JP2016223221A - Mounting structure of base isolation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mounting structure that can easily be applied when installing any base isolation device in the base concrete and can improve durability of a base isolation device while reducing cost.SOLUTION: A bolt 26 inserted into a lower flange member 20 of a base isolation device 10 is fastened to a box nut 28 embedded in base concrete 1202 of a lower structure 14. The box nut 28 has a body 2804 formed of a female screw 2802 and an anchor plate part 2806 having a cross-sectional area larger than the cross-sectional area of the body 2804. An outer circumferential surface 2804A of the body 2804 is embedded in the base concrete 1202 while being displaceable in an axial direction for the base concrete 1202 by an unbonded material 30 constituting a displaceable part 29. A flattenable space securing member 32A for securing a space without the concrete is embedded in the base concrete 1202 in a surface 2806A of the anchor plate part 2806 around the body 2804.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a base isolation device mounting structure, and more particularly, to a base isolation device mounting structure, a cap nut-integrated mounting plate for base isolation device mounting, and a base nut for base isolation mounting.

The seismic isolation device includes a seismic isolation laminated rubber, and an upper flange member and a lower flange member that are respectively joined to the upper and lower structures of the seismic isolation laminated rubber.
The seismic isolation laminated rubber is formed by alternately laminating thin steel plates and thin rubber sheets, and has a characteristic of being hard in the vertical direction and softly deforming in the horizontal direction.
In such seismic isolation devices equipped with seismic isolation laminated rubber, a part of the upper structure is caused by a falling moment when the lifting force is generated in the upper structure due to the vertical motion component of the earthquake, or in a building with a large tower ratio. There is a case where a lifting force is generated in the building, or in a building having a brace, a lifting force may be generated in a portion of the upper structure immediately below the brace mounting portion due to the pulling force of the brace.
In this way, when a lifting force is generated in the upper structure, a tensile force acts on the seismic isolation laminated rubber.
If you try to resist this tensile force with the seismic isolation laminated rubber, you will expect the adhesive strength between the rubber sheet and the steel plate, which will damage the seismic isolation laminated rubber and make the seismic isolation device durable. There is a concern that it may be disadvantageous for improvement.
Therefore, the treatment of the tensile force acting on the seismic isolation laminated rubber is a problem.
Therefore, in Patent Document 1, in the upper flange member or the lower flange member, the upper flange member or the lower flange member is disposed at a portion between the outer periphery of the seismic isolation laminated rubber and the fixing portion to the upper structure or the lower structure. A technique for forming a thin-walled part or an opening for reducing the bending rigidity of the sheet has been proposed.
According to the above prior art, when a tensile force acts on the seismic isolation laminated rubber, the upper flange member or the lower flange member part is displaced following the direction of the tensile force to act on the seismic isolation laminated rubber. The pulling force to be suppressed is suppressed.

JP 2002-195327 A

However, the above prior art requires a design change such as forming a thin portion or an opening in the upper flange member or the lower flange member constituting the seismic isolation device, which increases design cost and manufacturing cost. It is difficult to apply to the device.
The present invention has been devised in view of the above circumstances, and the object of the present invention can be easily applied to any seismic isolation device, and aims to improve the durability of the seismic isolation device while reducing costs. An object of the present invention is to provide a seismic isolation device mounting structure, a cap nut-integrated mounting plate for mounting the seismic isolation device, and a cap nut for mounting the seismic isolation device.

In order to achieve the above-mentioned object, the invention according to claim 1 is the flange member in which the cap nut is embedded in at least one of the basic concrete of the upper structure and the lower structure and joined to the upper and lower sides of the seismic isolation laminated rubber, respectively. A bolt inserted through at least one of the flange members is screwed into the female screw of the cap nut, so that the seismic isolation device is attached to the foundation concrete, and the cap nut is a male screw of the bolt And a fixing plate portion provided at an end portion of the body portion and having a cross-sectional area larger than the cross-sectional area of the body portion, and is provided on an outer peripheral surface of the body portion. A displaceable portion is provided that enables relative displacement in the axial direction of the trunk portion with respect to the foundation concrete, and the fuser plate portion can be flatly deformed on a surface facing the flange member. Extends toward the flange member around the, and a space secured member to ensure no concrete space is provided in said base in the concrete.
According to a second aspect of the present invention, there is provided a body portion formed with a female screw that is screwed into a male thread of a bolt that is inserted through a bolt insertion hole of a mounting plate that is overlapped with a flange member of the seismic isolation device, and an end portion of the body portion A cap nut having a fixing plate portion having a cross-sectional area larger than the cross-sectional area of the barrel portion, and a base concrete provided on an outer peripheral surface of the barrel portion and embedded with the cap nut. A displaceable portion capable of relative displacement in the axial direction, and the fixing plate portion are provided on a surface directed to the mounting plate, and can be deformed flatly and extend toward the mounting plate around the trunk portion. A space securing member that secures a space free of concrete in the foundation concrete when the cap nut is embedded in the foundation concrete, and is located opposite to the fixing plate portion. End parts is characterized in that it is welded to the internal thread in the mounting plate is matched to the bolt insertion hole.
The invention according to claim 3 is a cap nut for attaching the seismic isolation device, which is attached to a bolt inserted through the flange member of the seismic isolation device and embedded in the foundation concrete, and the cap nut is connected to the male screw of the bolt. A body portion formed with a female screw to be screwed, and a fixing plate portion provided at an end portion of the body portion and having a cross-sectional area larger than the cross-sectional area of the body portion, on the outer peripheral surface of the body portion, A displaceable portion that enables relative displacement in the axial direction of the trunk portion with respect to the foundation concrete is provided, and the fixing plate portion is flatly deformable on a surface facing the flange member and A space securing member is provided that extends toward the flange member and that secures a space free of concrete in the foundation concrete when the cap nut is embedded in the foundation concrete. .

