JP2007291765A - Installation structure of vibration control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an installation structure of a vibration control device, which can shorten a construction period by enabling the vibration control device to be easily introduced into a building by omitting construction labor on a job site. <P>SOLUTION: In this installation structure of the vibration control device, an upper frame member 12, which is laid between upper ends of a pair of column materials 10 and 10, a lower frame member 13, which is laid between lower ends of the column materials 10 and 10, and vertical frame members 14 and 14, which are erected between both the ends of the upper and lower frame members 12 and 13, are provided between the pair of column materials 10 and 10 in such a manner as to be assembled in a rectangular frame shape. The vibration control device 20 is built into an area which is surrounded by the upper and lower frame members 12 and 13 and both the vertical frame members 14 and 14, so that the vibration control device 20 and the pair of column materials 10 and 10 are integrated together. The pair of column materials 10 and 10, which is provided with the vibration control device 20, is erected and fixed on the top surface of a foundation 30 via column base metals 40 and 40. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a vibration damping device installation structure in which a pair of pillar members provided with a vibration damping device in advance are erected on a foundation.

Conventionally, the thing of patent document 1 is known as an example of the damping device of a building. In the vibration damping device described in Patent Document 1, a damper (vibration damping member) is interposed in the middle of a brace installed via a mounting gusset or the like in an internal space of a frame surrounded by columns and beams. This damper absorbs vibration energy in the event of an earthquake or the like, and is called a brace-type vibration damping device.
JP 2003-049557 A

However, in the vibration damping device of Patent Document 1, when the deformation of the building due to an earthquake or the like is small, the deformation transmitted to the vibration damping member (energy absorbing material) is also small, so the energy absorption amount of the vibration damping member is small, The damping force that attenuates the vibration is also reduced, and the damping structure does not work very effectively. For this reason, it was necessary to increase the number of locations of the vibration damping device.
And such a vibration control device must be installed in the internal space of the frame surrounded by pillars and beams at the site, for example, in the wall. There was a problem that it was difficult to introduce into the building. In addition, if it takes a lot of time to construct at the site in this way, it takes much time, so the construction period may be prolonged.

  Therefore, it has been desired to develop a technology capable of easily introducing a vibration damping device that can attenuate vibrations generated in the building more effectively.

  It is an object of the present invention to provide a vibration damping device installation structure that can easily introduce a vibration damping device into a building by omitting construction work on-site, thereby shortening the construction period. The purpose is to do.

The invention according to claim 1, for example, as shown in FIG. 1 and FIG. 2, between a pair of pillar members 10, 10, an upper frame member 12 constructed between upper ends of these pillar members 10, 10, A lower frame member 13 laid between the lower end portions of the column members 10 and 10 and vertical frame members 14 and 14 erected between both end portions of the upper and lower frame members 12 and 13 are assembled in a rectangular frame shape. Provided,
The vibration damping device 20 and the pair of column members 10 and 10 are integrated by incorporating the vibration damping device 20 in a portion surrounded by the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14. Has been
A pair of pillar members 10 and 10 provided with the vibration damping device 20 are fixed upright on the upper surface of the foundation 30 via pillar bases 40 and 40.

According to the first aspect of the present invention, the vibration damping device 20 is paired with the vibration damping device 20 by incorporating the vibration damping device 20 into a portion surrounded by the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14. Since the column members 10 and 10 are integrated with each other, it is possible to omit construction work on site. That is, for example, in a factory or the like, the upper and lower frames are formed between the pair of column members 10 and 10 on site by manufacturing the vibration damping device 20 and the pair of column members 10 and 10 in advance. There is no need to incorporate the members 12, 13 and the vertical frame members 14, 14, and the vibration control device 20.
The pair of pillar members 10 and 10 provided with the vibration damping device 20 in this way are erected and fixed to the upper surface of the foundation 30 via the column base metal members 40 and 40, so that the vibration damping device 20 is attached to the building. Since it can be introduced easily, the construction period can be shortened.

Further, since the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14 are assembled in a rectangular frame shape and provided between the pair of column members 10 and 10, the pair of column members 10 and 10. The two can be connected with a predetermined interval. That is, for example, the column bases 40 and 40 are fixed to the upper surface of the base 30 at the same interval as the pair of column members 10 and 10, and the pair of connected bases 40 and 40 are matched to the positions of the column base brackets 40 and 40. By only providing the column members 10, 10, the pair of column members 10, 10 can be erected easily and accurately.
Further, the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14 can also exhibit an effect as a reinforcing material for reinforcing the pair of column members 10 and 10.

