JP2001254532A - Mounting structure and mounting method of seismic isolation device - Google Patents

Abstract

(57) [Abstract] [PROBLEMS] To reduce the cross-sectional dimension of a seismic isolation device such as a laminated rubber to obtain more effective seismic isolation performance. SOLUTION: A seismic isolation device 11 is temporarily fixed in a space 12 for installing the seismic isolation device of a structure A with a gap between the seismic isolation device and a grout. By injecting and solidifying the material 13, the seismic isolation device 11
Is incorporated into the structure A.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mounting structure and a mounting method for a seismic isolation device suitable for use in incorporating a seismic isolation device such as a laminated rubber into a pillar or the like.

[0002]

2. Description of the Related Art In recent years, various seismic isolation devices have been developed for various structures, such as buildings, in order to minimize the shaking and the damage caused by the occurrence of an earthquake. As this seismic isolation device, a so-called laminated rubber having a structure in which an elastic body or a viscoelastic body and a steel plate are alternately laminated in the vertical direction is often used.

[0003] The laminated rubber is installed, for example, between a foundation of a structure and a main body of a structure constructed on the foundation, or is incorporated into a pillar of the structure. An example is shown in FIG.
This will be described with reference to FIG.
Is an upper connecting steel plate 5A having a plate shape above and below the seismic isolation part 4 in which the viscoelastic body 2 and the steel plate 3 are laminated, and having substantially the same diameter as the seismic isolation part 4.
A lower connecting steel plate 5B is provided.
A, the lower connecting steel plate 5B is integrally provided with a circular flange plate 6 having a predetermined diameter larger than that of the lower connecting steel plate 5B with bolts 7 or the like. Then, the laminated rubber 1 is formed of the upper connecting steel plate 5 of the upper and lower flange plates 6.
A, The flange plate 6 and a base plate 8 fixed to the structure A, which is disposed on the flange plate 6 and superposed thereon, are fastened by bolts 9 at a portion on the outer peripheral side of the lower connecting steel plate 5B. Thereby, it is fixed to the structure A.

[0004] When the laminated rubber 1 having the above structure is to be retrofitted to, for example, a pillar of a structure, the upper part of the pillar to which the seismic isolation rubber 1 is to be attached is supported by a support member, and a part of the pillar is cut to isolate the seismic isolation. Secure space for equipment installation. Next, the base plates 8, 8 are positioned at predetermined intervals while holding the base plates 8, 8 horizontally above and below the secured space for installing the seismic isolation device, and temporarily fixed. A grout material such as concrete is cast between the base plates 8, 8 and the cut surfaces of the columns, and the upper and lower pace plates 8, 8 are fixed to the cut portions of the columns. Next, after the poured grout material is solidified, the laminated rubber 1 is separated from the base plates 8 and 8.
Then, the base plate 8 and the flange plate 6 are fastened by bolts 9 to attach the laminated rubber 1 to the pillar of the structure.

In such a laminated rubber 1, when a large external force is input in the horizontal direction due to an earthquake or the like, the viscoelastic body 2 is deformed in the horizontal direction to attenuate the external force and suppress the swing of the structure A. be able to.

[0006]

However, the conventional structure for mounting a seismic isolation device as described above has the following problems. That is, in the laminated rubber 1, the flange plate 6 is the largest diameter portion in the laminated rubber 1, and it is needless to say that the diameter of the laminated rubber 1 is smaller than that of the portion in which the flange is to be incorporated. However, for example,
When incorporated between a part of a pillar, a pillar and a floor slab, a foundation pile and a foundation slab, etc., the diameter of the flange plate 6 of the laminated rubber 1 is determined by the cross-sectional dimension of an elongated member such as a pillar or a pile. Accordingly, it may not be possible to secure the minimum required diameter of the seismic isolation part 4 to obtain the predetermined seismic isolation performance.

In such a case, if the structure is newly constructed, it is conceivable to increase the diameter of the pillars or piles in accordance with the diameter of the seismic isolation part 4. -There is a problem that the cost is increased due to an increase in the cross-sectional area of the pile, and the indoor space is reduced. On the other hand, when the laminated rubber 1 is incorporated into an existing structure, it is impossible to increase the diameter of the pillars or piles, and as a result, the diameter of the seismic isolation part 4 cannot be secured. There is a problem that performance cannot be obtained.

