22.

  The cylindrical anchor 3 includes a cylindrical main body portion 4, a plate-like flange portion 5 provided at one axial end of the main body portion 4, and a plurality of rod-like studs 6 provided on the surface of the main body portion 4. Etc.

  The main body 4 is installed inside the pedestal 2 and is fixed to the pedestal 2 and the lower structure 21 or the upper structure 22 by fixing concrete on the surface of the cylindrical anchor 3. The main body 4 is made of, for example, steel, but may be any material that can withstand the required strength, and may be made of a material other than steel.

  The main body 4 is embedded in the pedestal 2 so that the axial direction is perpendicular to the horizontal plane. When the cylindrical anchor 3 is provided on the pedestal 2 of the lower structure 21, the end of the main body 4 on the flange 5 side is provided so as to be exposed from the upper surface of the pedestal 2. When the cylindrical anchor 3 is provided on the pedestal 2 of the upper structure 22, the end of the main body 4 on the flange 5 side is provided so as to be exposed from the lower surface of the pedestal 2. The case where the cylindrical anchor 3 is provided on the pedestal 2 of the upper structure 22 will be described. When a cap nut is installed on one side of the through hole 7 of the cylindrical anchor 3, the end of the main body 4 is the pedestal. 2 may not be exposed from the bottom surface. That is, the surface of the flange portion 5 on which the cap nut is installed is in contact with or embedded in the pedestal 2, and the surface of the flange portion 5 opposite to the main body portion 4 may be exposed from the lower surface of the pedestal 2. .

  The main body 4 has, for example, a cylindrical shape with a circular cross section, and the diameter and thickness are determined by conditions such as pulling resistance. For example, the diameter of the main body 4 is determined so as to obtain a concrete fracture surface that has a pulling resistance equal to or greater than the pulling resistance by a plurality of anchor bolts that have been conventionally installed. For example, the cylindrical portion of the main body 4 is disposed at the same position as the conventional anchor bolt.

  The main body portion 4 is joined to the flange portion 5 by welding, for example, at one end portion in the axial direction. The main body 4 is connected to the seismic isolation device 10 via the flange 5. That is, since the main body 4 is connected to one surface side of the flange portion 5 by welding and the seismic isolation device 10 is connected to the other surface side of the flange portion 5, the diameter of the main body portion 4 is the lamination of the seismic isolation device 10. It can be determined without being affected by the rubber 11. For example, the diameter of the main body 4 can be smaller than that of the seismic isolation device 10.

  Conventionally, an anchor bolt penetrates outside the outer peripheral surface of the laminated rubber 11 in the flange portion 12 of the seismic isolation device 10 so as not to interfere with the laminated rubber 11 of the seismic isolation device 10, so that the seismic isolation device 10 becomes the pedestal 2. It was fixed. On the other hand, in the present embodiment, in consideration of conditions such as pulling-out resistance, the diameter of the main body 4 can be made smaller than the same position as that of the conventional anchor bolt arrangement, and hence smaller than the diameter of the seismic isolation device 10. In these cases, the cross-sectional area of the pedestal 2 can be reduced as compared with the conventional case.

  One end portion in the axial direction of the main body portion 4 to which the flange portion 5 is joined is perpendicular to the axial direction of the main body portion 4, and the flange portion 5 is also perpendicular to the axial direction of the main body portion 4. The flange portion 12 is connected to the flange portion 12 of the seismic isolation device 10 by, for example, bolt joining. Thereby, the cylindrical anchor 3 and the seismic isolation apparatus 10 are integrated.

  One end of the rod-like body of the stud 6 is connected to the outer surface or inner surface of the main body 4. The stud 6 and the main body 4 are connected by welding, for example. Note that the stud 6 and the main body 4 may be connected to each other by bolt connection by passing the stud 6 through a through hole (not shown) provided in the main body 4. The stud 6 is provided so that the axial direction coincides with the normal direction of the outer surface or inner surface of the main body 4, for example. The stud 6 is a steel bar or a reinforcing bar, and the surface of the stud 6 may be a smooth surface or irregularities may be formed. A plurality of studs 6 are installed on the main body 4. The arrangement of the studs 6 on the surface of the main body 4 and the number of the studs 6 are determined according to design conditions and the like.

  The shape of the main body 4 is not limited to a cylindrical shape, and may be a polygonal cylinder having a square cross section. Further, a plurality of ring-shaped members (not shown) are formed on the outer surface or inner surface of the main body portion 4 so that the axial direction of the surface of the main body portion 4 is repeatedly uneven, instead of the rod-shaped stud 6. May be provided parallel to each other on the outer surface or the inner surface of the main body 4. In addition, for example, the stud 6 may be provided inside the main body 4, or the plate-like members may be combined and installed in a cross beam shape. In addition, as long as the shape of the main body portion 4 is improved, a member having another shape may be provided on the outer surface or inner surface of the main body portion 4.