The invention according to claim 2 is an installation structure of the vibration damping device 20 according to claim 1, for example, as shown in FIGS.
The vibration damping device 20 is disposed between a rectangular frame 21 having a rectangular frame shape, a pair of support portions 24, 24 provided to face the rectangular frame 21, and the pair of support portions 24, 24. A vibration control mechanism supported by the pair of support portions 24, 24,
The vibration damping mechanism is supported by the pair of support portions 24, 24, and when the pair of support portions 24, 24 are displaced, the vibration control mechanism swings around a substantially central portion between the pair of support portions 24, 24. A pendulum member 26 configured as described above, and a damping member 27 provided between the end of the pendulum member 26 and the rectangular frame 21 are provided.

  Here, the vibration suppression mechanism is a mechanism that can transmit the vibration generated in the building frame to the support portions 24 and 24 via the rectangular frame 21 and can suppress the vibration generated by the displacement of the support portions 24 and 24. Any structure may be used.

According to the second aspect of the present invention, when the building frame is deformed by vibration such as an earthquake, the pair of support portions 24 and 24 are displaced from the pair of column members 10 and 10 via the rectangular frame 21. . By the displacement of the pair of support portions 24, 24, the pendulum member 26 swings like a pendulum about the substantially central portion between the pair of support portions 24, 24, and the end portion of the pendulum member 26 is amplified. As a result, the displacement of the pair of support portions 24, 24 is amplified. Therefore, since the deformation of the vibration damping member 27 provided between the end of the pendulum member 26 and the rectangular frame 21 can be amplified, the vibration damping function can be used effectively from a small deformation of the building frame.
Thus, unlike the conventional case, it is not necessary to increase the number of locations where the vibration damping device 20 is arranged, and the construction work on site can be omitted.

The invention according to claim 3 is an installation structure of the vibration damping device 20 according to claim 1 or 2, as shown in FIGS. 4 (a) and 4 (b), for example.
The pair of pillar members 10 and 10 have one surface 10a and 10a flush with the one surface 12a, 13a, 14a and 14a of the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14 in plan view. And the other surfaces 10b, 10b are slightly projecting from the other surfaces 12b, 13b, 14b, 14b of the upper and lower frame members 12, 13 and the vertical frame members 14, 14.
Between the protruding portions of the pair of column members 10 and 10, for the face member 15 to be bonded to the other surfaces 12b, 13b, 14b and 14b of the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14, respectively. An affixing space 16 is formed.

  According to invention of Claim 3, by providing the face material 15 in the said pasting space 16, the surface of this face material 15 and the other surfaces 10b and 10b of said pair of pillar materials 10 and 10 are obtained. Become the same. Thereby, for example, a plate material (not shown) such as a gypsum board or a siding material can be securely attached to the both side surfaces 10a, 10a, 10b, 10b of the pair of column members 10, 10.

The invention according to claim 4 is the installation structure of the vibration damping device 20 according to claim 3, for example, as shown in FIG. 5 and FIG.
The face material 15 includes a joining plate member 15a for rigidly joining the rectangular frame 21 to the vertical frame members 14 and 14, and a plurality of covering plate members 15b for covering portions where the joining plate member 15a is not provided. , 15c.

According to the invention described in claim 4, the vertical frame members 14, 14 and the rectangular frame 21 are rigidly joined to each other by the joining plate member 15 a, so that the displacement of the pair of column members 10, 10 can be reduced in both longitudinal directions. Since it can transmit reliably to the rectangular frame 21 via the frame members 14 and 14, a damping function can be worked more effectively from the small deformation of a building frame.
Further, when the vertical frame members 14 and 14 and the rectangular frame 21 are rigidly bonded by the bonding plate material 15a, the portion where the bonding plate material 15a is not disposed has a relatively higher strength than the portion where the bonding plate material 15a is disposed. Although it becomes weak, the plurality of covering plate members 15b and 15c are arranged in a portion where the bonding plate member 15a is not arranged, and these covering plate members are the upper and lower frame members 12 and 13, and a part of both the vertical frame members 14 and 14, Since it is fixed to a part of the rectangular frame 21, the strength of the portion where the joining plate material 15a is not disposed can be reinforced by the plurality of covering plate materials 15b and 15c, and thus the vibration damping device 20 works in a balanced manner. be able to.