The present invention has been made in view of the above circumstances, and has as its object to reduce the cross-sectional dimension of a seismic isolation device such as a laminated rubber to obtain more effective seismic isolation performance. It is an object of the present invention to provide a mounting structure and a mounting method for a seismic isolation device that can be used.

[0009]

According to a first aspect of the present invention, there is provided a structure for mounting a seismic isolation device to be incorporated into a structure, wherein the seismic isolation device is provided on the structure. It is characterized by comprising a seismic isolation device arranged in the installation space with a gap between the structure and a grout material injected and solidified into the gap between the structure and the seismic isolation device. And The invention according to claim 2 is characterized in that an anchor member extending from the seismic isolation device is embedded in the grout material. The invention according to claim 3 is characterized in that the anchor member is an anchor bolt whose tip is screwed to the seismic isolation device. The invention according to claim 4 is characterized in that a shear key for transmitting a shearing force extending from the seismic isolation device is embedded in the grout material. The invention according to claim 5 is characterized in that a reinforcing bar extending from the structure is embedded in the grout material. The invention according to claim 6 is that the seismic isolation device is temporarily fixed in the space for installing the seismic isolation device of the structure with a gap between the structure and the structure, and then the space between the structure and the seismic isolation device is fixed. The seismic isolation device is incorporated into a structure by injecting and solidifying a grout material into the gap.

According to the present invention, the seismic isolation device is temporarily fixed in the space where the seismic isolation device is installed on the structure with a gap between the structure and the seismic isolation device. Since the seismic isolation device is incorporated into the structure by injecting and solidifying grout material from the ground, a flange plate that protrudes greatly outward from the seismic isolation part when attaching the seismic isolation device as in the conventional example This eliminates the need for a space for overlapping the base plate and the base plate and a space for rotating bolts for fastening the base plate and the outer diameter of the seismic isolation device itself.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. <First Embodiment> FIGS. 1 to 4 show a first embodiment of the present invention. Here, an example in which a seismic isolation device is incorporated in a pillar is shown. In the following description, portions common to FIG. 7 shown as a conventional example are denoted by the same reference numerals.

FIG. 1 shows a part of a structure to which a structure for mounting a seismic isolation device is applied. In this figure, reference numeral A denotes a structure such as a building, and B denotes a rectangular column constituting the structure A. (Figure 2
Reference numeral 11) indicates a seismic isolation device. As shown in this figure, the seismic isolation device 11 is incorporated in a portion obtained by vertically cutting the middle of the pillar B over a predetermined length, that is, a seismic isolation device installation space 12 described later. Seismic isolation device 1
Reference numeral 1 denotes a so-called laminated rubber, which is provided above and below the seismic isolation part 4 with a plate-shaped upper connecting steel plate 5A and a lower connecting steel plate 5B having a diameter substantially the same as or slightly larger than that of the seismic isolation part 4. It has a configuration.

The seismic isolation unit 4 has a structure in which the viscoelastic body 2 and the steel plate 3 are alternately stacked in a plurality of layers in the vertical direction.
As the viscoelastic body 2, a material having a high damping performance such as natural rubber, rubber asphalt-based rubber, and high damping rubber is used. As the steel plate 3, other than a normal steel material, for example, a vibration damping steel plate or the like is used. Adopted.

As described above, the seismic isolation device 11 is incorporated in the seismic isolation device installation space 12 formed by cutting the middle of the column B up and down over a predetermined length.
The seismic isolation device installation space 12 includes a central device installation space main body 12A in which the seismic isolation device 11 itself is installed, and the seismic isolation device 11 and the pillar B when the seismic isolation device 11 is installed in the device installation space main body 12A. And upper and lower cut surfaces 12B, 12B formed between the upper and lower cut surfaces, respectively. Grouts for integrally fixing the seismic isolation device 11 to the column B are provided in the upper and lower gaps 12B, 12B. The material 13 is injected and solidified. Concrete, polymer resin, or the like is used as the grout material 13. The height H of the portion filled with the grout material 13, that is, the height H of the gap 12 </ b> B is determined based on the workability, the state of stress transmission between the grout material 13 and the reinforcing steel in the structural body such as the column B of the structure, and the like.

