JP7338416B2 - How to install the vibration control unit - Google Patents

Description

The present invention relates to a method for installing a vibration damping unit.

Conventionally, as a vibration control unit, for example, it is attached between an upper horizontal member provided on the upper side of a building and a lower horizontal member provided below the upper horizontal member. A vibration damping device that absorbs horizontal force between side horizontal members and attenuates vibrations is known (see, for example, Patent Document 1). The damping device (vibration control unit) comprises a displacement unit, an upper tensioning means arranged between the displacement unit and the upper horizontal member, and a lower tensioning means arranged between the displacement unit and the lower horizontal member. and lateral tensioning means. The upper tensioning means and the lower tensioning means are composed of a pair of braces with turnbuckles, and by adjusting the length of the braces using the turnbuckles, the tension that pulls the displacement unit up and down can be appropriately adjusted. configured to allow In the displacement unit, a support piece connected to the upper side tension applying means and a support piece connected to the lower side tension application means are fixed by viscoelasticity. The viscoelastic body is configured to absorb the vibration energy by shearing deformation.

JP 2011-144556 A

The vibration damping device as described above is initially tensioned when it is installed. At this time, a vibration control device that absorbs vibration energy by deformation of a viscoelastic body like a conventional vibration control device can apply initial tension with a turnbuckle, but a greater vibration control performance is required. In the case of the damping device provided, a larger initial tension is required, and there is a problem that the initial tension cannot be applied with the turnbuckle.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for installing a vibration damping unit that can be installed by easily applying a large initial tension.

In order to achieve such an object, the method for installing the vibration control unit of the present invention includes:
a damping section that generates a damping force by applying a tensile force;
a first pulling part pin-connected to the vibration damping part and pulling the vibration damping part in a first direction;
a second pulling part that is pin-joined to the vibration damping part and pulls the vibration damping part in a second direction opposite to the first direction;
A vibration control unit installation method for installing a vibration control unit having
a first pin joining step of pin joining the first pulling portion and the damping portion;
a tensioning step of tensioning the vibration damping portion in the second direction after the first pin joining step;
a second pin joining step of pin joining the second tensioning portion and the damping portion after the tensioning step;
a tension release step of releasing the tensile tension after the second pin joining step;
A vibration control unit installation method characterized by having

According to this method of installing the vibration damping unit, by tensioning the vibration damping portion pin-joined with the first tensioning portion that pulls the vibration damping portion in the first direction in the second direction, for example, a turnbuckle can be interposed. It is possible to use the PC steel bar as a tensile member and tension it with a larger force than when the tensile force is applied by a turnbuckle. Then, the second tension and the vibration damping part are pin-joined in a state where the vibration damping part is tensioned in the second direction, and then the tension is released, whereby the first tension part and the second tension part are Similarly tensile tension is applied to introduce initial tension. Therefore, it is possible to easily apply a large initial tension and install the vibration control unit.

In addition, a damping section that generates a damping force by acting a tensile force,
a first pulling part pin-connected to the vibration damping part and pulling the vibration damping part in a first direction;
a second pulling part that is pin-joined to the vibration damping part and pulls the vibration damping part in a second direction opposite to the first direction;
A vibration control unit installation method for installing two vibration control units arranged side by side in the first direction, each having
The first tensile portion and the vibration damping portion of one of the vibration damping units of the two vibration damping units are joined together by pins, and the first tensile portion and the vibration damping portion of the other vibration damping unit of the two vibration damping units are joined together. a first pin joining step of pin joining the second tension part and the damping part;
After the first pin joining step, a mutual tension tensioning step of tensioning the vibration damping portion of the one vibration damping unit and the vibration damping portion of the other vibration damping unit in a direction toward each other;
After the mutual tension tensioning step, the second tensile portion and the damping portion of the one damping unit are pinned together, and the first tensile portion and the damping portion of the other damping unit are joined. a second pinning step of pinning the
a mutual tension release step of releasing the tension tension after the second pin joining step;
A vibration control unit installation method characterized by having

According to this method of installing the vibration control units, the vibration control section and the first tension section are connected by pins in one vibration control unit, and the vibration control section and the second tension section are connected by pins in the other vibration control unit. By joining and tensioning the mutual damping parts in the direction of approaching each other, the first tensioning part of one damping unit and the second tensioning part of the other damping unit are interposed, for example, with a turnbuckle. Using a PC steel bar as a tensile member, it is possible to apply tension with a larger force than when applying a tensile force with a turnbuckle. Then, the vibration control section of one vibration control unit and the second tension section are connected in a state in which each vibration control section is pulled toward each other, and the vibration control section of the other vibration control unit is connected to the first tension section. The first tension section and the second tension section of each damping unit are similarly tensioned by pin joining the tension sections and then releasing the tension tension acting on each damping section. An initial tension is introduced. Therefore, it is possible to easily apply a large initial tension to the two vibration damping units at the same time and install the two vibration damping units.

A method for installing such a vibration control unit,
The first structural surface on which one of the vibration control units is provided and the second structural surface on which the other vibration control unit is provided are the positions in the normal direction of the first structural surface and the second structural surface. are different from each other, and the second tensioning portion of the one damping unit and the first tensioning portion of the other damping unit overlap.