The invention according to claim 5 is the installation structure of the vibration damping device 20 according to any one of claims 1 to 4, for example, as shown in FIG.
The upper surfaces 10c and 10c of the pair of column members 10 and 10 are flush with the upper surface 12c of the upper frame member 12.

According to the invention described in claim 5, since the upper surfaces 10c, 10c of the pair of pillar members 10, 10 are flush with the upper surface 12c of the upper frame member 12, the pair of pillar members 10, 10 and a beam member (not shown) can be stably installed on the upper surfaces 10c, 10c and 12c of the upper frame member 12.
In addition, since the displacement of the beam material can be reliably transmitted to the rectangular frame 21 via the pair of column members 10 and 10 and the upper frame member 12, the vibration control function is further effective from a small deformation of the building frame. Can work on.

According to the present invention, since the vibration damping device and the pair of column members are integrated by incorporating the vibration damping device into the portion surrounded by the upper and lower frame members and both the vertical frame members, Construction work can be omitted. That is, for example, in a factory or the like, by previously manufacturing the vibration damping device and the pair of column members so as to be integrated, the upper and lower frame members and the two vertical frame members between the pair of column members at the site, There is no need to install a vibration control device.
And, because the pair of column members provided with the vibration damping device in this way can be easily introduced into the building by standing and fixing on the upper surface of the foundation via the column base metal, The construction period can be shortened.

  Embodiments of the present invention will be described below with reference to the drawings.

  First, the vibration damping device 20 of the present embodiment will be described. As shown in FIGS. 1 to 3, the vibration damping device 20 is provided between a pair of column members 10 and 10 that are erected on a foundation 30. Further, a beam material (not shown) is provided on the upper part of the pair of column members 10 and 10. Therefore, in this embodiment, the vibration damping device 20 is attached to a building frame constructed by a conventional wooden frame construction method.

The vibration damping device 20 is disposed between a rectangular frame 21 having a rectangular frame shape, a pair of support portions 24, 24 provided to face the rectangular frame 21, and the pair of support portions 24, 24. And a vibration damping mechanism supported by the pair of support portions 24, 24.
The rectangular frame 21 is formed by assembling a pair of left and right vertical frames 22 and 22 and a pair of upper and lower horizontal frames 23 and 23 into a rectangular frame shape. The end of the vertical frame 22 and the end of the horizontal frame 23 are formed. The parts are pin-coupled. Therefore, the rectangular frame 21 can be deformed so as to form a parallelogram when a force acts in the left-right direction. The vertical frame 22 and the horizontal frame 23 are made of metal such as iron or aluminum.
Further, the vertical frame 22 is formed in a belt plate-like outer peripheral plate portion 22a constituting the outer peripheral surface of the rectangular frame 21, and a belt plate shape formed at right angles to the inner surface of the outer peripheral plate portion 22a to which the support portion 24 is attached. The inner plate portion 22b is formed in a T-shaped cross section.
The horizontal frame 23 is formed at right angles to the belt-shaped outer peripheral plate portion 23a constituting the outer peripheral surface of the rectangular frame 21 and the inner surfaces of both end portions of the outer peripheral plate portion 23a. Inner plate portions 23b and 23b that are pin-coupled to end portions of 22b are provided, and a damping box 29 having a damping member 27 described later is attached to the inner plate portions 23b and 23b. .
Further, as shown in FIGS. 2 and 3, the wood 17 is fixed to the outer peripheral plate portions 22a, 22a, 23a, 23a of the vertical frames 22, 22 and the horizontal frames 23, 23 in advance at a factory or the like. The wood 17 is assembled in a frame shape so as to surround the vibration damping device 20.

Further, the longitudinal length of the rectangular frame 21 is shorter than the distance between the upper and lower frame members 12 and 13, and the lateral length of the rectangular frame 21 is shorter than the distance between the both vertical frame members 14 and 14. Furthermore, the thickness of the rectangular frame 21 is thinner than the thickness of the rectangular frame-shaped portion formed by the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14.
Therefore, the rectangular frame 21 of the vibration damping device 20 fits in a space surrounded by the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14. That is, it can be incorporated into a rectangular frame-shaped portion formed by the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14.

