JP2021134646A - Vibration control unit and splice plate - Google Patents

Abstract

To provide a new junction structure of a viscoelastic damper and a structural material of a building.SOLUTION: The vibration control unit 10 comprises a vibration control device 20 and splice plates 41,42. The splice plates 41,42 have first plate parts 41a,42a and second plate parts 41b,42b. The first plate parts 41a,42a are mounted to a first attachment part 21a of an inner plate 21 so as to interpose the first attachment part 21a of the inner plate 21 of the vibration control device 20. The second plate parts 41b,42b extend so as to extend over the inner plate 21. A width of the second plate parts 41b,42b are wider than that of the first plate parts 41a,42a.SELECTED DRAWING: Figure 1

Description

The present invention relates to a vibration control unit and a splicing plate.

Japanese Unexamined Patent Publication No. 2001-146856 discloses an invention relating to an installation structure of a viscoelastic damper installed in a building. The viscoelastic damper disclosed here is a stack of two outer steel plates and one inner steel plate via a viscoelastic material. The two outer steel plates are fixed to the upper beam. One inner steel plate is fixed to the lower beam. A sealing material is arranged around the viscoelastic material.

A joint plate is welded to the lower surface of the upper beam. The joint plate welded to the upper beam is inserted between the two outer steel plates and bolted to the two outer steel plates. On the other hand, a joint plate is welded to the upper surface of the lower beam. The inner steel plate of the viscoelastic damper and the joint plate welded to the lower beam are sandwiched between two plates (splicing plates) and bolted to each of the two plates. Furthermore, a large number of slits are formed in the two plates to be fastened to the inner steel plate of the viscoelastic damper and the joint plate welded to the lower beam, and the two plates are composed of a large number of small plates. It is disclosed that the two plates are made of a low yield point metal material such as ultra-mild steel or a lead alloy.

Japanese Unexamined Patent Publication No. 2001-146856

By the way, in the viscoelastic damper installed in the building, a shearing force acts according to the relative displacement between the upper beam and the lower beam of the building at the time of an earthquake. At this time, a large force acts on the portion connecting the viscoelastic damper and the structural material of the building. According to the study of the present inventor, when the part connecting the viscoelastic damper and the structural material of the building does not have sufficient joint strength, a large force is applied to the part connecting the viscoelastic damper and the structural material of the building. When it acts, an appropriate force does not act on the viscoelastic damper, and the viscoelastic damper cannot exhibit its performance. On the other hand, it is desired to secure sufficient joint strength for the member connecting the viscoelastic damper and the structural material of the building, but if the member strength is increased more than necessary, the material cost and the weight of the member increase. From this point of view, we would like to reduce the cost while ensuring the strength required for the member connecting the viscoelastic damper and the structural material of the building.

One embodiment of the seismic control unit disclosed herein includes a seismic control device and two splicing plates. The seismic control device includes an inner plate, a first outer plate facing one side of the inner plate, a second outer plate facing the first outer plate on the opposite side of the inner plate, and an inner plate. A first viscoelastic body arranged between the outer plate and the first outer plate and vulcanized and adhered to the inner plate and the first outer plate, and a position where the first viscoelastic body is vulcanized and adhered to the inner plate. At the same position, a second viscoelastic body is provided between the inner plate and the second outer plate and vulcanized and adhered to the inner plate and the second outer plate. The inner plate extends in one direction from the position where the first viscoelastic body and the second viscoelastic body are vulcanized and adhered, and has a first mounting portion at the extended portion. The first outer plate and the second outer plate face each other at a portion extending in a direction opposite to the direction in which the inner plate extends from the position where the first viscoelastic body and the second viscoelastic body are vulcanized and adhered, respectively. In addition, each of the extended portions has a second mounting portion. The two splicing plates have a first plate portion and a second plate portion. The first plate portion is attached to the first attachment portion of the inner plate so as to sandwich the first attachment portion of the inner plate. The second plate portion extends so as to protrude from the inner plate. The width of the second plate portion is wider than that of the first plate portion.