Next, the installation method of the seismic isolation apparatus support structure 1 is demonstrated.
First, the cylindrical anchor 3 is manufactured in advance at a factory or the like. The cylindrical anchor 3 is produced, for example, by welding a plate-like flange portion 5 to one axial end portion of the cylindrical main body portion 4 and welding a plurality of studs 6 to the surface of the main body portion 4. A through hole 7 for a bolt 13 for connecting to the seismic isolation device 10 is formed in the flange portion 5. A cap nut may be installed in advance on one side of the through-hole 7 of the cylindrical anchor 3 and the bolt 13 may be fastened there. And the produced cylindrical anchor 3 is carried in to the construction site of the structure where the seismic isolation device 10 is installed.

  In the installation site of the seismic isolation device 10, reinforcing bars for forming the pedestal 2 are assembled on the horizontal surface of the lower structure 21 or the upper structure 22. At this time, the cylindrical anchor 3 is installed together with the reinforcing bar so that the main body 4 of the cylindrical anchor 3 is arranged inside the pedestal 2. In the case of the pedestal 2 formed on the lower structure 21, the flange portion 5 is exposed on the upper surface side of the pedestal 2, and in the case of the pedestal 2 formed on the upper structure 22, the flange portion 5 is exposed on the lower surface side of the pedestal 2. A cylindrical anchor 3 is disposed on the side.

  Next, a mold is formed around the assembled reinforcing bars, and concrete is placed inside the mold. Then, when the placed concrete is hardened, the formwork is removed. Thereby, the base isolation device support structure 1 in which the cylindrical anchor 3 is integrated with the pedestal 2 is constructed. The seismic isolation device 10 is placed on a cylindrical anchor 3 installed on the pedestal 2. The seismic isolation device 10 may be placed on the flange portion 5 after forming the mold and before placing the concrete, or may be placed on the flange portion 5 after placing the concrete.

  According to the present embodiment, since the seismic isolation device 10 is placed on the tubular anchor 3, it is not necessary to inject grout after placing concrete, and the installation of the seismic isolation device support structure 1 can be performed by placing concrete. Complete. Therefore, the construction period can be shortened, and the labor required for installation can be reduced. In addition, when the seismic isolation device support structure 1 of this embodiment is applied, it does not mean that the grout is not injected at all. In this embodiment, the grout may be injected between the flange portion 5 and the pedestal 2.

  As described above, according to the present embodiment, the seismic isolation device 10 is not fixed with a plurality of anchor bolts as in the prior art, but is fixed with one cylindrical anchor 3. There are fewer members to handle, and construction is easier. For example, in the case of an anchor bolt, it is necessary to position one by one or to adjust the interference with the reinforcing bar, but in the case of the cylindrical anchor 3, it is possible to greatly reduce the effort required for positioning and adjusting the interference with the reinforcing bar. . As a result, the construction period is shortened and the cost is reduced.

  In the case of the tubular anchor 3, since the seismic isolation device 10 can be connected at the axial end of the tubular anchor 3 formed horizontally, the compression axial force of the seismic isolation device 10 can be transmitted to the tubular anchor 3. Therefore, the grout conventionally injected between the lower surface or upper surface of the seismic isolation device 10 and the pedestal can be made unnecessary. As a result, man-hours can be reduced, construction becomes easier, and costs can be reduced.

  In addition, since the seismic isolation device 10 can be arranged without waiting for the concrete strength to be developed when the pedestal 2 is produced, the production of the pedestal 2 and the arrangement of the seismic isolation device 10 can be performed in parallel. As a result, the construction period is shortened and the cost is reduced. Furthermore, the cross-sectional area of each pedestal 2 can be suppressed by setting the diameter of the main body 4 of the cylindrical anchor 3 to the necessary minimum diameter. As a result, in a structure where a large number of seismic isolation devices 10 such as a reactor building need to be installed, the structure of the structure can be established even when the necessary cross-sectional area of the foundation concrete is increased.

  Although the said embodiment demonstrated the case where the cylindrical anchor 3 was provided with the flange part 5 and connected with the seismic isolation apparatus 10 via the flange part 5, it is not necessary to necessarily provide the flange part 5. FIG. For example, the flange portion 12 of the seismic isolation device 10 may be directly connected to the axial end portion of the tubular main body portion 4 of the tubular anchor 3 without providing the flange portion 5. In this case, the cylindrical anchor 3 and the seismic isolation device 10 are assembled and integrated at a factory or the like, and are carried into the installation site of the seismic isolation device 10. Then, a member in which the cylindrical anchor 3 and the seismic isolation device 10 are integrated is installed on a reinforcing bar for forming the pedestal 2. Therefore, in the installation site of the seismic isolation device 10, the operation | work which connects the cylindrical anchor 3 and the seismic isolation device 10 becomes unnecessary.