A pair of attachment portions 25 and 25 are attached to the inner plate portions 22b and 22b of the vertical frames 22 and 22 by bolts so as to face each other. Attachment portions 25a and 25a are formed on the attachment portions 25 and 25, and the support portions 24 and 24 are attached to the attachment surfaces 25a and 25a by bolts.
The support portion 24 includes two support plates 24a and 24a. A predetermined gap is formed between the distal end portions of the support plates 24a and 24a, and the base end portions are overlapped with each other. The overlapped portion is in contact with the mounting surface 9a, and is attached integrally with a bolt. Further, between the two support plates 24a, 24a, the central portion of the pendulum member 26 constituting the vibration damping mechanism is inserted and supported.

  The vibration damping mechanism is supported by the pair of support portions 24, 24, and when the pair of support portions 24, 24 are displaced, the vibration control mechanism swings about a substantially central portion between the pair of support portions 24, 24. The pendulum member 26 configured as described above, and the vibration damping member 27 provided between the end of the pendulum member 26 and the rectangular frame 21 are provided.

The pendulum member 26 has a plate-like shape and is formed in a vertically long octagonal shape, and is arranged with its longitudinal direction facing up and down. The left half of the central portion of the pendulum member 26 is sandwiched between the support plates 24 a and 24 a of the one support portion 24, and the right half is sandwiched between the support plates 24 a and 24 a of the other support portion 24. The pendulum member 26 is made of a metal such as iron or aluminum.
A center portion in the longitudinal direction of the pendulum member 26 is supported by the tip portions of the pair of support portions 24, 24. The pendulum member 26 has a rectangular frame 21 deformed by vibration such as an earthquake, and the pair of support portions 24, When 24 is displaced, it is configured to swing around a substantially central portion between the pair of support portions 24, 24.

  That is, a hole is formed in the center of the tip of each of the support plates 24a, 24a of one support part 24, and the hole is also opposed to the center of the tip of each of the support plates 24a, 24a of the other support part 24. Is formed. On the other hand, a hole is formed in the central portion of the pendulum member 26 so as to be separated from the left and right, and among these holes, the left hole is a long hole that is long to the left and right.

The shaft 28 can rotate the pendulum member 26 between the holes formed in the support plates 24 a and 24 a of the one support portion 24 and the one long hole formed in the center portion of the pendulum member 26. In addition, it is inserted so as to be slidable in the length direction of the long hole. The shaft 28 is formed of, for example, a bolt 28 having a threaded portion at the tip, and the bolt 28 is inserted into the hole, and a nut is screwed into the bolt 28 inserted into the hole.
In addition, the shaft 28 can rotate the pendulum member 26 in the hole formed in the support plates 24 a and 24 a of the other support part 24 and the other hole formed in the center part of the pendulum member 26. It is inserted. The shaft 28 is also formed by a bolt 28 having a threaded portion at the tip, and the bolt 28 is inserted through the hole, and a nut is screwed into the bolt 28 inserted through the hole.
As a result, the pendulum member 26 is supported by the pair of support portions 24 and 24 via the shafts 28 and 28, and the pendulum member 26 is displaced when the pair of support portions 24 and 24 are displaced by vibration such as an earthquake. In addition, it is configured to swing around a substantially central portion between the pair of support portions 24, in other words, a central portion between the shafts 28, 28.

The vibration damping box 29 is inserted between the vibration damping members 27 and 27, a box-shaped box 29a having an open top and bottom surface, a pair of vibration damping members 27 and 27 attached in the box 29a, and And a plate 27a fixed to the pair of damping members 27, 27. Moreover, as this damping member 27, the viscoelastic body 27 formed, for example with the high damping rubber is used.
Viscoelastic bodies 21 and 21 are fixed to the opposing inner surfaces of the box 29a by an adhesive or the like, respectively. A plate 27 a is inserted between the viscoelastic bodies 21 and 21, and the surface of the plate 27 a is fixed to the viscoelastic bodies 21 and 21. One end of the plate 27a protrudes from the box 29a, and this protruding one end is connected to the end of the pendulum member 26 by a bolt. Therefore, the damping member 27 is detachably attached to the end of the pendulum member 26 via the plate 27a.
Further, mounting plates 29b and 20a are projected from the end face of the box 29a. The vibration damping box 29 has the box 29a installed on the outer peripheral plate portion 23a of the horizontal frame 23, and the mounting plates 29b and 20a of the box 29a are connected to the inner plate portions 23b and 23b by bolts. It is attached to the approximate center. Therefore, the damping member 27 is detachably attached to the horizontal frame 23 of the rectangular frame 21 via the box 29a.
The box 29a, the plate 27a, etc. of the vibration damping box 29 are made of metal such as iron or aluminum.