According to such a vibration control unit, a moment larger than that of the first plate portion can be applied to the second plate portion due to the reaction force against the shear deformation of the viscoelastic body. Since the width of the second plate portion is wider than that of the first plate portion, the required joint strength is secured for the splicing plate. Therefore, the viscoelastic body can be appropriately subjected to shear deformation. The splicing plate is a plate-shaped member, and can achieve both securing of joining strength and cost reduction.

Further, the splicing plate disclosed here is superposed on the plate on the structural material side and the plate on the seismic control device side, and is joined to the plate on the structural material side and the plate on the seismic control device side. Is. The splicing plate has a first plate portion attached to the plate on the vibration control device side and a second plate portion attached to the plate on the structural material side. The width of the second plate portion is wider than that of the first plate portion.

Such a splicing plate may have a corner portion at a portion where the width of the second plate portion is wider than that of the first plate portion, and the corner portion may be subjected to relief processing. The shape of the relief process may be an arc.

FIG. 1 is a front view of the vibration control unit 10. FIG. 2 is a sectional view taken along line II-II. FIG. 3 is a front view of the splicing plate 41.

Hereinafter, the vibration control unit and the splicing plate disclosed here will be described with reference to the drawings. The present invention is not limited to the following embodiments. Each drawing is schematically drawn and does not necessarily reflect the real thing. In addition, each drawing shows only one example, and does not limit the present invention unless otherwise specified. In addition, members and parts that perform the same action are appropriately designated by the same reference numerals, and duplicate description will be omitted. The directions of up, down, left, right, front, and back are represented by arrows U, D, L, R, F, and Rr in the figure, respectively.

FIG. 1 is a front view of the vibration control unit 10. FIG. 2 is a sectional view taken along line II-II. FIG. 3 is a front view of the splicing plate 41. In this embodiment, the splicing plates 41 and 42 have the same shape. In FIG. 3, the reference numerals of the respective parts of the splicing plate 42 are shown in parentheses.

<Damping unit 10>
As shown in FIGS. 1 and 2, the vibration control unit 10 includes a vibration control device 20 and two splicing plates 41 and 42. The vibration control unit 10 is attached to a pair of connecting steel plates 101 and 102 facing each other provided in a building (not shown). Here, the pair of connecting steel plates 101 and 102 may be members connected to the pair of structural members facing each other in the building. Here, the pair of structural members may be, for example, a pair of horizontal members (bases and beams) facing each other in the vertical direction. It can also be a pair of pillars in a building. The pair of connecting steel plates 101 and 102 may be welded to, for example, a pair of structural materials constituting the building frame.

<Connected steel plates 101, 102>
Here, the connecting steel plates 101 and 102 may be shaped steels such as so-called H-shaped steels. The connecting steel plates 101 and 102 shown in FIGS. 1 and 2 are H-shaped steels, respectively. The connecting steel plates 101 and 102 are welded to a pair of horizontal timbers (bases and beams) of the building, and extend vertically into the space between the pair of horizontal timbers. Further, the webs 101a and 102a of the connecting steel plates 101 and 102 are arranged so as to face each other vertically. When a building shakes greatly due to an earthquake or the like, the connecting steel plates 101 and 102 are relatively displaced according to the relative displacement of the pair of horizontal members of the building.

<Damping device 20>
As shown in FIG. 2, the vibration control device 20 includes an inner plate 21, a first outer plate 23, a second outer plate 24, a first viscoelastic body 25, and a second viscoelastic body 26. It has.