According to the first aspect of the present invention, the body portion is embedded in the foundation concrete in a state where the outer peripheral surface of the body portion can be displaced upward with respect to the foundation concrete by the displaceable portion, and the surface of the fixing plate portion and the flange A space free of concrete is secured between the members by the space securing member.
Therefore, when a lifting force acts on the upper structure, the trunk and the foundation concrete are displaced relatively, and the fixing plate and the foundation concrete are displaced relative to each other by deforming the space securing member. As a result, the seismic isolation device floats, or the superstructure rises relative to the seismic isolation device.
Therefore, it is advantageous in reducing the tensile force acting on the seismic isolation laminated rubber, minimizing damage to the seismic isolation laminated rubber, and improving the durability of the seismic isolation device.
In addition, the above effects can be achieved by changing only the cap nut without changing the seismic isolation laminated rubber and flange member of the seismic isolation device, so it can be easily applied to any seismic isolation device. This is advantageous in improving the durability of the seismic isolation device while reducing costs.
According to the invention described in claim 2, it is advantageous to increase the construction efficiency of the invention described in claim 1.
According to the third aspect of the invention, the tensile force acting on the seismic isolation laminated rubber is reduced, the damage to the seismic isolation laminated rubber is minimized, and the durability of the seismic isolation device is improved. It will be advantageous.

It is front sectional drawing which shows the attachment structure of the seismic isolation apparatus which concerns on 1st Embodiment, and shows the state from which the tensile force is not acting on the seismic isolation apparatus. It is front sectional drawing which shows the attachment structure of the seismic isolation apparatus which concerns on 1st Embodiment, and shows the state which the pulling force acted on the seismic isolation apparatus and the upper structure floated. It is a perspective view of the cap nut in a 1st embodiment. It is a perspective view which shows the cap nut and space securing member which were embedded in the basic concrete in 1st Embodiment. It is a perspective view of the space securing member in a 1st embodiment. It is sectional drawing of the space securing member of the modification 1. FIG. It is a perspective view of the cap nut of the modification 2. It is a perspective view of the cap nut of the modification 5. It is a perspective view of the cap nut integrated attachment plate for seismic isolation apparatus attachment. It is front sectional drawing which shows the attachment structure of the seismic isolation apparatus which concerns on 2nd Embodiment, and shows the state from which the tensile force has not acted on the seismic isolation apparatus. It is front sectional drawing which shows the attachment structure of the seismic isolation apparatus which concerns on 2nd Embodiment, and shows the state which the pulling force acted on the seismic isolation apparatus and the upper structure floated. It is front sectional drawing which shows the attachment structure of the seismic isolation apparatus which concerns on 3rd Embodiment, and shows the state where tensile force is not acting on the seismic isolation apparatus. It is front sectional drawing which shows the attachment structure of the seismic isolation apparatus which concerns on 3rd Embodiment, and shows the state which the pulling force acted on the seismic isolation apparatus and the upper structure floated.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a structure for mounting a seismic isolation device according to an embodiment of the present invention, a cap nut-integrated mounting plate for mounting a seismic isolation device, and a cap nut for mounting a seismic isolation device will be described with reference to the drawings.
(First embodiment)
As shown in FIG. 1, the seismic isolation device 10 is provided between the upper structure 12 and the lower structure 14.
In FIG. 1, reference numeral 1202 indicates basic concrete of the upper structure 12, and reference numeral 1402 indicates basic concrete of the lower structure 14.
In the present embodiment, the lower structure 14 is the foundation of a building, and the upper structure 12 is a building. However, the seismic isolation device 10 is also used for supporting an intermediate part in a vertical direction of a building, a bridge, and the like. The use is arbitrary.
The seismic isolation device 10 includes a seismic isolation laminated rubber 16, and an upper flange member 18 and a lower flange member 20 that are joined to the upper structure 12 and the lower structure 14 respectively joined to the upper and lower sides of the seismic isolation laminated rubber 16. It has.
The seismic isolation laminated rubber 16 is constituted by alternately laminating thin steel plates and thin rubber sheets. In addition, some of the seismic isolation laminated rubber 16 have a lead plug that absorbs vibration energy inserted therein and some that are not inserted. The present invention is applied to both, and in this embodiment the lead plug 17 is inserted. Has been inserted.
The seismic isolation device 10 is attached to the upper structure 12 by fastening the bolt 22 inserted through the upper flange member 18 to the female screw of the cap nut 24 embedded in the foundation concrete 1202 of the upper structure 12. 1 and 2, reference numeral 19 denotes an upper mounting plate disposed between the foundation concrete 1202 and the upper flange member 18, and a cap nut is used for mounting the seismic isolation device 10 to the upper structure 12. Various conventionally known mounting structures, such as a system that does not use 24, can be employed.

