JP7020045B2 - Damping structure - Google Patents

Description

The present invention relates to a vibration damping structure.

A vibration damping device provided in the structure surface of a frame and connected to an upper end portion of a frame provided on a lower beam and an upper beam is known (see, for example, Patent Document 1).

Further, there is known a vibration damping device provided in the structure surface of a frame and provided with a viscoelastic damper and a steel seismic wall connected in series (see, for example, Patent Document 2).

Japanese Unexamined Patent Publication No. 2001-090381 Japanese Unexamined Patent Publication No. 2011-117145

In the technique disclosed in Patent Document 1, when a relative displacement occurs between the upper end portion of the frame and the upper beam during an earthquake, the vibration damping device operates to generate a damping force. This reduces the vibration of the frame.

However, if the relative displacement between the upper end portion of the frame and the upper beam becomes excessive, the support member such as the frame that supports the vibration damping device may be damaged.

In consideration of the above facts, an object of the present invention is to suppress damage to the support member that supports the vibration damping device.

The vibration damping structure according to the first aspect is connected to a frame, a support member provided in the structure surface of the frame, the frame and the support member, and is accompanied by a relative displacement between the frame and the support member. When the vibration damping device that generates the damping force and the vibration damping device provided in the vibration damping device and the relative displacement between the frame and the support member becomes a predetermined value or more, the damping force generated by the vibration damping device is reduced. It is equipped with a relief mechanism.

According to the vibration damping structure according to the first aspect , a support member is provided in the frame surface of the frame. A vibration damping device is connected to the frame and the support member. The vibration damping device generates a damping force with the relative displacement between the frame and the support member during an earthquake. This reduces the vibration of the frame during an earthquake.

Further, the vibration damping device is provided with a relief mechanism. The relief mechanism reduces the damping force generated by the vibration damping device when the relative displacement between the frame and the support member becomes a predetermined value or more. As a result, the seismic force input from the frame to the support member via the vibration damping device is reduced. Therefore, damage to the support member is suppressed.

The vibration damping structure according to the second aspect is the vibration damping structure according to the first aspect, and the support member has a grid-like wall and a plate-like member provided at an opening of the grid-like wall.

According to the vibration damping structure according to the second aspect , the support member has a grid-like wall and a plate-like member. The grid wall has a plurality of openings. A plate-shaped member is provided in the plurality of openings.

Therefore, the design of the support member can be enhanced by appropriately changing the arrangement of the plate-shaped members with respect to the lattice-shaped wall and, for example, arranging a plurality of plate-shaped members in a checkered shape (staggered shape).

The vibration damping structure according to the third aspect is the vibration damping structure according to the second aspect, in which the plate-shaped member has glass.

According to the vibration damping structure according to the third aspect , the plate-shaped member has glass. This makes it possible to further enhance the design of the support member. In addition, the daylighting property of the support member can be improved.

As described above, according to the vibration damping structure according to the present invention, it is possible to suppress damage to the support member that supports the vibration damping device.

FIG. 1 is an elevational view showing a frame to which the vibration damping structure according to the embodiment is applied. FIG. 2 is a sectional view taken along line 2-2 of FIG.

Hereinafter, the vibration damping structure according to the embodiment will be described with reference to the drawings.

(Damping structure)
As shown in FIG. 1, the vibration damping structure 10 according to the present embodiment includes a frame 12, a steel wall 30 as a support member, and a pair of vibration damping devices 50.

(Frame)
The frame 12 is a rigid frame frame having a pair of columns 14 and an upper beam 16 and a lower beam 18 erected on the pair of columns 14. The pair of columns 14 are, for example, steel columns formed by a square steel pipe or the like. Further, the upper beam 16 and the lower beam 18 are, for example, steel beams formed of H-shaped steel. A slab 20 is provided on each of the upper beam 16 and the lower beam 18.

A pair of frame-side connecting portions 22 to which the vibration damping device 50 is connected are provided at the corners (corners) on both sides of the frame 12. Each frame-side connecting portion 22 has a gusset plate 22A and a plurality of reinforcing ribs 22B. The gusset plate 22A is provided over the stigma of the column 14 and the end of the upper beam 16. The gusset plate 22A is reinforced by a plurality of reinforcing ribs 22B.

(Steel wall)
A steel wall 30 is provided in the frame surface (inside the opening) of the frame 12. The steel wall 30 functions as a support member for supporting the pair of vibration damping devices 50. The steel wall 30 is arranged with the wall thickness direction as the out-of-plane direction of the frame 12.

The steel wall 30 is joined to the lower beam 18 via the slab 20. The steel wall 30 and the slab 20 are joined so that a shear force can be transmitted via a stud or the like (not shown). Further, openings 24 are formed between the ends 30S on both sides of the steel wall 30 in the lateral width direction and the pair of columns 14. Further, the lower end side of the end portion 30S of the steel wall 30 and the column base side of the pair of columns 14 are joined via a gusset plate 26 or the like.

The steel wall 30 and the pair of columns 14 do not have to be joined.