The inner plate 21, the first outer plate 23, and the second outer plate 24 may be plate materials having required strengths, respectively. For the inner plate 21, the first outer plate 23, and the second outer plate 24, for example, a steel plate having a required thickness is used. The first viscoelastic body 25 and the second viscoelastic body 26 are preferably so-called viscoelastic bodies. Materials that generate a required damping force in response to shear deformation are used for the viscoelastic bodies 25 and 26. As the material used for the viscoelastic bodies 25 and 26, for example, styrene-based, urethane-based, acrylic-based, isobutylene-based, silicon-based, diene-based, and isoprene-based elastomers are suitable. In particular, a material having less temperature dependence is more preferable, and a rubber material such as so-called high damping rubber can be adopted. Further, as the viscoelastic bodies 25 and 26, various viscoelastic bodies used as vibration damping rubbers for buildings can be adopted.

The inner plate 21 extends in one direction from the position where the first viscoelastic body 25 and the second viscoelastic body 26 are vulcanized and adhered, and has a first mounting portion 21a at the extended portion. The first outer plate 23 and the second outer plate 24 extend in the direction opposite to the direction in which the inner plate 21 extends from the positions where the first viscoelastic body 25 and the second viscoelastic body 26 are vulcanized and adhered, respectively. The second attachment portions 23a and 24a are provided at the portions facing each other and at the extended portions, respectively. In the vibration control device 20, shear displacement is applied to the first viscoelastic body 25 and the second viscoelastic body 26 according to the relative displacement between the first outer plate 23 and the second outer plate 24 and the inner plate 21. Entered. The first viscoelastic body 25 and the second viscoelastic body 26 exert an elastic reaction force corresponding to the shear deformation on the inner plate 21, the first outer plate 23, and the second outer plate 24. Further, the first viscoelastic body 25 and the second viscoelastic body 26 are made of a viscoelastic body. Therefore, when shear deformation occurs in the first viscoelastic body 25 and the second viscoelastic body 26, energy is consumed according to the shear deformation. The first outer plate 23 and the second outer plate 24 are appropriately referred to as outer plates 23 and 24.

In the form shown in FIGS. 1 and 2, the vibration control device 20 is attached to a pair of connecting steel plates 101 and 102 facing each other, which are attached to the frame of the building. In this embodiment, the connecting steel plates 101 and 102 face each other vertically. The vibration control device 20 is arranged between the connecting steel plates 101 and 102. In the form shown in FIGS. 1 and 2, the first outer plate 23 and the second outer plate 24 of the vibration control device 20 are directed upward, and the inner plate 21 is directed downward. That is, the portion of the first outer plate 23 and the second outer plate 24 that extends beyond the first viscoelastic body 25 and the second viscoelastic body 26 is directed upward, and the first of the inner plates 21. The portion extending beyond the viscoelastic body 25 and the second viscoelastic body 26 is directed downward. That is, the second mounting portions 23a and 24a provided on the first outer plate 23 and the second outer plate 24 are directed upward. Further, the first mounting portion 21a provided on the inner plate 21 is directed downward.

Then, as shown in FIG. 2, the second mounting portions 23a and 24a provided on the first outer plate 23 and the second outer plate 24 sandwich the web 101a of the upper connecting steel plate 101 and are on the upper side. It is attached to the connecting steel plate 101 of. In this embodiment, spacers 27 and 28 are sandwiched between the first outer plate 23, the second outer plate 24, and the upper connecting steel plate 101. In this embodiment, the first outer plate 23 and the second outer plate 24 are attached to the upper connecting steel plate 101 with bolts and nuts 33. Further, bolt insertion holes are formed in the second mounting portions 23a and 24a and the web 101a of the upper connecting steel plate 101, respectively.

The first mounting portion 21a of the inner plate 21 is arranged so as to be vertically aligned with the web 102a of the lower connecting steel plate 102. Here, the lower end edge 21a1 of the first mounting portion 21a of the inner plate 21 and the upper end edge 102a1 of the web 102a of the lower connecting steel plate 102 face each other vertically. The first mounting portion 21a of the inner plate 21 facing vertically and the web 102a of the lower connecting steel plate 102 are connected by splicing plates 41 and 42.