As shown in FIGS. 1 and 2, the pair of pillar members 10, 10 are provided with an upper frame member 12 installed between upper ends of the pillar members 10, 10, and lower ends of the pillar members 10, 10. A lower frame member 13 installed between the upper frame members 12 and 13 and vertical frame members 14 and 14 provided between both ends of the upper and lower frame members 12 and 13 are assembled in a rectangular frame shape. , 13 and the vertical frame members 14, 14, the vibration damping device 20 is incorporated. That is, by incorporating the vibration damping device 20 in the region surrounded by the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14, the vibration damping device 20 and the pair of column members 10 and 10 are combined. And are integrated.
Therefore, if the vibration damping device 20 and the pair of column members 10 and 10 are manufactured in advance in a factory or the like, the upper and lower frame members 12 and 10 are placed between the pair of column members 10 and 10 at the site. 13, both vertical frame members 14, 14, and the vibration damping device 20 are not required to be incorporated, so that construction work on site can be omitted. The pair of pillar members 10 and 10 provided with the vibration damping device 20 in this way are erected and fixed to the upper surface of the foundation 30 via the column base metal members 40 and 40, so that the vibration damping device 20 is attached to the building. Since it can be easily introduced, the construction period can be shortened.
In addition, the upper frame member 12 and the vertical frame members 14 and 14 can also exhibit an effect as a reinforcing material that reinforces the pair of column members 10 and 10.

  In addition, in order to hold and fix the vibration damping device 20 at a predetermined portion between the wood 17 fixed to the outer peripheral plate portions 23a, 23a of the horizontal frames 23, 23 and the upper and lower frame members 12, 13. The fixed wood 18 is erected.

Further, the upper surfaces 10c, 10c of the pair of column members 10, 10 are flush with the upper surface 12c of the upper frame member 12, and the upper surfaces 12c of the pair of column members 10, 10 and the upper frame member 12 are The beam member can be stably installed, and the displacement of the beam member can be reliably transmitted to the rectangular frame 21 via the pair of column members 10 and 10 and the upper frame member 12.
When installing the beam member, a hole (not shown) for inserting the dowel member 19 provided on the upper part of the pair of column members 10 and 10 is provided in the beam member. The beam material is installed so that the dowel material 19 is inserted into the part.

In the case of the vibration damping device 20 configured as described above, as shown in FIG. 3, when deformation occurs in the building frame due to vibration such as an earthquake, the pair of column members 10 and 10 are connected via the rectangular frame 21. A pair of support parts 24 and 24 are displaced. By the displacement of the pair of support portions 24, 24, the pendulum member 26 swings like a pendulum about the substantially central portion between the pair of support portions 24, 24, and the end portion of the pendulum member 26 is amplified. As a result, the displacement of the pair of support portions 24, 24 is amplified.
Therefore, since the deformation of the vibration damping member 27 provided between the end of the pendulum member 26 and the rectangular frame 21 can be amplified, the vibration damping function can be effectively used from a small deformation of the building frame. ing.

On the other hand, the face material 15 is affixed between the pair of column members 10 and 10 in which the vibration damping device 20 is incorporated as described above. That is, as shown in FIGS. 4 (a) and 4 (b), the pair of pillar members 10 and 10 have one surface 10a and 10a in the plan view, the upper and lower frame members 12 and 13 and both the vertical frame members 14 and 14 is flush with one surface 12a, 13a, 14a, 14a, and the other surface 10b, 10b is the other surface 12b, 13b of the upper and lower frame members 12, 13 and the vertical frame members 14, 14. , 14b, 14b, and between the projecting portions of the pair of column members 10, 10, the other surfaces 12b, 13b of the upper and lower frame members 12, 13 and the vertical frame members 14, 14 are provided. An affixing space 16 for the face material 15 to be affixed to 14b and 14b is formed.
By providing the face material 15 in the affixing space 16 in this manner, the surface of the face material 15 and the other surfaces 10b, 10b of the pair of columnar materials 10, 10 are flush with each other. For example, a plate material such as a gypsum board or a siding material can be securely attached to the both side surfaces 10a, 10a, 10b, and 10b of the column members 10 and 10. In the present embodiment, a structural plywood is used as the face material 15 to be affixed to the affixing space 16.