The steel wall 30 has a grid-like wall 32 and a plurality of plate-like members 36. The grid-like wall 32 has a plurality of vertical members 32A and horizontal members 32B. The plurality of vertical members 32A and horizontal members 32B are formed of steel plates or the like. These vertical members 32A and horizontal members 32B are joined in a grid pattern by welding or the like.

Further, the grid-like wall 32 has a plurality of openings 34 surrounded by the vertical member 32A and the horizontal member 32B. Each opening 34 is formed in a rectangular shape. Further, each opening 34 penetrates the grid-like wall 32 in the wall thickness direction. A plate-shaped member 36 is provided in a part of these openings 34.

Each plate-shaped member 36 is formed in a rectangular plate shape by a glass block or the like. Further, each plate-shaped member 36 is arranged in the opening 34, and the outer peripheral portion thereof is appropriately joined to the lattice-shaped wall 32. The opening 34 is closed by the plate-shaped member 36.

It is also possible to form a part of the plate-shaped member 36 with glass and the other part with a steel plate or the like. That is, the plate-shaped member 36 can be formed of a member having glass at least in part.

The plurality of plate-shaped members 36 are arranged in a checkered shape (staggered shape). That is, in the lattice-shaped wall 32, the opening 34 in which the plate-shaped member 36 is provided and the opening 34 in which the plate-shaped member 36 is not provided are formed in the lateral width direction (arrow W direction) of the lattice-shaped wall 32 and. They are arranged alternately in the height direction (arrow H direction).

The upper end of the steel wall 30 is provided with a pair of wall-side connecting portions 38 to which the pair of vibration damping devices 50 are connected. The pair of wall-side connecting portions 38 project upward from the upper end portion of the grid-like wall 32 and are arranged between the pair of frame-side connecting portions 22. The pair of wall-side connecting portions 38 are installed behind the ceiling. More specifically, the pair of wall-side connecting portions 38 are arranged between the upper beam 16 and the ceiling material (not shown).

As shown in FIG. 2, the wall-side connecting portion (supporting member-side connecting portion) 38 is formed by a steel plate 38A joined to the upper end of the steel wall 30 and a plurality of reinforcing ribs 38B for reinforcing the steel plate 38A. ing.

(Collapse suppression structure)
Here, the steel wall 30 and the upper beam 16 are connected via a tilt suppressing structure 40 that suppresses tilting (deformation) of the steel wall 30 in the wall thickness direction. As shown in FIG. 2, the fall-preventing structure 40 has an engaging plate 42 and a pair of limiting plates 44.

The engagement plate 42 is provided at the upper end of the wall-side connecting portion 38. Further, the engagement plate 42 is formed of a steel plate or the like, and its thickness direction is arranged as the wall thickness direction of the steel wall 30 (out-of-plane direction of the frame 12). The engagement plate 42 extends from the upper end of the wall-side connecting portion 38 toward the upper beam 16 side, and is inserted between the pair of limiting plates 44.

The pair of limiting plates 44 are provided on the lower surface of the upper beam 16. Further, the pair of limiting plates 44 are formed of a steel plate or the like, and are arranged with the thickness direction thereof as the out-of-plane direction of the frame 12 (the wall thickness direction of the steel wall 30). The pair of limiting plates 44 extend from the lower surface of the upper beam 16 to both sides of the engaging plate 42 in the thickness direction. Further, the pair of limiting plates 44 restricts the movement of the engaging plate 42 in the thickness direction, that is, the movement of the steel wall 30 in the wall thickness direction.

The collapse suppressing structure 40 may be provided as needed and may be omitted as appropriate.

(Vibration damping device)
The pair of vibration damping devices 50 are shear link type oil dampers provided with a relief mechanism. The pair of vibration damping devices 50 generate damping force by expanding and contracting in the axial direction.

The pair of vibration damping devices 50 are arranged with the expansion / contraction direction as the lateral width direction of the steel wall 30. Further, one end of each vibration damping device 50 is connected to the wall-side connecting portion 38, and the other end is connected to the frame-side connecting portion 22. The vibration damping device 50 has a cylinder 50A, a piston (not shown) provided in the cylinder 50A, and a rod 50B connected to the piston.

The vibration damping device 50 has a relief mechanism (not shown). The relief mechanism reduces the damping force generated by the vibration damping device 50 when the relative displacement between the frame 12 (frame-side connecting portion 22) and the steel wall 30 (wall-side connecting portion 38) exceeds a predetermined value. Let me.

Specifically, the relief mechanism has, for example, a relief valve provided on the cylinder 50A or the piston. The relief valve has a damping force generated when the relative displacement between the frame 12 (frame-side connecting portion 22) and the steel wall 30 (wall-side connecting portion 38) exceeds a predetermined value, that is, the vibration damping device 50 generates. When it becomes a predetermined value or more, it is opened and the pressure in the cylinder 50A is reduced. As a result, the damping force generated by the vibration damping device 50 is reduced.

The timing at which the relief mechanism operates (a predetermined value of the relative displacement between the frame 12 and the steel wall 30) is appropriately set so that the steel wall 30, particularly the plate-shaped member 36, is not damaged.