According to this method of installing the vibration control units, the first structure plane on which one vibration control unit is installed and the second structure plane on which the other vibration control unit is installed are different in position in the normal direction. Therefore, it is possible to arrange the two vibration control units in a narrower range than when they are arranged side by side in the first direction and the second direction so that the two vibration control units do not overlap in the normal direction. At this time, since the second tensile portion of one damping unit overlaps the first tensile portion of the other damping unit, the damping units are brought closer together without interfering with each other. It is possible to place Moreover, at this time, since the respective vibration damping sections are arranged side by side in the first direction and the second direction, it is possible to easily pull and tension the two vibration damping sections in directions approaching each other. Therefore, it is possible to easily introduce an initial tensile force into a plurality of vibration damping units and install them.

ADVANTAGE OF THE INVENTION According to this invention, it is possible to provide the installation method of the vibration control unit which can apply a big initial tension easily, and can install it.

FIG. 4 is a diagram showing a penetration space in which a plurality of damping units according to the present embodiment are installed in a building; FIG. 2 is a schematic diagram showing a cross section taken along line AA in FIG. 1; It is an enlarged view of the B section in FIG. FIG. 3 is an enlarged view of a portion C in FIG. 2; FIG. 5 is a diagram showing one damping unit in FIG. 4; It is a figure which shows a damping part. FIG. 7 is a cross-sectional view taken along line DD in FIG. 6; FIG. 7 is a cross-sectional view taken along line EE in FIG. 6; FIG. 4 is an exploded perspective view showing the configuration of the damping section of the lower damping unit; FIG. 4 is a side view showing a state in which an initial tensile force is introduced to the upper damping unit and the lower damping unit; FIG. 10 is a diagram showing an installation method in which initial tension is introduced and installed for each two vibration control units. FIG. 4 is a diagram showing an installation method of introducing and installing an initial tension in one vibration control unit; FIG. 13(a) is a diagram showing vibration control units arranged every two floors, FIG. 13(b) is a diagram showing vibration control units arranged every four floors, and FIG. ) is a diagram showing vibration control units arranged every five floors.

An example of the installation method of the vibration control unit according to the present invention will be described below with reference to the drawings.
In this embodiment, a plurality of damping units 2 are incorporated in an elevator pit section S1, for example, as shown in FIGS. The installation method of the seismic control unit will be explained using a seismic structure as an example.

The vibration damping structure of this embodiment is provided with a through space S2 vertically penetrating between two pillars 3 standing apart from each other in an elevator pit section S1 in a building 1. As shown in FIG.

In the following description, the vertical direction is the direction along the erected pillars 3, the horizontal direction is the direction in which the two pillars 3 are spaced apart, and the depth is the direction that intersects (perpendicularly) with the horizontal direction in the horizontal plane. shown as a direction. Even for each part that constitutes the vibration control structure, and for each member that constitutes the vibration control structure, even if it is a single unit, the vertical direction, horizontal direction, and depth when the vibration control structure is incorporated The direction will be specified and explained as the direction.

As shown in FIG. 3, between two pillars 3, a horizontal member 1a connecting between the two pillars 3 is provided for each story with an interval in the depth direction. Each horizontal member 1a is a small beam made of, for example, H-section steel, and only the web is pin-connected to the column 3 side by bolts and nuts, and the flange portion is not connected. The width of each horizontal member 1a in the depth direction is sufficiently narrower than the width W1 of the pillar 3 in the depth direction. The horizontal member 1a is stretched over the vicinity of each floor so as to connect two pillars 3 at both ends of the pillar 3 in the depth direction.

Between two horizontal members 1a spaced apart in the depth direction, there is provided a through space S2 that vertically penetrates across a plurality of floors. A plurality of damping units 2 for damping external forces are provided. That is, the width W1 in the depth direction of the two pillars 3 is wider than the width W2 in the depth direction of the through space S2. No structural members are provided. Note that the horizontal member 1a and the like may not necessarily be provided between the two pillars 3. In this case, the entire space between the two pillars 3 corresponds to a through space vertically penetrating across multiple floors.

As shown in FIGS. 2 and 4, the vibration control unit 2 of the present embodiment is arranged in each of the continuous spaces S3, which are vertically connected spaces extending over three layers, of the through spaces S2 extending over a plurality of layers. ing. The arrangement of the plurality of damping units 2 in the penetration space S2 will be detailed later. In the following description of the vibration damping unit 2, as shown in FIG. 5, the spaces of the three floors connected above and below the continuous space S3 are described as an upper space S3a, a middle space S3b, and a lower space S3c. For convenience of explanation, FIG. 5 shows only one damping unit 2 and omits other damping units 2 .

As shown in FIG. 5, each vibration damping unit 2 is pinned by bolts and nuts via a gusset plate 4 to the surfaces 3a facing each other of two pillars 3 in the upper side of the upper space S3a and the lower side of the lower space S3c. It has four tension parts 51 and 52 that are joined and arranged on a diagonal line of the continuous space S3, and a damping part 6 that is supported by the four tension parts 51 and 52 and arranged in the center of the hollow space S3b. are doing. That is, the vibration damping unit 2 forms an X-shaped brace extending over the three-level spaces S3a, S3b, and S3c of the continuous space S3 with the four tension portions 51 and 52 and the vibration damping portion 6. As shown in FIG.