Further, the seismic isolation device 10 is attached to the lower structure 14 with the bolt 26 inserted through the lower flange member 20 being attached to the female screw 2802 (FIG. 3) of the cap nut 28 embedded in the foundation concrete 1402 of the lower structure 14. It is made by fastening, and this invention is applied to this attachment. 1 and 2, reference numeral 21 denotes a lower mounting plate disposed between the foundation concrete 1402 and the lower flange member 20.
As shown in FIG. 3, the cap nut 28 includes a barrel portion 2804 in which an internal thread 2802 is formed, and a fixing plate portion 2806 that is provided at the lower end of the barrel portion 2804 and has a cross-sectional area larger than that of the barrel portion 2804. Have.
The cross section of the body portion 2804 and the cross section of the fixing plate portion 2806 are arbitrary such as a rectangle or a polygon, but in the present embodiment, a circular shape is exhibited.
As shown in FIGS. 1 and 4, the body portion 2804 is embedded in the foundation concrete 1402 in a state where the outer peripheral surface 2804 </ b> A of the body portion 2804 can be displaced upward with respect to the foundation concrete 1402.

In the first embodiment, as shown in FIG. 4, the outer peripheral surface 2804 </ b> A of the body portion 2804 is covered with an unbond material 30 that prevents adhesion between the outer peripheral surface 2804 </ b> A and the foundation concrete 1402.
Further, the unbond material 30 enables displacement of the body portion 2804 in the foundation concrete 1402 upward.
Therefore, in the first embodiment, the outer peripheral surface 2804A of the trunk portion 2804 is provided on the outer peripheral surface 2804A, and the outer peripheral surface 2804A of the trunk portion 2804 can be displaced upward in the basic concrete 1402, in other words, the basic concrete 1402 is provided. On the other hand, a displaceable portion 29 that is capable of relative displacement in the axial direction of the body portion 2804 is formed of an unbonded material 30.
As such an unbond material 30, various conventionally known materials such as a butyl rubber tape can be used.

Further, the surface 2806A of the fixing plate portion 2806 around the body portion 2804, in other words, the surface 2806A of the fixing plate portion 2806 facing the lower mounting plate 21 or the lower flange member 20 around the body portion 2804 is made of concrete. A flat-deformable space securing member 32 </ b> A that secures no space is embedded in the foundation concrete 1402.
As shown in FIG. 5, the space securing member 32 </ b> A has a hole 3202 through which the body portion 2804 is inserted at the center thereof, and covers the surface 2806 </ b> A of the fixing plate portion 2806 facing upward on the outside in the radial direction of the body portion 2804. It has an annular plate shape.
The space securing member 32A is formed of a material that can be compressed and deformed. As such a material, various conventionally known materials such as foamed polyethylene can be used.
On the other hand, as shown in FIG. 1, the basic concrete 1402 in which the cap nut 28 is embedded has a small-diameter hole portion 1410 in which the body portion 2804 and the unbond material 30 of the cap nut 28 are located, a fixing plate portion 2806, and a space securing member. 32A has a large-diameter hole portion 1412 where the small-diameter hole portion 1410 and the large-diameter hole portion 1412 are located, and an annular contact surface 1414 facing downward in the vertical direction.

Next, the function and effect will be described.
When a lifting force is generated in the foundation concrete 1202 of the upper structure 12 due to the vertical motion component of the earthquake, or when a lifting force is generated in a part of the foundation concrete 1202 due to a falling moment in a building having a large tower ratio, or In a building having braces, when the foundation concrete 1202 of the upper structure 12 immediately below the brace attachment portion is lifted by the pulling force of the brace, this lifting force is introduced into the seismic isolation laminated rubber 16.
At this time, in the seismic isolation device mounting structure of the present embodiment, as shown in FIG. 1, the outer peripheral surface 2804 </ b> A of the trunk portion 2804 is relative to the foundation concrete 1402 in the axial direction of the trunk portion 2804 by the unbond material 30. The body portion 2804 is embedded in the foundation concrete 1402 in a state in which a general displacement is possible, and a space without concrete is secured above the surface 2806A of the fixing plate portion 2806 by the space securing member 32A.
Further, the adhesion force between the outer peripheral surface 2806B of the fixing plate portion 2806 and the basic concrete 1402 is small because the area of the outer peripheral surface 2806B of the fixing plate portion 2806 is small, and the outer peripheral surface 2806B and the basic concrete 1402 are easily separated from each other. It has become.