(Action)
Next, the operation of this embodiment will be described.

When the frame is sheared and deformed during an earthquake, relative displacement of the steel wall 30 in the lateral width direction (arrow W direction) occurs between the frame side connecting portion 22 and the wall side connecting portion 38. As a result, the vibration damping device 50 connected to the frame side connecting portion 22 and the wall side connecting portion 38 expands and contracts, and a damping force is generated. Therefore, the vibration of the frame 12 is reduced. The vibration damping device 50 generates a damping force depending on the relative speed between the frame side connecting portion 22 and the wall side connecting portion 38.

Here, when the relative displacement amount between the frame side connecting portion 22 and the wall side connecting portion 38 becomes large due to a large earthquake or the like, an earthquake transmitted from the frame side connecting portion 22 to the wall side connecting portion 38 via the vibration damping device 50. The force may be excessive and the steel wall 30 may be damaged. In particular, in the present embodiment, the plate-shaped member 36 of the steel wall 30 is formed of glass blocks. Therefore, if the seismic force acting on the steel wall 30 becomes large, the plate-shaped member 36 may be damaged.

As a countermeasure, in the present embodiment, the vibration damping device 50 is provided with a relief mechanism. The relief mechanism reduces the damping force generated by the vibration damping device 50 when the relative displacement between the frame side connecting portion 22 and the wall side connecting portion 38 becomes a predetermined value or more. As a result, the seismic force input from the frame-side connecting portion 22 to the wall-side connecting portion 38 via the vibration damping device 50 is reduced. Therefore, damage to the steel wall 30 is suppressed.

Further, the steel wall 30 has a grid-like wall 32 and a plate-like member 36. The grid wall 32 has a plurality of openings 34. A plate-shaped member 36 is provided in these openings 34.

Here, the design of the steel wall 30 can be enhanced by appropriately changing the arrangement of the plate-shaped member 36 with respect to the lattice-shaped wall 32. In particular, in the present embodiment, a plurality of plate-shaped members 36 are arranged in a checkered shape (staggered shape). As a result, the design of the steel wall 30 is enhanced.

Further, the plate-shaped member 36 of the present embodiment is made of glass blocks as described above. This makes it possible to realize a transparent steel wall. Therefore, the design of the steel wall 30 can be further enhanced. Further, the daylighting property of the steel wall 30 can be improved.

(Modification example)
Next, a modified example of the above embodiment will be described.

In the above embodiment, the frame 12 is provided with a pair of vibration damping devices 50, but the number of vibration damping devices 50 provided in the frame 12 can be appropriately changed.

Further, in the above embodiment, the vibration damping device 50 is installed between the steel wall 30 and the upper beam 16, but the above embodiment is not limited to this. The vibration control device may be installed, for example, between the steel wall suspended from the upper beam 16 and the lower beam 18. Further, the vibration damping device may be installed between the steel wall provided in the shape of a sleeve wall on one pillar side and the other pillar.

Further, in the above embodiment, the vibration damping device is an oil damper, but the above embodiment is not limited to this. The vibration damping device may have a relief mechanism, and may be, for example, a viscoelastic damper, a friction damper, or the like.

Further, in the above embodiment, a plurality of plate-shaped members 36 are arranged in a staggered manner on the lattice-shaped wall 32 of the steel wall 30, but the number and arrangement of the plate-shaped members 36 can be appropriately changed. Further, the plate-shaped member 36 may be provided in all the openings 34 of the lattice-shaped wall 32.

Further, in the above embodiment, the plate-shaped member 36 is formed of glass blocks, but the above embodiment is not limited to this. The plate-shaped member may be formed of metal, wood, or the like.

Further, in the above embodiment, the steel walls 30 are formed in a grid pattern, but the above embodiment is not limited to this. The steel wall may be, for example, a steel plate wall reinforced by ribs or the like.

Further, in the above embodiment, the steel wall 30 as a support member is provided on the frame 12, but the above embodiment is not limited to this. The support member may be, for example, a reinforced concrete or wooden wall. Further, the support member is not limited to the wall, but may be a brace or the like.

Although one embodiment of the present invention has been described above, the present invention is not limited to such an embodiment, and one embodiment and various modifications may be used in combination as appropriate. Of course, it can be carried out in various embodiments as long as it does not deviate.

10 Vibration damping structure 12 Frame 30 Steel wall (example of support member)
32 Lattice wall 34 Opening 36 Plate-shaped member 50 Vibration damping device

Claims (1)

Framing and
A support member provided in the frame surface of the frame and
A vibration damping device that is connected to the frame and the support member and generates a damping force according to the relative displacement between the frame and the support member.
A relief mechanism provided in the vibration damping device to reduce the damping force generated by the vibration damping device when the relative displacement between the frame and the support member becomes a predetermined value or more.
Equipped with
The support member is
A grid wall with multiple openings and
A plurality of glass blocks provided in a checkered pattern in the plurality of openings, and
Have,
Damping structure.

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