<Splicing plates 41, 42>
The splicing plates 41 and 42 are preferably plate materials having required strengths, respectively. For the splicing plates 41 and 42, for example, steel plates having a required thickness are used. As shown in FIGS. 1 and 2, the splicing plates 41 and 42 include first plate portions 41a and 42a and second plate portions 41b and 42b, respectively.

As shown in FIG. 2, the first plate portions 41a and 42a are portions to be attached to the first attachment portion 21a of the inner plate 21 so as to sandwich the first attachment portion 21a of the inner plate 21. In this embodiment, the first plate portions 41a and 42a are attached to the first attachment portion 21a of the inner plate 21 by bolts and nuts 31. Further, bolt insertion holes are formed in the first plate portions 41a and 42a and the first mounting portion 21a of the inner plate 21, respectively.

The second plate portions 41b and 42b extend so as to protrude from the inner plate 21, are overlapped with the web 102a of the lower connecting steel plate 102, and are attached to the lower connecting steel plate 102. In this embodiment, the second plate portions 41b and 42b are attached to the lower connecting steel plate 102 by bolts and nuts 32. Further, bolt insertion holes are formed in the second plate portions 41b and 42b and the web 102a of the lower connecting steel plate 102, respectively.

The width d2 of the second plate portions 41b, 42b of the splicing plates 41, 42 is wider than the width d1 of the first plate portions 41a, 42a, as shown in FIG. In this embodiment, the width d1 of the first plate portions 41a and 42a is approximately the same as the width of the inner plate 21. On the other hand, the widths d2 of the second plate portions 41b and 42b are set remarkably wide. As a result, more bolts and nuts are attached to the second plate portions 41b and 42b, which are wider than the first plate portions 41a and 42a and larger than those of the first plate portions 41a and 42a.

For example, as shown in FIG. 1, when a large shaking occurs in a building, the upper connecting steel plate 101 moves to the right with respect to the lower connecting steel plate 102 as shown by an arrow X. Further, the upper connecting steel plate 101 and the lower connecting steel plate 102 move in relatively opposite directions. At this time, the outer plates 23 and 24 connected to the upper connecting steel plate 101 move in the direction of the arrow X or in the opposite direction as in the upper connecting steel plate 101. The inner plate 21 is connected to the lower connecting steel plate 102 via the splicing plates 41 and 42. Therefore, the viscoelastic bodies 25 and 26 are sheared and deformed between the inner plate 21 and the outer plates 23 and 24. Further, the reaction force against the shear deformation of the viscoelastic bodies 25 and 26 acts on the joints between the inner plate 21, the splicing plates 41 and 42 and the lower connecting steel plate 102, respectively. Further, a reaction force against shear deformation of the viscoelastic bodies 25 and 26 also acts on the joint portion between the outer plates 23 and 24 and the upper connecting steel plate 101.

In this case, as shown in FIG. 1, in the splicing plates 41 and 42, the center P1 of the first plate portions 41a and 42a attached to the inner plates 21 is attached to the lower connecting steel plate 102. The distance from the viscoelastic bodies 25 and 26 is longer than the center P2 of the plate portions 41b and 42b. Here, P0 in FIG. 1 is a force point on which the reaction force against the shear deformation of the viscoelastic bodies 25 and 26 acts. P0 may be set at the center of the viscoelastic bodies 25 and 26, for example. P1 is a force point on which the bonding force between the inner plate 21 and the splicing plates 41 and 42 acts. P1 may be set at the center (center of gravity) of the first plate portions 41a and 42a, for example. P2 is a force point on which the bonding force between the second plate portions 41b and 42b and the connecting steel plate 102 acts. P2 may be set at the center (center of gravity) of the second plate portions 41b and 42b, for example. Further, P3 is a force point on which the bonding force between the outer plates 23 and 24 and the connecting steel plate 101 acts. P3 may be set at the center of the region where the outer plates 23 and 24 and the connecting steel plate 101 are joined, for example.