Therefore, when a lifting force is generated in the upper structure 12, the body portion 2804 of the cap nut 28 and the foundation concrete 1402 are relatively displaced, and the fixing plate portion 2806 and the foundation concrete 1402 are deformed relative to each other while the space securing member 32A is deformed. The seismic isolation device 10 can be lifted with respect to the lower structure 14.
That is, when a lifting force is generated in the upper structure 12, as shown in FIG. 2, the foundation concrete 1402 of the lower structure 14 remains stationary in the vertical direction, and the cap nut 28 The seismic isolation device 10 is displaced upward.
More specifically, the outer peripheral surface 2806B of the fixing plate portion 2806 and the foundation concrete 1402 are separated by the lifting force, the trunk portion 2804 moves upward in the small diameter hole portion 1410, and the fixing plate portion 2806 is the space securing member 32A. The inside of the large-diameter hole portion 1412 is moved upward until it abuts against the abutment surface 1414 while compressing.
That is, the cap nut 28 moves upward together with the lower flange member 20, the lower mounting plate 21 and the bolt 26, and the seismic isolation device 10 can be lifted.

Therefore, according to the mounting structure of the seismic isolation device of the present embodiment, when a lifting force is generated in the upper structure 12 and the lifting force is introduced into the seismic isolation laminated rubber 16, the seismic isolation laminated rubber 16 is The seismic isolation laminated rubber 16 can be lifted together with the structure 12, reducing the tensile force acting on the seismic isolation laminated rubber 16, minimizing damage to the seismic isolation laminated rubber 16, and improving the durability of the seismic isolation device 10. This is advantageous.
Further, according to the seismic isolation device mounting structure of the present embodiment, it is not necessary to change the design such as forming a thin portion or an opening in the upper flange member 18 or the lower flange member 20 as in the prior art.
That is, according to the mounting structure of the seismic isolation device of the present embodiment, without adding any hand to the seismic isolation laminated rubber 16, the upper flange member 18, and the lower flange member 20, which are the main parts of the seismic isolation device 10, Since the above-mentioned effect can be achieved by modifying only the cap nut 28, it can be easily applied to any seismic isolation device 10, and the durability of the seismic isolation device 10 can be improved while reducing costs. It will be advantageous.

(Modification 1)
Next, Modification 1 will be described with reference to FIG.
In the first modification, the configuration of the space securing member 32B is different from that of the first embodiment. That is, the space securing member 32B can be flatly deformed to secure a space for movement above the fixing plate portion 2806 in the basic concrete 1402 above the surface 2806A of the fixing plate portion 2806 around the trunk portion 2804. The second embodiment is the same as the first embodiment, and is similar to the first embodiment in that it has a hole 3202 through which the body portion 2804 is inserted and has an annular plate shape. This is different from the first embodiment in that it is not formed of a possible material.
That is, the space securing member 32B is formed in a hollow annular plate shape by a thin synthetic resin wall 3204 that can be broken.
According to the first modified example, when the tensile force is applied, the space securing member 32B is broken (broken), so that a space without concrete is secured above the fixing plate portion 2806, and the cap nut 28 is It can be displaced together with the bolt 26.
Therefore, similarly to the first embodiment, according to the structure for mounting the seismic isolation device using the first modification, the cap nut 28 moves upward together with the lower flange member 20 and the bolt 26, and the seismic isolation device 10 is Since it can float, it is advantageous in reducing the tensile force acting on the seismic isolation laminated rubber 16 and improving the durability of the seismic isolation device 10, and can be easily applied to any seismic isolation device 10. This is advantageous in improving the durability of the seismic isolation device 10 while reducing costs.

(Modification 2)
Next, Modification 2 will be described with reference to FIG.
In the second modification, the configuration of the displaceable portion 29 is different from that of the first embodiment. That is, instead of the unbonded material 30, the body portion 2804 is accommodated in the pipe 34 embedded in the foundation concrete 1402, so that the body portion 2804 can be displaced upward in the foundation concrete 1402. This is different from the first embodiment.
Therefore, in the modified example 2, the displaceable portion 29 that is provided on the outer peripheral surface 2804A of the trunk portion 2804 and allows the outer peripheral surface 2804A of the trunk portion 2804 to be displaced upward in the foundation concrete 1402 is configured by the pipe material 34. ing.
The tube material 34 is formed of a material having a small adhesion to concrete. As such a material, various conventionally known synthetic resin materials can be used.
Further, the tube material 34 may be formed of a thin material that can be broken. As such a material, various conventionally known synthetic resin materials can be used.
When the pipe material 34 is formed of a material having a low adhesion force to concrete, the pipe material 34 can be displaced upward together with the cap nut 28 and the bolt 26 when a tensile force is applied, and the pipe material 34 can be broken. In the case of being formed of a thin material, when the pulling force is applied, the tube material 34 is broken, so that the cap nut 28 can be displaced upward together with the bolt 26.