The four tension members 51 and 52 are, on the upper side of the vibration damping portion 6, an upper brace member 5a that pulls the vibration damping portion 6 upward as the first direction, and an upper brace member 5a that is pin-joined to the vibration damping portion 6. and the upper connecting member 18 connected to the two first tensioning parts 51 connected to the lower brace that pulls the vibration damping part 6 downward as the second direction on the lower side of the vibration damping part 6. The lower connecting member 16 pin-connected to the vibration damping portion 6 and connected to the lower brace member 5b are two second tension portions 52 connected to each other. The upper brace member 5a, the upper connection member 18, the lower brace member 5b, and the lower connection member 16 are all formed of plate-like members, and the upper brace member 5a, the upper connection member 18, and the lower brace member 5b The lower connecting members 16 are pin-joined by bolts and nuts.

As shown in FIGS. 6 to 9, the damping section 6 includes two first tension sections 51 respectively joined to the left and right pillars 3 and three upper damping sections rotatably connected in the in-plane direction. It has a vibration plate member 7, two second tension portions 52 respectively joined to the left and right pillars 3, and two lower vibration damping plate members 8 connected to each other so as to be rotatable in the in-plane direction. Each of the three upper damping plate members 7 and the two lower damping plate members 8 is a flat member.

The three upper damping plate members 7 are arranged to face each other with a gap in the depth direction, and the two lower damping plate members 8 are arranged to face each other with a gap in the depth direction. The upper parts of the two lower vibration damping plate members 8 are inserted one by one between the lower parts of the three upper vibration damping plate members 7 facing each other. That is, the three upper damping plate members 7 and the two lower damping plate members 8 have overlapping portions 7a and 8a on the lower side and the upper side, respectively, overlapping in the depth direction.

Friction plates 9 are fixed to the surfaces of the overlapping portions 7a of the three upper vibration damping plates 7 on the side of the lower vibration damping plates 8, respectively. , the slide plate 10 is fixed. Here, the friction plate 9 is made of, for example, an organic friction material or an inorganic friction material, and the slide plate 10 is made of a corrosion-resistant material such as stainless steel or titanium.

Circular bolt insertion holes 7b and 9a through which the bolts 11 are inserted are formed in the overlapping portion 7a of the three upper damping plates 7 and the friction plate 9 at appropriate intervals in the vertical direction. The two lower vibration damping plates 8 and the slide plate 10 are provided with long holes 8b and 10a elongated in the left-right direction at the same interval as the bolt insertion holes 7b and 9a.

The three upper damping plate members 7 to which the friction plates 9 are fixed and the two lower damping plate members 8 to which the slide plates 10 are fixed are superimposed so as to form bolt insertion holes 7b and 9a and a long hole 8b. , 10a. A plurality of disc springs 12 are inserted through the inserted bolt 11 on the tip side of the bolt 11, and a nut 13 is tightened to form the vibration damping section 6. - 特許庁

Connecting bolts 14 are inserted through the left and right corners of the upper ends of the three upper vibration damping plates 7 of the vibration damping section 6 and the left and right corners of the lower ends of the two lower vibration damping plates 8. Holes 7c and 8c are provided.
Vertical plate members 15 extending from the upper vibration damping plate member 7 to the lower vibration damping plate member 8 are stacked along the left and right ends on both sides of the vibration damping portion 6 in the depth direction.

As shown in FIG. 8, the three lower connecting members 16 of the second tensile portion 52 are interposed between the opposing lower damping plate members 8 and between the lower damping plate member 8 and the vertical plate member 15. protruded downwards. The two vertical plates 15 and the three lower connecting members 16 are provided with connecting bolt insertion holes 15a, 16a in the same manner as the two lower damping plate members 8. A connecting bolt 14 is inserted through 16a. The connecting bolt 14 is a bolt having a threaded portion at its tip. A washer is interposed between the head of the connecting bolt 14 and the upper damping plate member 7 and the lower damping plate member 8, and a nut 14a is fastened to the threaded portion.

Splice plates 17 are interposed between the opposing lower connecting members 16 on the lower end side of the three lower connecting members 16 protruding downward from the lower damping plate member 8 . Between the two splice plates 17, the end surfaces of the middle lower connecting member 16 and the lower brace member 5b are arranged so as to face each other. The lower connecting member 16 and the lower brace member 5b are connected by pin joining. Spacers are appropriately interposed so that the lower damping plate member 8, the vertical plate member 15, the lower connecting member 16, the splice plate 17, and the lower brace member 5b are overlapped substantially in parallel.

Between the three upper damping plate members 7, two upper connecting members 18 that connect the upper brace member 5a and the damping portion 6 are interposed and protrude upward. The two vertical plates 15 and the two upper connecting members 18 superimposed on the three upper vibration damping plates 7 are provided with connecting bolt insertion holes 18a like the three upper vibration damping plates 7. , the connecting bolts 14 are inserted through the connecting bolt insertion holes 7c and 18a.