An anchor member such as an anchor bolt 14 extending from the upper connecting steel plate 5A and the lower connecting steel plate 5B of the seismic isolation device 11 is embedded in the grout material 13. As the anchor member, in addition to the anchor bolt 14, a straight reinforcing bar, a deformed reinforcing bar, or the like is used. As a means for fixing the anchor member to the upper connecting steel plate 5A or the like, welding or the like is used. However, when the anchor bolt 14 is used as the anchor member, the female screw provided on the upper connecting steel plate 5A or the lower connecting steel plate 5B is used. May be used. Also, the anchor member should not protrude outward from the seismic isolation device 11, or should the protruding amount be as small as possible, even if it protrudes.
It is attached to the upper connecting steel plate 5A or the like. The diameter and the number of the anchor members are determined based on the strength required for fixing to the grout material 13.

Further, the grout material 13 includes a pillar B of the structure.
A reinforcing bar 16 extending from the hole is buried. The reinforcing bar 16 includes a main bar 16a and a stirrup 16b. The reinforcing bar 16 was originally buried in the column B, and is a portion left when the column B is cut vertically. If the reinforcing bar 16 is cut by mistake with the concrete, a new reinforcing bar may be added to the cut portion of the reinforcing bar 16 by welding, and the added reinforcing bar may be embedded in the grout material 13. In addition, if necessary, hooks, nuts, mechanical protrusions, etc.
A device for preventing the grout material 13 from slipping out may be employed.

As described above, an anchor member is buried in the grout material 13 mainly to counter the tensile force caused by the bending moment between the grout material 13 and the seismic isolation device 11, but this anchor member alone is used. , Grout 1
When the shearing force transmitting force between the base 3 and the seismic isolation device 11 is insufficient, the shear key 17 is provided on the upper connecting steel plate 5A or the lower connecting steel plate 5B for transmitting the shearing force, and the shear key 17 is embedded in the grout material 13. May be.

As the shear key 17, for example, FIG.
As shown in (a), a member in which a suitably rigid member such as a plate 17a, a bolt or a nut is fixed to the lower connecting steel plate 5B by welding can be used. Further, as shown in FIG. 3B, when the lower connecting steel plate 5B is made by casting, the projections 17b are integrally formed, and the projections 17b are formed.
b may be used. Also, as shown in FIG.
A notch 5Ba is provided in the lower connecting steel plate 5B, and the notch 5Ba
Alternatively, a member having a suitably rigid member such as the plate 17c may be used. Further, as shown in FIG. 3D, a bolt 17 is attached to the female screw formed on the lower connecting steel plate 5B.
You may use what screwed the front-end | tip of d.

Next, a method of attaching the seismic isolation device 11 will be described. First, the middle of the pillar B is cut up and down over a predetermined length to obtain the seismic isolation device installation space 12. The seismic isolation device 11 is installed in the device installation space main body 12A at the center of the seismic isolation device installation space 12 thus obtained, and temporarily fixed (see FIG. 4).

When the seismic isolation device 11 is installed, for example, when using the anchor member and the anchor bolt 14 screwed to the lower connecting steel plate 5B or the upper connecting steel plate 5A, a plurality of screws screwed to the lower connecting steel plate 5B are used. The anchor bolt 14 of
In addition to supporting the seismic isolation device 11 at the time of installation, the plurality of anchor bolts 14 can be used for level adjustment and inclination adjustment by appropriately rotating each of the anchor bolts 14. When female screws are provided on the upper connecting steel plate 5A and the lower connecting steel plate 5B for fixing the anchor member, a flange assembly in which the upper or lower connecting steel plate and the flange plate are separated as shown in FIG. When the seismic isolation device of the type is used, the one from which the flange plate has been removed can be used as it is as the seismic isolation device for implementing the present invention, and furthermore, the upper connecting steel plate 5A and the lower connecting steel plate 5B
The female screw for fixing the flange plate, which is provided in advance, can be used as it is for fixing the anchor bolt.