Therefore, according to the mounting structure of the seismic isolation device using the modified example 2, the cap nut 28 moves upward together with the lower flange member 20 and the bolt 26 as in the first embodiment, and the seismic isolation device 10 is Since it can float, it is advantageous in reducing the tensile force acting on the seismic isolation laminated rubber 16 and improving the durability of the seismic isolation device 10, and can be easily applied to any seismic isolation device 10. This is advantageous in improving the durability of the seismic isolation device 10 while reducing costs.
As the displaceable portion 29, it is also possible to use a pipe material 34 whose outer peripheral surface adheres to concrete and whose inner peripheral surface is slidably or slidably contacted with the outer peripheral surface 2804A of the trunk portion 2804. is there.

(Modification 3)
In the first embodiment, the first modification, and the second modification, the outer peripheral surface 2804A of the trunk portion 2804 is provided on the outer peripheral surface 2804A, and the outer peripheral surface 2804A of the trunk portion 2804 can be displaced upward in the foundation concrete 1402. The case where the displaceable portion 29 is composed of the unbonded material 30 and the pipe material 34 and the outer peripheral surface 2804A of the trunk portion 2804 is separated from the foundation concrete 1402 by the displaceable portion 29 has been described.
However, the displaceable portion 29 of the present invention is such that the body portion 2804 becomes the foundation concrete 1402 in a state in which the outer peripheral surface 2804A of the body portion 2804 allows relative displacement in the axial direction of the body portion 2804 with respect to the foundation concrete 1402. Anything that can be embedded is acceptable.
For example, the outer peripheral surface 2804A of the body 2804 may be formed by a smooth surface with fine surface roughness, and the displaceable portion 29 may be configured by this smooth surface.
In this case, the outer peripheral surface 2804A of the trunk portion 2804 and the foundation concrete 1402 adhere to each other. However, when a tensile force acts on the cap nut 28, the outer circumferential surface 2804A of the trunk portion 2804 is separated from the foundation concrete 1402 and the present invention. The effect of. However, when configured as in the first embodiment, the first modification, and the second modification, when the pulling force is applied to the seismic isolation device 10, the upward movement of the cap nut 28 is made smoother. Is advantageous.

(Modification 4)
When a displaceable portion that allows relative displacement in the axial direction of the fixing plate portion 2806 with respect to the basic concrete 1402 is provided on the outer peripheral surface 2806B of the fixing plate portion 2806, similarly to the body portion 2804, a cap nut This is advantageous in that the upward movement of 28 is made smoother.
The displaceable portion provided on the outer peripheral surface 2806B of the fixing plate portion 2806 can be configured by the unbonded material 30 of the first embodiment, the pipe material 34 of the second modification, and the smooth surface of the third modification.
Therefore, Modification 4 is particularly effective when the thickness of the fixing plate portion 2806 is large and the area of the outer peripheral surface 2806B of the fixing plate portion 2806 is large.

(Modification 5)
Next, Modification 5 will be described with reference to FIG.
Modification 5 is the same as that of the first embodiment, or Modification 1 or Modification 2 or Modification 3, except that the pipe member 36 that covers the periphery of the fixing plate portion 2806 and the space securing member 32A (32B) is provided. It is.
That is, in the modified example 5, the displaceable portion 29 provided on the outer peripheral surface 2804A of the trunk portion 2804 and allowing the outer peripheral surface 2804A of the trunk portion 2804 to be displaced upward in the foundation concrete 1402 is the unbonded material 30 or the pipe material. 34 or a smooth surface.
In addition, a space securing member 32A (32B) is disposed on the surface 2806A of the fixing plate portion 2806 around the body portion 2804.
Furthermore, the pipe material 36 in which the fixing plate portion 2806 and the space securing member 32A (32B) are accommodated is embedded in the foundation concrete 1402.

According to Modification Example 5 as described above, the outer peripheral surface 2806B of the fixing plate portion 2806 is separated from the foundation concrete 1402. Therefore, compared with the first embodiment, Modification Examples 1 to 3, the foundation concrete 1402 is Thus, the fixing plate 2806 can be moved upward smoothly.
Therefore, when the fixing plate portion 2806 is thick and the area of the outer peripheral surface 2806B of the fixing plate portion 2806 is large, the modified example 5 is particularly effective as in the modified example 4.
Therefore, according to the mounting structure of the seismic isolation device using the modified example 5, as in the first embodiment, the tensile force acting on the seismic isolation laminated rubber 16 is reduced, and the durability of the seismic isolation device 10 is reduced. It is advantageous for improving the seismic isolation device, and can be easily applied to any seismic isolation device 10, and is advantageous for improving the durability of the seismic isolation device 10 while reducing costs.