An upper brace member 5a is interposed on the upper end side of the two upper connecting members 18 that protrude upward from the upper damping plate member 7, and the upper brace member 5a is interposed between the two opposing upper connecting members 18. The vibration damping plate member 7 and the upper brace member 5a are arranged so that their end surfaces face each other, and the upper connecting member 18 and the upper brace member 5a are pin-joined by bolts and nuts to form the upper vibration damping plate member 7 and the upper brace member 5a. and are connected. Spacers are appropriately interposed so that the upper damping plate member 7, the vertical plate member 15, the upper connecting member 18, and the upper brace member 5a are overlapped substantially in parallel.

As shown in FIG. 6, each vibration control section 6 of a plurality of vibration control units 2 provided in this vibration control structure has an upper tensile force introduction in order to introduce an initial tensile force when installing the vibration control unit 2. Either a portion 70 or a lower pull force introducing portion 80 is provided. The configuration of the upper tensile force introduction portion 70 and the lower tensile force introduction portion 80 and the position where the upper tensile force introduction portion 70 or the lower tensile force introduction portion 80 is provided will be described later.

With the above configuration, the damping section 6, which is installed in the continuous space S3 over three stories and forms an X-shaped brace together with the first tensioning section 51 and the second tensioning section 52, is composed of the upper damping plate 7, the lower damping The diaphragm member 8 and the vertical plate member 15 are rotatably connected to each other, and mechanically function as a rectangular parallel link. That is, the left and right vertical plates 15 rotate with respect to the upper vibration damping plate member 7 and the lower vibration damping plate member 8 using the four connecting bolts 14 as joint axes, whereby the upper vibration damping plate member 7 and the lower vibration damping plate member 8 are rotated. They are configured to move relative to each other while maintaining their parallel postures.

In a state where no seismic motion or the like is input to the column 3, the four connecting bolts 14 forming the joint axes of the vibration control section 6 forming parallel links are connected via the first tensioning section 51 and the second tensioning section 52. Tensile force acts evenly in the diagonal direction of the continuous space S3 over three floors, and the vibration damping section 6 forming a parallel link has a rectangular shape.

Then, when seismic motion or the like is input to the column 3 and the column 3 is deformed by a horizontal load, the first tension portion 51 and the second tension portion stretched on one of the two diagonal lines of the X-shaped brace are stretched. 52 becomes larger than the tension of the first tension part 51 and the second tension part 52 stretched on the other diagonal line, the vibration damping part 6 forming a parallel link also follows the column 3 and the parallel quadrilateral Deform to form. At this time, due to the deformation of the vibration damping portion 6, the upper vibration damping plate member 7 and the lower vibration damping plate member 8 move relative to each other while maintaining their parallel postures. and the sliding plate 10 fixed to the lower vibration damping plate member 8 slide while being compressed by the disc spring 12 to function as a tension damper for damping vibration.

A plurality of vibration control units 2 of the present embodiment are provided in the through space S2 between the two pillars 3, and are arranged in different continuous spaces S3. More specifically, for example, a continuous space S3 spanning three layers from the lowest layer to the layer two levels above, and a layer one level above the lowest layer (hereinafter referred to as the second floor) A continuous space S3 covering three floors up to the fourth floor (hereinafter referred to as the fourth floor), three floors from the third floor (hereinafter referred to as the third floor) to the fifth floor (hereinafter referred to as the fifth floor) The seismic control units 2 are arranged in the continuous spaces S3 over the three floors shifted upward by one floor, such as the continuous space S3 over the floors.

Since each continuous space S3 extends over three layers and is shifted one layer at a time, the lower space S3c of the continuous space S3 located at the bottom of the continuous space S3 of the through space S2 and the continuous space S3 located at the top. The space other than the upper space S3a is shared by a plurality of continuous spaces S3, and in the shared space, part of the vibration control unit 2 overlaps in the depth direction. For example, the continuous space S3 including the lowest floor has a space shared by the continuous space S3 whose lowest floor is the second floor and the continuous space S3 whose lowest floor is the third floor, and includes the lowest floor. A part of the vibration control unit 2 arranged in the continuous space S3 and arranged to reach the third floor is divided into the continuous space S3 where the second floor is the lowest and the continuous space S3 where the third floor is the lowest. It is arranged at a different position in the depth direction from part of the seismic unit 2 .

In addition, the vibration control unit 2 arranged in the continuous space S3 over the three floors from the 4th floor to the 6th floor is arranged directly above the vibration control unit 2 arranged in the continuous space S3 including the lowest floor. The vibration control unit 2 arranged in the continuous space S3 over the three floors from the 2nd to the 7th floor is arranged directly above the vibration control unit 2 arranged in the continuous space S3 over the 3rd floor from the 2nd to the 4th floor. , the vibration control unit 2 arranged in the continuous space S3 over the three stories from the 6th to the 8th floor is directly above the vibration control unit 2 arranged in the continuous space S3 over the three stories from the 3rd to the 5th floor. are placed.

In other words, the plurality of vibration control units 2 are arranged in a row in the vertical direction. The vibration damping units 2 in the matching row are shifted from each other by one layer in the vertical direction.