Next, the central device installation space body 12
The grout material 13 is injected into the upper and lower gaps 12B, 12B formed between the seismic isolation device 11 temporarily fixed to A and the upper and lower cut surfaces of the column B, respectively, and solidified. The seismic isolation device 11 can be incorporated into the structure by the above series of procedures.

In such a seismic isolation device 11, when a horizontal external force is input due to an earthquake or the like, the upper portion and the lower portion of the seismic isolation device 11 are moved relative to the horizontal direction of the end of the column B. Displacement occurs. Then, upper connecting steel plate 5A of seismic isolation part 4
And the lower connecting steel plate 5B are connected to the anchor bolts 14 respectively.
Through the anchor member such as the shear key 17 and the grout material 13, the end Bb of the column B located above and the end Bc of the column B located below are displaced integrally with the upper connecting steel plate 5A. Horizontal relative displacement occurs between the lower connecting steel plate 5B and the lower connecting steel plate 5B. This relative displacement is transmitted to the seismic isolation part 4, and is attenuated by the deformation of each viscoelastic body 2, and as a result, the relative displacement of the column B in the upper part and the lower part of the seismic isolation device 11 is attenuated, As a result, the swing of the structure A can be suppressed.

In the mounting structure of the seismic isolation device 11 described above, the seismic isolation device 11 is temporarily fixed to the seismic isolation device installation space 12 formed by cutting the middle of the column B of the structure A up and down over a predetermined length. Grout material 13 is inserted into gaps 12B, 12B formed between the upper and lower cut surfaces of the pillar and the seismic isolation device 11 later.
The seismic isolation device is incorporated into the structure by injecting and solidifying, so that the flange plate 6 and the base plate 8 are overlapped and bolted to attach the seismic isolation device 11 as in the conventional example. 9 eliminates the need for any work such as fastening, and eliminates the need for a space for arranging the plates in an overlapping manner and for rotating the bolts. Therefore, the outer diameter of the seismic isolation device 11 itself, which includes accessories for mounting, can be reduced, and when the seismic isolation device 11 is incorporated into a portion having a small cross-sectional dimension, such as the column B, the cross-section of the seismic isolation unit 4 Since the maximum dimensions can be secured, sufficient seismic isolation performance can be obtained. In addition, in the case of a new construction, it is not necessary to increase the cross-sectional dimension of the pillar B in order to secure the cross-sectional dimension of the seismic isolation part 4, and the effective use of the space is not hindered.

In particular, when the structure A is an existing one,
In the conventional mounting structure as shown in FIG. 7, since the cross-sectional dimension of the part to be incorporated is small, even in the part where the laminated rubber enough to obtain sufficient seismic isolation performance cannot be applied,
The seismic isolation device 11 including the seismic isolation part 4 having a larger cross-sectional dimension can be incorporated, and the applicable range of the seismic isolation device 11 can be expanded.

<Second Embodiment> FIGS. 5 and 6 show a second embodiment of the present invention. Also in this embodiment, the same reference numerals are given to portions common to FIG. 7 shown as a conventional example.

FIG. 5 shows a part of a structure to which the mounting structure of the seismic isolation device according to the present invention is applied, and FIG. 6 shows VI-VI.
It is sectional drawing which follows a line. In the second embodiment, the seismic isolation device 20 can be easily replaced. By the way, in the mounting structure of the seismic isolation device shown in the first embodiment, the seismic isolation device 11 is basically not replaced. Here, seismic isolation devices 11 and 12
Explaining the concept of replacement of 0, the seismic isolation device may deteriorate the viscoelastic body 2 due to secular change, etc.
The idea that replacement is required every predetermined period has been dominant in the past, but in recent years, the need for replacement of seismic isolation devices has increased as technology has been considered in recent years, based on technological advances and actual use. But rather very low. As a result, in the above-described first embodiment, the seismic isolation device is basically not replaced. However, it does not mean that even the first embodiment cannot be replaced at all.
It is technically possible to replace them by using a means such as cutting a pillar or cutting a pillar like retrofit (existing renovation).