(Cap nut integrated mounting plate for seismic isolation devices)
In the first embodiment, the lower mounting plate 21 and the plurality of cap nuts 28 may be assembled at the site. However, as shown in FIG. A plurality of cap nuts 28 provided with the member 32A (32B) may be inseparably integrated with the lower mounting plate 21.
That is, a plurality of cap nuts 28 provided with the displaceable portion 29 and the space securing member 32A (32B) and the cap nut integrated mounting plate 23 in which the lower mounting plate 21 is inseparably welded may be provided.
In this case, with the center of the bolt insertion hole 2102 of the lower mounting plate 21 and the center of the female screw 2802 of the cap nut 28 matched, the tip of the trunk portion 2804 of the cap nut 28 is the lower surface of the lower mounting plate 21. To be joined by welding.
According to the cap nut-integrated mounting plate 23, by using the one in which the plurality of cap nuts 28 and the lower mounting plate 21 are welded in advance, it is easy to install the plurality of cap nuts 28 at the actual construction site. Moreover, since it can be determined accurately, it is advantageous in improving the efficiency and accuracy of work.
In addition to the cap nut 28 of the first embodiment, all of the modified examples 1 to 4 can of course be applied to the cap nut 28 of the cap nut integrated mounting plate 23, and the lower mounting plate shown in FIG. The shape of 21, the arrangement structure and the number of cap nuts 28 are appropriately changed according to the specifications and installation location of the seismic isolation device 10.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIGS.
In the following embodiments, the same parts and members as those in the first embodiment are denoted by the same reference numerals, the description thereof is omitted, and different parts are mainly described.
In the second embodiment, as shown in FIG. 10, the upper flange member 18 of the seismic isolation device 10 is attached to the upper structure 12 via a cap nut 28 including a displaceable portion 29 and a space securing member 32A. This is different from the first embodiment.
The lower flange member 20 is attached to the lower structure 14 via a cap nut 24, and various conventionally known mounting structures such as a method that does not use the cap nut 24 are used to attach the seismic isolation device 10 to the lower structure 14. It can be adopted.

The seismic isolation device 10 is attached to the upper structure 12 with a bolt 22 inserted through the upper flange member 20 and the upper mounting plate 19 and a female screw 2802 of a cap nut 28 embedded in the foundation concrete 1202 of the upper structure 12 (see FIG. This is done by fastening to 3).
As shown in FIG. 3, the cap nut 28 has a trunk portion 2804 and a fixing plate portion 2806, and as shown in FIG. 4, the outer peripheral surface 2804 A of the trunk portion 2804 is formed between the outer peripheral surface 2804 A and the foundation concrete 1202. An unbondable material 30 is covered with an unbonded material 30 that prevents adhesion, and a displaceable portion 29 that enables relative displacement in the axial direction of the trunk portion 2804 with respect to the basic concrete 1202 is the same as in the first embodiment. It consists of

Further, the first surface 2806A of the fixing plate portion 2806 is surrounded by the surface 2806A around the body portion 2804. In other words, the first surface 2806A of the fixing plate portion 2806 is directed to the upper mounting plate 19 or the upper flange member 18 around the body portion 2804. As in the first embodiment, a flat deformable space securing member 32 </ b> A that secures a space without concrete is embedded in the foundation concrete 1402.
As shown in FIG. 5, the space securing member 32 </ b> A has a hole 3202 through which the body portion 2804 is inserted, and covers the surface 2806 </ b> A of the fixing plate portion 2806 facing downward on the outside in the radial direction of the body portion 2804. It has an annular plate shape and is made of a material that can be compressed and deformed.
On the other hand, as shown in FIG. 10, in the basic concrete 1202 in which the cap nut 28 is embedded, a small diameter hole portion 1210 in which the trunk portion 2804 and the unbond material 30 of the cap nut 28 are located, a fixing plate portion 2806, and a space securing member. 32A has a large-diameter hole portion 1212 where the small-diameter hole portion 1410 and the large-diameter hole portion 1412 are located, and an annular contact surface 1214 facing upward in the vertical direction.
Accordingly, the space securing member 32A is positioned between the surface 2806A of the fixing plate portion 2806 and the contact surface 1214 of the foundation concrete 1202, and a space without concrete is secured above the contact surface 1214 by the space securing member 32A. Has been.

Next, the function and effect will be described.
When a lifting force is generated in the foundation concrete 1202 of the upper structure 12 due to the vertical motion component of the earthquake, this lifting force is introduced into the seismic isolation laminated rubber 16.
At this time, in the seismic isolation device mounting structure of the present embodiment, as shown in FIG. 10, the outer peripheral surface 2804 </ b> A of the trunk portion 2804 is relative to the foundation concrete 1202 in the axial direction of the trunk portion 2804 by the unbond material 30. The body portion 2804 is embedded in the foundation concrete 1202 in a state in which a general displacement is possible, and a space without concrete is secured above the contact surface 1214 by the space securing member 32A.
Further, the adhesion force between the outer peripheral surface 2806B of the fixing plate portion 2806 and the basic concrete 1402 is small because the area of the outer peripheral surface 2806B of the fixing plate portion 2806 is small, and the outer peripheral surface 2806B and the basic concrete 1402 are easily separated from each other. It has become.