[Second Embodiment]
Next, a second embodiment of the present invention will be described with reference to FIGS.
Although 1st Embodiment mentioned above demonstrated the case where the cylindrical anchor 3 was installed in the inside of the pedestal 2, this invention is not limited to this example. In 2nd Embodiment, as shown in FIG. 5, the steel cylindrical anchor 3 is arrange | positioned so that the outer side of the concrete part of the pedestal 2 may be enclosed.

  The cylindrical anchor 3 includes a cylindrical main body portion 4, an end surface portion 8 provided at one end portion in the axial direction of the main body portion 4, a rod-like stud 6 provided on the surface of the main body portion 4, and the like. The main body 4 may have a cylindrical shape or a square tube shape such as a square cross section. A part of the main body 4 is embedded in the lower structure 21 or the upper structure 22 and is fixed to the lower structure 21 or the upper structure 22. As shown in FIG. 6, an opening 9 for placing concrete is formed in the end surface portion 8 of the cylindrical anchor 3 installed in the lower structure 21.

The installation method of the seismic isolation apparatus support structure 1 which concerns on this embodiment is demonstrated.
First, the cylindrical anchor 3 is manufactured in advance at a factory or the like. The cylindrical anchor 3 is produced, for example, by welding a plate-like end surface portion 8 to one axial end portion of the cylindrical main body portion 4 and welding a plurality of studs 6 to the surface of the main body portion 4. A bolt through hole (not shown) for connecting to the seismic isolation device 10 may be formed in the end surface portion 8. Further, the seismic isolation device 10 may be connected to the tubular anchor 3 in advance at a factory or the like. And the produced cylindrical anchor 3 is carried in to the construction site of the structure where the seismic isolation device 10 is installed.

  Next, at the installation site of the seismic isolation device 10, the cylindrical anchor 3 is installed on the reinforcing bars assembled to form the lower structure 21 or the upper structure 22. At this time, a part of the main body 4 of the tubular anchor 3 is disposed inside the reinforcing bar portion of the lower structure 21 or the upper structure 22, and the remaining part is from the reinforcing bar portion of the lower structure 21 or the upper structure 22. It is exposed in the vertical direction.

  Next, concrete is placed on the lower structure 21 or the upper structure 22. At this time, concrete is also placed inside the cylindrical anchor 3. By filling the inside of the cylindrical anchor 3 with concrete, the compression strength of the pedestal 2 is improved. As the concrete hardens, the seismic isolation device support structure 1 in which the tubular anchor 3 is integrated with the lower structure 21 or the upper structure 22 is constructed.

  According to the present embodiment, unlike the first embodiment, the formwork is not required when the seismic isolation device support structure 1 is installed. Therefore, since the installation work of a formwork and the removal work of the formwork after concrete hardening can be omitted, a construction period becomes short.

1 Seismic isolation device support structure 2 Pedestal (support part)
3 cylindrical anchor (anchor part)
4 Body portion 5 Flange portion 6 Stud 8 End surface portion 10 Seismic isolation device 11 Laminated rubber 12 Flange portion 21 Lower structure 22 Upper structure

Claims (5)

A seismic isolation device support structure for supporting a seismic isolation device installed between a lower structure and an upper structure of a structure,
A concrete support provided on the lower structure or the upper structure;
An anchor portion in which a cylindrical main body is fixed to the support, and an axial end of the main body is connected to the seismic isolation device;
Seismic isolation device support structure.   The seismic isolation device support structure according to claim 1, wherein the main body portion of the anchor portion is installed inside the support portion.   The seismic isolation device support structure according to claim 1, wherein the main body portion of the anchor portion is installed on an outer periphery of the support portion.   The seismic isolation device support structure according to any one of claims 1 to 3, wherein the main body portion of the anchor portion is provided with a rod-shaped stud on an outer surface or an inner surface. A construction method of a base isolation device support structure for supporting a base isolation device installed between a lower structure and an upper structure of a structure,
In the lower structure or the upper structure, installing an anchor portion having a cylindrical main body portion in advance at a position where the support portion is provided;
Producing the support made of concrete in the lower structure or the upper structure in which the anchor portion is installed; and
Connecting the seismic isolation device to the axial end of the anchor portion;
Construction method of seismic isolation device support structure including

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