In the second embodiment shown here, the seismic isolation device 20 is temporarily fixed to the seismic isolation device installation space 12 formed by cutting the middle of the column B of the structure A up and down over a predetermined length. The basic part of incorporating the seismic isolation device 20 into a structure by injecting and subsequently solidifying the grout material 13 into the gaps 12B, 12B between the upper and lower cut surfaces of the column B and the seismic isolation device 20 is used. This is the same as the first embodiment described above.

The difference between the second embodiment and the first embodiment is that a rectangular column B and a circular seismic isolation device 2 are provided.
The point that the bolt 24 fixing the seismic isolation device 20 can be removed using the portion C that does not overlap with zero.

That is, on the upper and lower ends of the seismic isolation device 20, a rectangular flange plate 21 having substantially the same shape as the column B is provided.
Is attached to the flange plate 21. A rectangular intermediate plate 22 left on the column B side at the time of replacement is fixed to the flange plate 21 by bolts 24,. The bolt 24 is shown in FIG.
As shown in the figure, the rectangular column B and the circular seismic isolation device 20 are arranged at a portion C where they do not overlap. Intermediate plate 22
A nut 23 is attached to the column cut surface side by welding, and the tip of the bolt 24 is screwed to the nut 23. Instead of the nut 23, a female screw may be provided directly on the intermediate plate 22, and the bolt 24 may be screwed into the female screw. An anchor member such as the anchor bolt 14 and, if necessary, a shear key are attached to the intermediate plate 22 so as to extend toward the cut surface of the column B. These anchor members and shear keys are grout 1
3 buried. The seismic isolation device 20 shown here uses a type in which a flange plate and an upper connecting steel plate or a lower connecting steel plate are integrated.

Also in the mounting structure of the seismic isolation device according to the second embodiment, the space is temporarily fixed to the structure A by leaving a gap between the structure A and the seismic isolation device 20.
The seismic isolation device 20 is incorporated into the structure A by subsequently injecting and solidifying the grout material 13 into the structure 12B, so that the seismic isolation device 20 is installed in the same manner as in the first embodiment. The space for superposing the flange plate and the base plate, which protrude greatly from the seismic isolation part 4, and the space for rotating the bolts for fastening the flange plate and the base plate are not required, and the seismic isolation device 20 itself is correspondingly used. Can be reduced in outer diameter. Although the seismic isolation device 20 includes the flange plate 21 and the intermediate plate 22, these are used only for replacement, and are not used for installing the device. Therefore, the dimensions of the flange plate 21 and the intermediate plate 22 are much smaller than those of the conventional flange plate 6 and base plate 8.

The present invention is not limited to the above-described embodiment, and can be appropriately changed in design without departing from the spirit of the invention. For example, in the first embodiment that does not assume the above-described device replacement, an example is given in which a flange-integrated seismic isolation device 11 in which a flange plate and an upper connecting steel plate or a lower connecting steel plate are integrated, In the second embodiment on the premise that the device is replaced, the flange plate 21 is connected to the upper connecting steel plate 5A or the lower connecting steel plate 5B by bolts 7.
Although the example using the flange-attached seismic isolation device 20 to be attached to the vehicle is described, it is needless to say that the present invention is not limited to this. May be used, and as a second embodiment, a seismic isolation device integrated with a flange may be used. Also,
Regardless of whether or not the device replacement is assumed, when the present invention is applied, the conventional seismic isolation device 11 shown in FIG.
Instead of using the large circular flange plate 6 used in FIG. 7, instead of protruding beyond the seismic isolation part 4,
Alternatively, even in the case of protruding, a flange plate with a small amount of protruding can be separately attached and used. In this case, after the flange plate is attached, it can be used in the same manner as a flange-integrated seismic isolation device with a reduced flange. Further, in the case of a seismic isolation device of a flange assembly type, since the flange plate can be retrofitted to the seismic isolation part 4, an anchor bolt, a shear key, etc. are welded with the flange plate separated from the seismic isolation part. When mounted directly, the advantage is obtained that the adverse effect of heat is not exerted on the rubber constituting the viscoelastic body of the seismic isolation part 4.