Further, as shown in FIGS. 5 and 6, the face material 15 is provided with a joining plate material 15a for rigidly joining the rectangular frame 21 to the vertical frame members 14 and 14, and these joining plate materials 15a. A plurality of covering plate members 15b and 15c are provided for covering the portions that are not.
As shown in FIG. 4 and FIG. 5, the joining plate material 15 a extends over both the vertical frame members 14, 14 and the wood 17 fixed to the rectangular frame 21, and is formed in a vertically long shape. .
As shown in FIG. 5, the plurality of covering plate members 15b and 15c are a large first covering plate member 15b provided so as to cover the vibration damping device 20 between the bonding plate members 15a and 15a, and FIG. As shown in FIG. 2, the second cover plate members 15c and 15c are provided above and below the joint plate member 15a and the first cover plate member 15b. The second covering plate members 15 c and 15 c are provided so that the upper side reaches a height reaching the upper surface 12 c of the upper frame member 12 and the lower side reaches a height reaching the lower surface of the lower frame member 13.

  Then, by rigidly joining the vertical frame members 14 and 14 and the rectangular frame 21 with the joining plate material 15a in this way, the displacement of the pair of column members 10 and 10 is reduced. Therefore, the vibration control function can be made to work more effectively from the small deformation of the building frame.

  Further, when the vertical frame members 14 and 14 and the rectangular frame 21 are rigidly bonded by the bonding plate material 15a, the portion where the bonding plate material 15a is not disposed has a relatively higher strength than the portion where the bonding plate material 15a is disposed. Although it becomes weak, the plurality of covering plate members 15b and 15c are arranged in a portion where the bonding plate member 15a is not arranged, and these covering plate members are the upper and lower frame members 12 and 13, and a part of both the vertical frame members 14 and 14, Since it is fixed to a part of the rectangular frame 21, the strength of the portion where the joining plate material 15a is not disposed can be reinforced by the plurality of covering plate materials 15b and 15c, and thus the vibration damping device 20 works in a balanced manner. be able to.

  Next, the column base metal 40 of this Embodiment is demonstrated. As shown in FIG. 7, the column base metal 40 includes a base plate 41 part in which an insertion hole 41 a for inserting an anchor bolt 30 a protruding from the foundation 30 is formed, and the column bases of the pair of column members 10 and 10. A support plate 42 that abuts on and supports the lower surfaces of 11 and 11; a support leg 43 that is provided between the support plate 42 and the base plate 41 and supports the support plate 42 on the base plate 41; An insertion portion 44 is provided on the upper surface of the support plate 42 and is inserted into a slit 11 a formed in the column bases 11, 11 of the pair of column members 10, 10.

The insertion portion 44 is formed in a cross shape in plan view, and the slits 11a of the column bases 11 and 11 are also formed in a cross-section in accordance with the shape of the insertion portion 44. The pair of column members 10 and 10 and the pair of column base metal members 40 and 40 are connected by inserting the insertion portion 44 into the slit 11a.
Although not shown, a pin insertion hole is formed in the column bases 11 and 11 and the insertion portion 44 of the column members 10 and 10, and a drift pin is inserted into the pin insertion hole, whereby the column members 10 and 10 are formed. It is preferable to firmly connect the column base metal members 40 and 40 to each other.

On the other hand, the column bases 40, 40 are fixed to the upper surface of the foundation 30 with the same interval as that between the pair of column members 10, 10. Further, a support portion 45 for supporting the floor plate 31 at a height at which the floor plate 31 comes into contact with the lower surface of the lower frame member 13 is provided between the pair of column base metal members 40, 40.
As shown in FIG. 8, the support portion 45 is fixed to the upper surface of the foundation 30 and is provided between the pair of column bases 40, 40, and as shown in FIG. There are connecting metal fittings 45b and 45c that are integrally formed with the column base metal fittings 40 and 40 and connect the pair of column base metal fittings 40 and 40 at a predetermined interval.