For this reason, the vibration control units 2 arranged one by one in each continuous space S3 are partly divided into the vibration control units 2 provided in the continuous space S3 with the lower space S3c being one floor above, and It is arranged so as to overlap in the depth direction with the vibration control unit 2 provided in the continuous space S3 with the lower space S3c being two floors higher. That is, the damping units 2 arranged in the continuous space S3 sharing the space partially overlap each other in the depth direction.

At this time, since the vibration control unit 2 arranged in each continuous space S3 has the vibration control section 6 arranged in the center of the middle space S3b of each continuous space S3, the vibration control unit 2 that is vertically adjacent to the vibration control unit 2 has the vibration control unit 6 arranged in the center of the middle space S3b of each continuous space S3. The vibration parts 6 do not overlap each other in the depth direction, and are arranged so that a part of the first pulling part 51 or the second pulling part 52 overlaps.

Therefore, as in the vibration control structure of this embodiment, when the vibration control unit 2 is installed in the continuous space S3 over three stories, the two vibration control units 2 are arranged in the depth direction by shifting one story up and down. In order to arrange the three vibration control units 2 so that they partially overlap each other, a penetration space S2 over four stories is required. through space S2 is required. That is, when the vibration control unit 2 is installed in the continuous space S3 over multiple floors, the number of layers of the continuous space S3 in which one vibration control unit 2 is arranged is greater than the number of layers in the continuous space S3. Penetration spaces S2 corresponding to the number of seismic units 2 are required.

Next, a method for installing the vibration control unit 2 in the vibration control structure of this embodiment will be described.
As shown in FIG. 11, first, each of the plurality of vibration damping units 2 installed in the penetration space S2 is temporarily fixed to the pillar 3 via the gusset plate 4 (STEP 1: temporary fixing step). Temporary fixation here means bolts that join the gusset plate 4 and the upper brace member 5a and the lower brace member 5b of each vibration damping unit 2, and joins the upper brace member 5a and the upper connecting member 18 of each vibration damping unit 2. It shows a state in which the bolts that connect the lower brace members 5b and the bolts that join the lower connecting members 16 to each other are both loosened.

Next, an initial tensile force is introduced into each damping unit 2 . The introduction of the initial tensile force is performed for each group by grouping the plurality of vibration control units 2 temporarily fixed in the through space S2, starting with the vibration control unit 2 placed at the top. When the number of damping units 2 temporarily fixed in the penetration space S2 is odd, for example, the initial tensile force is introduced independently to the damping unit 2 placed at the bottom.

First, a method of introducing an initial tensile force to the pair of two vibration damping units 20 and 21 will be described. In the following description, of the two vibration damping units 20 and 21 in each set, the upper one will be referred to as the upper damping unit 20 and the lower one will be referred to as the lower damping unit 21 . Further, as shown in FIG. 10, in the temporarily fixed state, the second structural plane P2 on which the lower vibration control unit 21 is provided is deeper in the depth direction than the first structural plane P1 on which the upper vibration control unit 20 is provided. 6, the second tensioning portion 52 of the upper damping unit 20 and the first tensioning portion 51 of the lower damping unit 21 overlap in the depth direction. Here, the depth direction corresponds to the normal direction of the first structural surface P1 and the second structural surface P2.

As shown in FIG. 10, each of the paired two vibration damping units 20 and 21 is positioned on the front side of the two lower vibration damping plates 8 of the vibration damping portion 6 of the upper vibration damping unit 20. The lower damping plate member 8 is provided with a lower tensile force introducing portion 80 that protrudes downward, and is positioned in the middle of the three upper damping plate members 7 of the damping portion 6 of the lower damping unit 21. An upper tensile force introducing portion 70 is provided on the upper damping plate member 7 so as to protrude upward.

The lower tensile force introduction part 80 is provided at the center in the left-right direction of the lower damping plate member 8 on the front side, and is welded so that the lower damping plate member 8 extends downward. It has a lower lead-in plate portion 80b welded to the lower end of the portion 80a. The lower introduction plate portion 80b forms a substantially horizontal surface with the upper damping unit 20 temporarily fixed, and extends to the front side and the rear side of the welded lower extension portion 80a. The lower introduction plate portion 80b is provided with through holes 80c penetrating in the vertical direction on the front side and the back side of the lower extension portion 80a.

The upper tensile force introduction part 70 is provided in the center in the left-right direction of the middle damping plate member 7, and is welded so that the upper damping plate member 7 extends upward. and an upper lead-in plate portion 70b welded to the upper end of the . With the lower damping unit 21 temporarily fixed, the upper introduction plate portion 70b forms a substantially horizontal plane and extends to the front side and the rear side of the welded upper extension portion 70a. The upper introduction plate portion 70b is provided with through holes 70c penetrating in the vertical direction on the front side and the back side of the upper extension portion 70a. When the upper damping unit 20 and the lower damping unit 21 are temporarily fixed, the upper introduction plate portion 70b and the lower introduction plate portion 80b face each other with a space therebetween in the vertical direction.