[0032]

According to the first aspect of the present invention, a seismic isolation device is temporarily fixed in a space for installing a seismic isolation device of a structure with a gap between the structure and the seismic isolation device. The seismic isolation device is built into the structure by injecting and solidifying the grout material later in the gap between the two. A space for disposing the flange plate and the base plate and a space for rotating a bolt for fastening the flange plate and the base plate are not required, and the outer diameter of the seismic isolation device itself can be reduced accordingly. Therefore, even when the seismic isolation device is incorporated into a member such as a pillar or a pile with a small cross-sectional dimension, the plate does not protrude, so the cross-sectional dimensions of the seismic isolator itself can be maximized and sufficient seismic isolation performance can be achieved. Can be secured. In particular, when incorporating a seismic isolation device into an existing structure, the seismic isolation device cannot be applied to a part that would not be applicable due to the small cross-sectional dimensions of the mounting structure of the conventional seismic isolation device. It can be incorporated, and the range of application of the seismic isolation device can be expanded.

According to the second aspect of the present invention, the anchoring member extending from the seismic isolation device is embedded in the grout material, so that the fixing strength between the grout material and the seismic isolation device can be increased, and the seismic isolation device can be used. Can be firmly assembled to a structure.

According to the third aspect of the present invention, since the anchor bolt whose tip is screwed to the seismic isolation device is used as the anchor member, when the seismic isolation device is assembled to the structure, the anchor bolt is used for the seismic isolation device. In addition to support, it can be widely used for level adjustment and tilt adjustment,
Workability can be improved.

In the invention according to claim 4, since the shear key extending from the seismic isolation device for transmitting the shearing force is buried in the grout material, it is possible to increase the horizontal fixing strength between the grout material and the seismic isolation device. The seismic isolation function of the seismic isolation device can be more reliably exhibited.

According to the fifth aspect of the present invention, since the reinforcing bar extending from the structure is buried in the grout material, the mounting strength between the grout material and the structure can be made strong. In addition, the seismic isolation device can be firmly assembled to the structure.

In the invention according to claim 6, the seismic isolation device is temporarily fixed in the space for installing the seismic isolation device of the structure with a gap between the structure and the seismic isolation device. By injecting and solidifying grout into the above gap between the seismic isolation device and the structure,
The mounting structure of the seismic isolation device according to claim 1 can be easily obtained.

[Brief description of the drawings]

FIG. 1 is a vertical sectional view showing a mounting structure of a seismic isolation device according to a first embodiment of the present invention.

FIG. 2 is a sectional view taken along the line II-II in FIG.

FIGS. 3A to 3D are side views showing examples of a sheerk. FIG.

FIG. 4 is a sectional view showing an example of a construction procedure for obtaining a mounting structure of the seismic isolation device.

FIG. 5 is a vertical sectional view showing a mounting structure of a seismic isolation device according to a second embodiment of the present invention.

6 is a sectional view taken along the line VI-VI in FIG.

FIG. 7 is a vertical sectional view showing a mounting structure of a conventional seismic isolation device.

[Explanation of symbols]

 11 Seismic isolation device 12 Seismic isolation device installation space 12B Gap 13 Grout material 14 Anchor bolt (anchor member) 16 Reinforcing bar 17 Shear key 20 Seismic isolation device A Structure B Column

Claims (6)

[Claims] 1. A mounting structure for a seismic isolation device to be incorporated in a structure, wherein the seismic isolation device is disposed in a space provided in the structure with a gap between the seismic device and the structure. A mounting structure for a seismic isolation device, comprising: a grout material injected and solidified into the gap between the structure and the seismic isolation device. 2. The mounting structure according to claim 1, wherein an anchor member extending from the seismic isolation device is embedded in the grout material. 3. The mounting structure for a seismic isolation device according to claim 2, wherein the anchor member is an anchor bolt whose tip is screwed to the seismic isolation device. 4. The mounting structure for a seismic isolation device according to claim 2, wherein a shear key extending from the seismic isolation device for transmitting shearing force is embedded in the grout material. 5. The grout material has a reinforcing bar extending from the structure embedded therein.
4. The mounting structure of the seismic isolation device according to any one of 4. 6. A seismic isolation device is temporarily fixed in a space for installing the seismic isolation device of a structure with a gap between the structure and the seismic isolation device. A method of mounting a seismic isolation device, wherein the seismic isolation device is incorporated into a structure by injecting and solidifying a grout material.