As shown in FIG. 8, the base member 45a has the same length as the distance between the pair of column members 10 and 10, and the pair of column base metal members 40 and 40 are applied to both end surfaces. It is touched. The pair of column members 10 and 10 can be simply erected in accordance with the positions of the pair of column bases 40 and 40 provided at predetermined intervals in this manner. The vibration damping device 20 incorporated in between can be accurately installed at a predetermined position above the foundation 30. That is, the length dimension of the base member 45a and the length dimension of the lower frame member 13 are formed to be substantially the same.
Further, a base member 45a different from the base member 45a fixed between the pair of column base metal members 40, 40 is provided on the upper surface of the foundation 30, and a floor plate 31 is provided on the upper surface of the base member 45a. The floor of the building is constructed.

  As shown in FIG. 9A, the connection hardware 45b has the same length as the distance between the pair of column members 10, 10, and the pair of column base metal 40, 40 is abutted and fixed by means such as welding. Further, in order to adjust the height so that the floor plate 31 can be supported at a height contacting the lower surface of the lower frame member 13, a spacer plate material (not shown) or the like may be laid on the upper plate portion 46 of the connection hardware 45 b. it can. If the height can be adjusted in this way, it is preferable because it can correspond to any building having a different floor height. Further, as shown in FIG. 9B, the upper plate portion 47 has a thickness that can support the floor plate 31 at a height that abuts the floor plate 31 against the lower surface of the lower frame member 13 in advance as the connection metal 45c. You may form in.

The pair of column members 10 and 10 can be simply erected in accordance with the positions of the pair of column bases 40 and 40 provided at predetermined intervals in this manner. The vibration damping device 20 incorporated in between can be accurately installed at a predetermined position above the foundation 30. That is, the length dimension of the connection hardware 45b (45c) and the length dimension of the lower frame member 13 are formed to be substantially the same.
In addition, the connection bracket 45b (45c) and the pair of column base brackets 40, 40 are integrally formed in this manner, so that a predetermined interval is provided between the pair of column base brackets 40, 40. Since there is no need to perform the operation, it is possible to omit the construction work on site and to shorten the construction period.

Further, by providing a support portion 45 such as the base member 45a and the connecting hardware 45b, 45c between the pair of column base hardware 40, 40, as shown in FIGS. When supporting 31, not only the lower frame member 13 but also the upper frame member 12 and both vertical frame members 14, 14 assembled together with the lower frame member 13, and the upper and lower frame members 12, 13 and both vertical frame members The pair of pillar members 10 and 10 and the vibration damping device 20 fixed to the fourteen and fourteen can be stably supported on the floor plate 31.
In addition, since vibration generated in the floor plate 31 can be reliably transmitted to the vibration damping device 20 via the lower frame member 13, the vibration damping function of the vibration damping device 20 can be effectively used.

Next, the incorporation of the vibration damping device 20 into the pair of column members 10 and 10 and the installation method of the pair of column members 10 and 10 into which the vibration damping device 20 is incorporated will be described.
First, as shown in FIGS. 1 and 2, a vibration damping device 20 is assembled and integrated between a pair of pillar members 10 and 10 in advance in a factory or the like. At this time, the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14 are assembled and provided in a rectangular frame shape between the pair of column members 10 and 10. The vibration damping device 20 is incorporated in a portion surrounded by the vertical frame members 14 and 14.
As a result, the vibration damping device 20 can be held in a portion surrounded by the upper and lower frame members 12 and 13 and the both vertical frame members 14 and 14, so that the pair of column members 10 and 10 are connected to a pair of columns. The vibration damping device 20 incorporated between the pair of pillar members 10 and 10 can be accurately installed at a predetermined position above the foundation 30 only by being erected so as to be aligned with the positions of the legs 40 and 40.
Further, since the upper and lower frame members 12 and 13 and the vertical frame members 14 and 14 are assembled in a rectangular frame shape and provided between the pair of column members 10 and 10, the pair of column members 10 and 10 are arranged in a predetermined manner. It can be connected at intervals.

  Next, the joining plate member 15a and the plurality of covering plate members 15b and 15c are attached to the attaching space 16 formed between the protruding portions of the pair of pillar members 10 and 10. Of the plurality of covering plate members 15b and 15c, the second covering plate members 15c and 15c include the pair of column members 10 and 10 provided with the vibration damping device 20 and the pair of column base metal members 40 and 40. After being erected on the foundation 30 through, it is pasted.