When an initial tensile force is introduced into the two vibration damping units 20 and 21, first, the first tensile portion 51 of the upper vibration damping unit 20, the vibration damping portion 6, and the gusset plate 4 are pin-connected, and the lower vibration damping is performed. The second tensioning portion 52 of the unit 21, the damping portion 6, and the gusset plate 4 are pin-joined (STEP 2: first pin-joining step). Specifically, the upper brace member 5a of the upper vibration damping unit 20, the gusset plate 4, and the upper connecting member 18 are connected by tightening the bolts to connect them with pins, and the lower brace member 5b of the lower vibration damping unit 21 and the gusset plate are connected. 4 and the lower connecting member 16 are tightened and pin-connected. The vibration damping portion 6 of the upper vibration damping unit 20 and the upper connecting member 18 pin-joined by the connecting bolt 14 are connected to the upper brace member 5a, thereby connecting the first tension portion 51 of the upper vibration damping unit 20 and the vibration damping. The lower brace member 5b is connected to the lower brace member 5b by connecting the lower brace member 5b to the vibration damping portion 6 of the lower vibration damping unit 21 and the connection bolt 14. The second pulling portion 52 and the damping portion 6 are pin-joined. At this time, the bolts connecting the lower brace member 5b of the upper vibration damping unit 20 to the gusset plate 4 and the lower connecting member 16 are still loosened, and the upper brace member 5a of the lower vibration damping unit 21, the gusset plate 4 and the upper connecting member 16 are still loosened. The bolts joining the material 18 remain loose.

Next, in the two through holes 80c of the lower introduction plate portion 80b provided in the upper vibration damping unit 20 and the two through holes 70c of the upper introduction plate portion 70b provided in the lower vibration damping unit 21, A PC steel bar 19 having thread grooves formed at both ends thereof is inserted, and a nut 19a is screwed onto both ends of the PC steel bar 19 . The PC steel rod 19 is pulled by a tensioning device such as a center hole jack and tightened with a screwed nut 19a, so that the vibration damping portion 6 of the upper vibration damping unit 20 and the vibration damping portion 6 of the lower vibration damping unit 21 are tightened. and pull toward each other to apply a desired tensile force (STEP 3: Mutual tensile tension step).

Next, the second tensioning portion 52 of the upper vibration damping unit 20, the vibration damping portion 6 and the gusset plate 4 are pin-connected, and the first tension portion 51 of the lower vibration damping unit 21, the vibration damping portion 6 and the gusset plate 4 are joined together. are pin-joined (STEP 4: second pin-joining step). Specifically, the bolts connecting the lower brace member 5b of the upper vibration damping unit 20, the gusset plate 4 and the lower connecting member 16 are tightened and pinned, and the upper brace member 5a and the gusset plate of the lower vibration damping unit 21 are connected. 4 and the upper connecting member 18 are tightened and pin-connected. The vibration damping portion 6 of the upper vibration damping unit 20 and the lower connecting member 16 pin-joined by the connecting bolt 14 are connected to the lower brace member 5b, whereby the second tension portion 52 of the upper vibration damping unit 20 and the vibration damping portion 5b are connected. The lower vibration damping unit 21 is connected to the upper brace member 5a by connecting the vibration damping portion 6 of the lower vibration damping unit 21 and the upper brace member 5a. The first pulling portion 51 and the damping portion 6 are pin-joined.

Next, the nuts 19a screwed to both ends of the PC steel rod 19 are removed, the PC steel rod 19 is removed, the tensile tension is released, and the initial tensile force is applied to the upper vibration damping unit 20 and the lower vibration damping unit 21. is introduced to complete the installation of the two damping units 2 (STEP 5: Mutual tension releasing step).

In this way, the initial tensile force is introduced and installed for every two vibration damping units 2 in order from, for example, the upper side of the penetration space S2. If the number of damping units 2 to be installed in the penetration space S2 is even, the installation is completed by introducing the initial tensile force to all the damping units 2 arranged in the penetration space S2 by this installation method.

According to the installation method of the two vibration damping units 20 and 21 of the present embodiment, the first tensile portion 51 and the vibration damping portion 6 and the gusset plate 4 are connected by pins in the upper vibration damping unit 20, and in the lower vibration damping unit The second tensile portion 52, the vibration damping portion 6, and the gusset plate 4 are pin-connected, and the vibration damping portions 6 are tensioned in a direction toward each other, whereby the first tension portion 51 of the upper vibration damping unit 20 and the lower The second tensile portion 52 of the vibration damping unit 21 can be tensioned with a larger force than when a turnbuckle is used as a tensile member, for example, a PC steel bar interposed with a turnbuckle. be.

Then, the second tensile portion 52 of the upper vibration damping unit 20, the vibration damping portion 6 and the gusset plate 4 are pulled together in a state in which the respective damping portions 6 are pulled toward each other, and the lower damping unit 21 The first tensile portion 51 and the vibration damping portion 6 and the gusset plate 4 are pin-joined, and then the tensile tension acting on each vibration damping portion 6 is released, so that each vibration damping unit 20, 21 The first tensioning portion 51 and the second tensioning portion 52 of are similarly tensioned to introduce initial tension. Therefore, it is possible to install the two vibration control units 20 and 21 by easily applying a large initial tension to the two vibration control units 20 and 21 at the same time.