The distance e2 from the viscoelastic bodies 25 and 26 to the center P2 of the second plate portions 41b and 42b is longer than the distance e1 from the viscoelastic bodies 25 and 26 to the center P1 of the first plate portions 41a and 42a. Therefore, due to the reaction force against the shear deformation of the viscoelastic bodies 25 and 26, a larger moment is applied to the second plate portions 41b and 42b than the first plate portions 41a and 42a.

In the splicing plates 41 and 42 that sandwich and connect the inner plate 21 and the lower connecting steel plate 102, the vibration damping unit 10 has a second plate portion rather than the width d1 of the first plate portions 41a and 42a. The width d2 of 41b and 42b is wide. That is, the width d2 of the second plate portions 41b and 42b attached to the lower connecting steel plate 102 is wider than the width d1 of the first plate portions 41a and 42a attached to the inner plate 21. More bolts and nuts are attached to the second plate portions 41b and 42b of the splicing plates 41 and 42 than those of the first plate portions 41a and 42a.

Therefore, even when a moment larger than that of the first plate portions 41a and 42a is applied to the second plate portions 41b and 42b due to the reaction force against the shear deformation of the viscoelastic bodies 25 and 26, the splicing plate 41, The required joint strength is secured in 42. Therefore, the viscoelastic bodies 25 and 26 can be appropriately subjected to shear deformation.

In this embodiment, the second plate portions 41b and 42b are widened by the same width on both sides of the first plate portions 41a and 42a in the width direction. Further, in this embodiment, the second plate portions 41b and 42b are wider in the length direction orthogonal to the first plate portions 41a and 42a, and the area is wider. Further, a total of 12 bolts and nuts 31 are attached to the first plate portions 41a and 42a in an arrangement of 6 rows × 2 columns. On the other hand, 24 bolts and nuts 32 are attached to the second plate portions 41b and 42b in an arrangement of 8 rows × 3 columns. Further, bolts and nuts 31 and 32 are arranged on the first plate portions 41a and 42a and the second plate portions 41b and 42b so as to be biased to both sides more than the center in the width direction, respectively. As described above, in this embodiment, more bolts and nuts are arranged on the second plate portions 41b and 42b on which a moment larger than that on the first plate portions 41a and 42a is applied, which is required for the splicing plates 41 and 42. The joint strength of is secured. Further, in the first plate portions 41a and 42a and the second plate portions 41b and 42b, the same degree of spacing is secured between the bolts and nuts 32 and 33 to be attached. Further, since the areas of the second plate portions 41b and 42b are large, the degree of freedom in design such as the diameter of the bolts that can be used and the arrangement of the bolts is improved.

Further, in this embodiment, the inner plate 21 is a single plate. The inner plate 21 is connected to the lower connecting steel plate 102 via splicing plates 41 and 42. The outer plates 23 and 24 are two plates. The outer plates 23 and 24 are directly connected with the upper connecting steel plate 101 interposed therebetween. Further, considering the manufacturing cost, it is desired to keep the molding equipment for molding the viscoelastic bodies 25 and 26 small. Therefore, the distance between the inner plate 21 and the outer plates 23 and 24 protruding from the viscoelastic bodies 25 and 26 cannot be unnecessarily long. In this embodiment, the distances between the inner plate 21 and the outer plates 23 and 24 protruding from the viscoelastic bodies 25 and 26 are substantially the same, respectively. The splicing plates 41 and 42 are further attached to the inner plate 21. Therefore, the distance e2 from the viscoelastic bodies 25 and 26 to the center P2 of the second plate portions 41b and 42b is longer than the distance e1 from the viscoelastic bodies 25 and 26 to the center P1 of the first plate portions 41a and 42a. Become.