Subsequently, as shown in FIGS. 8 and 9, a pair of column bases 40, 40 for supporting the pair of column members 10, 10 are arranged on the upper surface of the foundation 30 between the pair of column members 10, 10. And fix them at the same interval. At this time, the support portion 45 is provided between the pair of column base metal members 40, 40.
Then, after providing the pair of column base metal members 40, 40 and the support portion 45 on the upper surface of the foundation 30, as shown in FIG. 10, a plurality of floor plates 31, 31,. Form. In addition, the floor plate 31 is provided with a notch 31a for the insertion portion 44 of the column base hardware 40, 40 in advance.

  Thereafter, as shown in FIG. 11, the pair of column members 10, 10 provided with the vibration damping device 20 are erected on the foundation 30 so as to be supported by the pair of column base metal members 40, 40. As a result, the vibration damping device 20 incorporated between the pair of pillar members 10 and 10 can be accurately installed at a predetermined position above the foundation 30, and construction work on site can be omitted. Since the vibration damping device 20 can be easily introduced into the building, the construction period can be significantly shortened.

  Then, the second covering plate members 15c and 15c are attached to the upper and lower sides of both the joining plate members 15a and the first covering plate member 15b. Thereafter, a plate material such as a gypsum board is attached to the both side surfaces 10a, 10a, 10b, 10b of the pair of pillar members 10, 10 provided with the vibration damping device 20, or the pair of pillar members 10, 10 The building construction work is sequentially advanced by providing beam members on the upper surfaces 10c, 10c, and 12c of the upper frame member 12.

It is a perspective view which shows a pair of pillar material before a damping device is integrated. It is a perspective view which shows a pair of pillar material after a damping device is integrated. It is a front view which shows the operating state of a damping device. It is sectional drawing which shows the affixing space, (a) is the state in which the face material is not affixed, (b) is the state in which the face material was affixed. It is a perspective view which shows the state by which the joining board | plate material and the 1st coating board | plate material were stuck. It is a perspective view showing the state where the 2nd covering board material was stuck. It is a perspective view which shows a column base metal object. It is a perspective view which shows the installation state of a pair of column base metal and a base member. It is a perspective view which shows a pair of column base metal with which the connection hardware was formed integrally, (a) is the example, (b) is an example different from the thing of (a). It is a perspective view which shows the standing method of a pair of pillar material provided with the damping device. It is a perspective view which shows the installation state of a pair of pillar material provided with the damping device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Column material 12 Upper frame member 13 Lower frame member 14 Vertical frame member 20 Damping device 30 Foundation 40 Column base metal

Claims (5)

Between a pair of column members, an upper frame member erected between the upper end portions of these column members, a lower frame member erected between the lower end portions of the column members, and between both end portions of these upper and lower frame members. The vertical frame member is assembled in a rectangular frame shape,
By incorporating the vibration damping device into a portion surrounded by these upper and lower frame members and both vertical frame members, the vibration damping device and the pair of column members are integrated,
A structure for installing a vibration damping device, wherein a pair of column members provided with the vibration damping device are fixed upright on an upper surface of a foundation via a column base. In the installation structure of the vibration damping device according to claim 1,
The vibration damping device is a rectangular frame-shaped rectangular frame, a pair of support portions provided opposite to the rectangular frame, and disposed between the pair of support portions and supported by the pair of support portions. With a vibration control mechanism,
The vibration damping mechanism is supported by the pair of support portions, and when the pair of support portions is displaced, a pendulum member configured to swing around a substantially central portion between the pair of support portions; An installation structure for a damping device, comprising: a damping member provided between an end of the pendulum member and the rectangular frame. In the installation structure of the vibration damping device according to claim 1 or 2,
The pair of column members have one surface flush with one surface of the upper and lower frame members and both vertical frame members in plan view, and the other surface of the upper and lower frame members and both vertical frame members. In a position slightly protruding from the other surface,
An attachment space for a face material to be attached to the other surface of the upper and lower frame members and both vertical frame members is formed between the protruding portions of the pair of column members. Installation structure. In the installation structure of the vibration damping device according to claim 3,
The face material includes a joining plate material for rigidly joining the rectangular frame to the vertical frame members, and a plurality of covering plate materials for covering portions where these joining plate materials are not provided. The installation structure of the damping device. In the installation structure of the vibration damping device according to any one of claims 1 to 4,
An installation structure of a vibration damping device, wherein upper surfaces of the pair of column members are flush with an upper surface of the upper frame member.

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