In addition, since the first structure plane P1 on which the upper vibration control unit 20 is provided and the second structure plane P2 on which the lower vibration control unit 21 is provided are different from each other in the normal direction, the two vibration control units It is possible to arrange the two vibration damping units 20 and 21 in a narrower space than when they are arranged side by side in the vertical direction so that they do not overlap in the normal direction. At this time, since the second tensioning portion 52 of the upper damping unit 20 and the first tensioning portion 51 of the lower damping unit 21 overlap each other, the damping units 20 and 21 do not interfere with each other. It is possible to place the seismic part 6 closer together. At this time, since the vibration damping portions 6 are arranged side by side in the vertical direction, the two vibration damping portions 6 can be easily tensioned in a direction toward each other. Therefore, it is possible to install a plurality of vibration control units 2 by easily introducing an initial tensile force to the multiple vibration control units 2 .

In the above-described embodiment, an example was described in which the initial tensile force is sequentially introduced to the two vertically aligned damping units after temporarily fixing all of the plurality of damping units 2 provided in the through space S2 in advance. Alternatively, for example, the step of introducing an initial tensile force after temporary fixing may be sequentially repeated for every two vertically adjacent vibration damping units.

If the number of damping units 2 temporarily fixed in the penetration space S2 is an odd number, for example, the vibration damping unit 2 temporarily fixed at the bottom of the penetration space S2 may A lower tensile force introducing portion 80 of the vibration damping portion 6 of the upper vibration damping unit 20 is provided. In addition, a member similar to the upper tensile force introducing portion 70 provided in the lower vibration damping unit 21 is attached to the structure located below the vibration damping unit 2 so that the upper introduction plate portion 70b and the lower introduction plate portion 80b are connected. They are arranged so as to face each other with an interval in the vertical direction.

When installing the seismic control unit 2 by introducing an initial tensile force independently, first, the bolts connecting the upper brace member 5a of the seismic control unit 2, the gusset plate 4 and the upper connecting member 18 are tightened to tighten the pin. Bond (STEP 6: first pin bonding step). The first tensioning portion 51 and the vibration damping portion 6 are pin-joined by connecting the vibration damping portion 6 and the upper connecting member 18 pin-joined by the connecting bolt 14 to the upper brace member 5a. At this time, the bolts connecting the lower brace member 5b, the gusset plate 4 and the lower connecting member 16 are still loosened.

Next, the two through-holes 80c of the lower introduction plate portion 80b provided in the vibration damping unit 2 and the two through-holes 70c of the upper introduction plate portion 70b provided in the structure are screwed at both ends. The PC steel rods 19 formed with grooves are respectively inserted, and nuts 19a are screwed to both ends of the PC steel rods 19. As shown in FIG. The PC steel rod 19 is pulled by the tension tension device and the nut 19a screwed thereto is tightened, and the vibration damping section 6 of the vibration damping unit 2 is tensioned downward toward the structure to apply a desired tensile force. (STEP7: Tensile tension step).

Next, the bolts joining the lower brace member 5b, the gusset plate 4 and the lower connecting member 16 are tightened and pin joined (STEP 8: second pin joining step). The second tensioning portion 52 and the vibration damping portion 6 are pin-joined by connecting the lower connecting member 16 and the lower brace member 5b which are pin-joined to the vibration damping portion 6 by the connecting bolts 14 .

Next, the nuts 19a screwed to both ends of the PC steel rod 19 are removed, the PC steel rod 19 is removed, the tensile tension is released, an initial tensile force is introduced into the vibration damping unit 2, and the vibration damping unit Installation of 2 is completed (STEP 9: tension releasing step).

According to the installation method of the vibration damping unit 2 of the present embodiment, the vibration damping portion 6 pin-joined to the first tensioning portion 51 that pulls the vibration damping portion 6 upward is tensioned downward, thereby for example turning. By using a PC steel bar interposed with a buckle as a tensile member, it is possible to apply tension with a greater force than in the case where a tensile force is applied by a turnbuckle. Then, the second tension portion 52 and the vibration damping portion 6 are pin-joined in a state where the vibration damping portion 6 is tensioned downward. The second pull section 52 is similarly tensioned to introduce initial tension. Therefore, even if the vibration control unit 2 is a single unit, it is possible to install the vibration control unit 2 by easily imparting a large initial tension.

In the present embodiment, the installation method of introducing an initial tensile force to the damping unit 2 that is temporarily fixed at the bottom of the penetration space S2 and installing it has been described. The same is true when installing the seismic control unit with an initial tensile force. At this time, the portion where the lower introduction plate portion 80b provided in the vibration damping unit 2 and the PC steel rod 19 are connected is not limited to the structure, and has rigidity and strength capable of introducing a desired initial tensile force. Anchor bolts or hooks on which wires or the like can be hooked may also be used.

In the above embodiment, an example in which the first tensioning portion 51 is composed of the upper brace member 5a and the upper connecting member 18, and the second tensioning portion 52 is composed of the lower brace member 5b and the lower connecting member 16 will be described. However, the first pulling portion 51 and the second pulling portion 52 may be a single member. In this case, for example, in the first pin joining step, one of the first tensioning portion and the second tensioning portion and the vibration damping portion are pin-joined with a connecting bolt, and in the tension tension step, the vibration damping portion and the pin The damping section is pulled in the direction opposite to the joined first tension section or the second tension section, and in the second pin joining step, the other of the first tension section and the second tension section and the damping section are connected. Pin joint with connecting bolts.