Therefore, when a lifting force acts on the upper structure 12, the body 2804 of the cap nut 28 and the foundation concrete 1402 are relatively displaced, and the fixing plate 2806 and the foundation concrete 1402 are deformed relative to each other while deforming the space securing member 32A. Therefore, the seismic isolation device 10 can be lifted.
That is, when a lifting force is generated in the upper structure 12, as shown in FIG. 11, the cap nut 28 remains stationary in the vertical direction together with the basic concrete 1402 of the lower structure 14 and the seismic isolation device 10, The upper structure 12 and the foundation concrete 1202 of the upper structure 12 are displaced upward.
More specifically, as shown in FIG. 11, the outer peripheral surface 2806B of the fixing plate portion 2806 and the foundation concrete 1202 are separated from each other by the lifting force, and the body portion 2804 and the small-diameter hole portion 1210 are relatively displaced in the vertical direction. Since this is possible, the foundation structure 120 and the base isolation device 10 are supported until the contact surface 1214 of the foundation concrete 1202 contacts the surface 2806A of the fixing plate portion 2806 while compressing the space securing member 32A. The concrete 1202 and the upper structure 12 move upward.

Therefore, according to the mounting structure of the seismic isolation device of the present embodiment, when a lifting force is generated in the upper structure 12, the upper structure 12 can be lifted with respect to the seismic isolation device 10, and the seismic isolation laminate This is advantageous in reducing the tensile force acting on the rubber 16, minimizing damage to the seismic isolation laminated rubber 16, and improving the durability of the seismic isolation device 10.
Further, according to the seismic isolation device mounting structure of the present embodiment, it is not necessary to change the design such as forming a thin portion or an opening in the upper flange member 18 or the lower flange member 20 as in the prior art.
That is, according to the mounting structure of the seismic isolation device of the present embodiment, without adding any hand to the seismic isolation laminated rubber 16, the upper flange member 18, and the lower flange member 20, which are the main parts of the seismic isolation device 10, Since the above-mentioned effect can be achieved by modifying only the cap nut 28, it can be easily applied to any seismic isolation device 10, and the durability of the seismic isolation device 10 can be improved while reducing costs. It will be advantageous.

  Moreover, the modification 1-5 of 1st Embodiment and the cap nut integrated attachment plate for seismic isolation apparatus attachment are applicable similarly to 2nd Embodiment. In this case, in the second embodiment, the cap nut-integrated mounting plate for mounting the seismic isolation device includes a plurality of cap nuts 28 including the displaceable portion 29 and the space securing member 32A (32B), and the upper mounting plate. 19 is a cap nut integrated mounting plate that is inseparably welded to 19.

(Third embodiment)
Next, a third embodiment will be described with reference to FIGS.
In the third embodiment, the first embodiment and the second embodiment are added.
That is, as shown in FIG. 12, in the third embodiment, the lower flange member 20 of the seismic isolation device 10 includes a displaceable portion 29 and a space securing member 32A, as in the first embodiment. The upper flange member 18 of the seismic isolation device 10 is connected to the displaceable portion 29 and the space securing member 32A in the same manner as in the second embodiment by being attached to the foundation concrete 1402 of the lower structure 14 via the cap nut 28. It is attached to the foundation concrete 1202 of the upper structure 12 via a cap nut 28 provided.

Therefore, when a lifting force is generated in the upper structure 12, as shown in FIG. 13, when the foundation concrete 1402 and the seismic isolation device 10 of the lower structure 14 are viewed, the foundation concrete 1402 is stationary in the vertical direction. The cap nut 28 disposed on the lower surface of the lower mounting plate 21 is displaced upward together with the upper structure 12 and the seismic isolation device 10.
Further, when the seismic isolation device 10 and the foundation concrete 1202 of the upper structure 12 are viewed, the cap nut 28 disposed on the upper surface of the upper mounting plate 19 maintains a stationary state in the vertical direction together with the seismic isolation device 10. The upper structure 12 and the foundation concrete 1202 of the upper structure 12 are displaced upward with respect to the cap nut 28 in a stationary state.
Therefore, according to the third embodiment, in addition to the same effects as those of the first embodiment, the upper structure 12 is compared with the first embodiment and the second embodiment. The amount of upward displacement can be secured, the tensile force acting on the seismic isolation laminated rubber 16 is reduced, the damage to the seismic isolation laminated rubber 16 is minimized, and the durability of the seismic isolation device 10 is improved. It becomes more advantageous in aiming at.

DESCRIPTION OF SYMBOLS 10 Seismic isolation device 12 Upper structure 1202 Foundation concrete 14 Lower structure 1402 Foundation concrete 16 Laminated rubber 18 for base isolation 18 Upper flange member 19 Upper mounting plate 20 Lower flange member 21 Lower mounting plate 22 Bolt 23 Cap nut integrated mounting plate 24 Cap nut 26 Bolt 28 Cap nut 2802 Female screw 2804 Body 2804A Outer peripheral surface 2806 Fixing plate portion 2806A Upper surface 2806B Outer peripheral surface 30 Unbonded material (displaceable portion 29)
32 Space Securing Member 3202 Hole 3204 Wall 34 Tube Material (Displaceable Part 29)
36 pipes

Claims (13)