Further, when a tensile force is introduced into each vibration damping unit 2, it is not necessary to preliminarily fix the first tensioning portion 51, the second tensioning portion 52, and the damping portion 6. A first tension part or a second tension part in which only one of the tension part and the second tension part is pin-connected to the vibration damping part and the other is not arranged, and the vibration damping part is pin-joined It may be pulled in the opposite direction and then the other of the first and second pull sections may be placed and pinned to the damping section.

In the above-described embodiment, the PC steel rod 19 is inserted into the through hole 70c of the upper tensile force introducing portion 70 and the through hole 80c of the lower tensile force introducing portion 80 located above and below, and the nut 19a is screwed to obtain the initial tensile force. Although the method of introducing is described as an example, it is not limited to this. For example, a wire stretched between the through hole 70c of the upper tensile force introduction portion 70 and the through hole 80c of the lower tensile force introduction portion 80 is connected to the upper tensile force introduction portion 70 by a tensioning device such as a lever block (registered trademark). The initial tensile force may be introduced by attracting the lower tensile force introducing portion 80 in the direction of approaching each other.

In the above embodiment, the damping units 2, 20, and 21 made up of X-shaped braces in which the damping portion 6 is supported by four tension portions 51 and 52 arranged on two diagonal lines are taken as examples. Although they have been mentioned and explained, they are not limited to these. For example, even if a vibration control unit consists of a brace that is strung diagonally with a vibration control part interposed between two tension parts arranged on a diagonal line, one tension part and the vibration control part are pin-joined to each other, and after tensioning the vibration-damping part to the other tension part, the other tension part and the vibration-damping part can be installed by pin-joining.

Further, in the above-described embodiment, an example in which a plurality of vibration control units 2 are provided in a space penetrating in the vertical direction has been described, but the present invention is not limited to this. It may be provided in a space penetrating in the lateral direction, such as between the slabs.

In the above-described embodiment, an example has been described in which the tensile portions of vertically adjacent damping units among the plurality of damping units 2 provided in the through space S2 are arranged so as to overlap in the depth direction. For example, vibration damping units adjacent in the vertical direction may be provided within the same structural plane without overlapping in the depth direction.

In the above embodiment, the continuous space has been described as a three-layered space that is vertically connected. It is not limited to this. For example, as shown in FIG. 13(a), the continuous space S3 may be formed as a space of two layers connected vertically, or as a space of four layers connected vertically as shown in FIG. 13(b). Also, as shown in FIG. 13(c), the continuous space S3 may be a space of five layers connected in the vertical direction, or may be a space of more layers.

The above-described embodiments are intended to facilitate understanding of the present invention, and are not intended to limit and interpret the present invention. The present invention can be modified and improved without departing from its spirit, and it goes without saying that the present invention includes equivalents thereof.

2 Vibration control unit 6 Vibration control part 51 First tension part 52 Second tension part P1 First structural surface P2 Second structural surface

Claims (3)

a damping section that generates a damping force by applying a tensile force;
a first pulling part pin-connected to the vibration damping part and pulling the vibration damping part in a first direction;
a second pulling part that is pin-joined to the vibration damping part and pulls the vibration damping part in a second direction opposite to the first direction;
A vibration control unit installation method for installing a vibration control unit having
a first pin joining step of pin joining the first pulling portion and the damping portion;
a tensioning step of tensioning the vibration damping portion in the second direction after the first pin joining step;
a second pin joining step of pin joining the second tensioning portion and the damping portion after the tensioning step;
a tension release step of releasing the tensile tension after the second pin joining step;
A method for installing a vibration control unit, comprising: a damping section that generates a damping force by applying a tensile force;
a first pulling part pin-connected to the vibration damping part and pulling the vibration damping part in a first direction;
a second pulling part that is pin-joined to the vibration damping part and pulls the vibration damping part in a second direction opposite to the first direction;
A vibration control unit installation method for installing two vibration control units arranged side by side in the first direction, each having
The first tensile portion and the vibration damping portion of one of the vibration damping units of the two vibration damping units are joined together by pins, and the first tensile portion and the vibration damping portion of the other vibration damping unit of the two vibration damping units are joined together. a first pin joining step of pin joining the second tension part and the damping part;
After the first pin joining step, a mutual tension tensioning step of tensioning the vibration damping portion of the one vibration damping unit and the vibration damping portion of the other vibration damping unit in a direction toward each other;
After the mutual tension tensioning step, the second tensile portion and the damping portion of the one damping unit are pinned together, and the first tensile portion and the damping portion of the other damping unit are joined. a second pinning step of pinning the
a mutual tension release step of releasing the tension tension after the second pin joining step;
A method for installing a vibration control unit, comprising: A method for installing a vibration control unit according to claim 2,
The first structural surface on which one of the vibration control units is provided and the second structural surface on which the other vibration control unit is provided are the positions in the normal direction of the first structural surface and the second structural surface. are different from each other, and the second tensioning portion of the one of the vibration control units and the first tensioning portion of the other vibration control unit overlap each other. .

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