A cap nut is embedded in at least one foundation concrete of the upper structure and the lower structure,
The seismic isolation device is attached to the foundation concrete by bolting the bolt inserted through at least one of the flange members joined to the upper and lower sides of the seismic isolation laminated rubber into the female screw of the cap nut. Structure,
The cap nut has a barrel portion formed with a female screw that is screwed into a male screw of the bolt, and a fixing plate portion that is provided at an end portion of the barrel portion and has a cross-sectional area larger than the cross-sectional area of the barrel portion. And
On the outer peripheral surface of the trunk part, a displaceable part that enables relative displacement in the axial direction of the trunk part with respect to the basic concrete is provided,
A space securing member for securing a space free of concrete in the foundation concrete, wherein the fixing plate portion is flatly deformable on a surface directed to the flange member and extends toward the flange member around the trunk portion. Is provided,
A structure for mounting a seismic isolation device. A body part formed with a female thread to be screwed into a male thread of a bolt that is inserted through a bolt insertion hole of a mounting plate that is overlapped with a flange member of the seismic isolation device, and a disconnection of the body part provided at an end of the body part A cap nut having a fixing plate portion having a cross-sectional area larger than the area;
A displaceable portion that is provided on the outer peripheral surface of the barrel portion, and capable of relative displacement in the axial direction of the barrel portion with respect to the basic concrete in which the cap nut is embedded;
The fixing plate portion is provided on a surface directed to the mounting plate, can be deformed flat, extends toward the mounting plate around the trunk portion, and the base concrete is embedded when the cap nut is embedded in the basic concrete. A space securing member that secures a space without concrete inside,
The end portion of the body portion located opposite to the fixing plate portion is welded to the mounting plate with the female screw aligned with the bolt insertion hole.
A cap nut-integrated mounting plate for mounting seismic isolation devices. A cap nut attached to a bolt inserted through the flange member of the seismic isolation device and embedded in the foundation concrete,
The cap nut has a barrel portion formed with a female screw that is screwed into a male screw of the bolt, and a fixing plate portion that is provided at an end portion of the barrel portion and has a cross-sectional area larger than the cross-sectional area of the barrel portion. And
On the outer peripheral surface of the trunk part, a displaceable part that enables relative displacement in the axial direction of the trunk part with respect to the basic concrete is provided,
The fixing plate portion is flatly deformable on the surface facing the flange member, extends toward the flange member around the trunk portion, and the cap nut is embedded in the basic concrete when the cap nut is embedded in the basic concrete. A space securing member that secures a space without concrete is provided,
A cap nut for attaching a seismic isolation device. The displaceable portion is made of an unbonded material that covers the outer peripheral surface of the trunk portion and prevents adhesion between the outer peripheral surface and the foundation concrete.
The seismic isolation device mounting structure according to claim 1, the cap nut-integrated mounting plate for seismic isolation device mounting according to claim 2, or the cap nut for seismic isolation device mounting according to claim 3. The displaceable part is composed of a tube material that accommodates the body part and enables displacement in the axial direction of the body part in the foundation concrete.
The seismic isolation device mounting structure according to claim 1, the cap nut-integrated mounting plate for seismic isolation device mounting according to claim 2, or the cap nut for seismic isolation device mounting according to claim 3. The tube material is formed of a material having a small adhesion to the foundation concrete.
The seismic isolation device mounting structure according to claim 5, a cap nut-integrated mounting plate for mounting the seismic isolation device, or a cap nut for mounting the seismic isolation device. The pipe is formed of a thin material that can be broken,
The seismic isolation device mounting structure according to claim 5, a cap nut-integrated mounting plate for mounting the seismic isolation device, or a cap nut for mounting the seismic isolation device. The displaceable part is composed of a smooth surface that forms the outer peripheral surface of the trunk part.
The seismic isolation device mounting structure according to claim 1, the cap nut-integrated mounting plate for seismic isolation device mounting according to claim 2, or the cap nut for seismic isolation device mounting according to claim 3. The space securing member has a hole through which the body portion is inserted at the center thereof, and has an annular plate shape covering the surface of the fixing plate portion.
The seismic isolation device mounting structure according to any one of claims 1 to 8, a cap nut-integrated mounting plate for seismic isolation device mounting, or a cap nut for seismic isolation device mounting. The space securing member is formed of a compressible material,
The seismic isolation device mounting structure according to any one of claims 1 to 9, a cap nut-integrated mounting plate for mounting a seismic isolation device, or a cap nut for mounting a seismic isolation device. The space securing member is formed in a hollow shape by a thin synthetic resin wall that can be broken,
The seismic isolation device mounting structure according to any one of claims 1 to 9, a cap nut-integrated mounting plate for mounting a seismic isolation device, or a cap nut for mounting a seismic isolation device. Displaceable portions that enable relative displacement in the axial direction of the fixing plate with respect to the foundation concrete are provided on the outer peripheral surface of the fixing plate.
The seismic isolation device mounting structure according to any one of claims 1 to 11, a cap nut-integrated mounting plate for mounting a seismic isolation device, or a cap nut for mounting a seismic isolation device. A pipe material embedded in the foundation concrete and containing the fixing plate portion and the space securing member is further provided.
The seismic isolation device mounting structure according to any one of claims 1 to 11, a cap nut-integrated mounting plate for mounting a seismic isolation device, or a cap nut for mounting a seismic isolation device.

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