Then, as shown in FIG. 1, the center P2 of the second plate portions 41b, 42b of the splicing plates 41, 42 attached to the lower connecting steel plate 102 is an outer plate attached to the upper connecting steel plate 101. It is farther from the center P0 of the viscoelastic bodies 25 and 26 than the center P3 of the second mounting portions 23a and 24a provided on the 23 and 24. That is, the distance e2 from the viscoelastic bodies 25, 26 to the center P2 of the second plate portions 41b, 42b is larger than the distance e3 to the center P3 of the second mounting portions 23a, 24a provided on the outer plates 23, 24. become longer. The reaction force from the viscoelastic bodies 25 and 26 acts on the site P2 and the site P3 in the same manner. Therefore, a larger moment is applied to the portion P2 than to the portion P3. On the other hand, the width d2 of the second plate portions 41b and 42b attached to the lower connecting steel plate 102 is larger than the width d3 of the second attachment portions 23a and 24a of the outer plates 23 and 24 (see FIG. 1). wide. Therefore, even when a moment larger than that of the outer plates 23 and 24 is applied to the second plate portions 41b and 42b due to the reaction force against the shear deformation of the viscoelastic bodies 25 and 26, the splicing plates 41 and 42 are affected. The required joint strength is secured. Therefore, the viscoelastic bodies 25 and 26 can be appropriately subjected to shear deformation.

Further, in this embodiment, the splicing plates 41, 42 have a width of the second plate portions 41b, 42b wider than that of the first plate portions 41a, 42a, as shown in FIGS. 1 and 3. The portions have corners 41c and 42c, and the corners 41c and 42c are subjected to relief processing. Here, the shape of the relief process is an arc. Due to the relief processing, stress is less likely to concentrate on the portion where the width of the second plate portions 41b and 42b is wider than that of the first plate portions 41a and 42a, and the splicing plates 41 and 42 are broken. It becomes difficult. In this embodiment, the shape of the relief process is an arc from the viewpoint of relaxing the stress concentration. Unless otherwise specified, the shape of the relief process is not limited to an arc. Further, since the width of the joint on the support member side can be freely set, the required joint strength can be easily secured.

The vibration control unit and the splicing plate disclosed here have been described in various ways, but the vibration control device disclosed here is not limited to the above-described embodiment or modification unless otherwise specified. In addition, the configurations of the embodiments and modifications described in various ways can be appropriately combined as long as they do not interfere with each other.

10 Vibration control unit 20 Seismic control device 21 Inner plate 21a First mounting part 21a1 Lower end edge 23,24 of first mounting part 21a Outer plate 23a, 24a Second mounting part 25,26 Viscoelastic body 27,28 Spacer 31, 32 , 33 Bolts and nuts 41, 42 Splicing plates 41a, 42a First plate portions 41b, 42b Second plate portions 41c, 42c Square portions 101, 102 Connecting steel plates 101a, 102a Web 102a1 Upper end edge of connecting steel plates 102 on the lower side

Claims (6)

Seismic control device and
Equipped with two splicing plates
The vibration control device is
Inner plate and
The first outer plate facing one side of the inner plate and
On the opposite side of the inner plate, the second outer plate facing the first outer plate with the inner plate sandwiched between them.
A first viscoelastic body arranged between the inner plate and the first outer plate and vulcanized and adhered to the inner plate and the first outer plate.
At the same position where the first viscoelastic body is vulcanized and adhered to the inner plate, it is arranged between the inner plate and the second outer plate, and on the inner plate and the second outer plate. With a second viscoelastic body vulcanized and bonded,
The inner plate
The first viscoelastic body and the second viscoelastic body extend in one direction from the position where the second viscoelastic body is vulcanized and adhered, and the extended portion has a first attachment portion.
The first outer plate and the second outer plate are
The first viscoelastic body and the second viscoelastic body face each other at a portion extending in a direction opposite to the direction in which the inner plate extends from the position where the first viscoelastic body and the second viscoelastic body are vulcanized and adhered, and the second viscoelastic body faces the extended portion. Each has a mounting part,
The two splicing plates are
A first plate portion attached to the first attachment portion of the inner plate so as to sandwich the first attachment portion of the inner plate, and a first plate portion.
It has a second plate portion that extends so as to protrude from the inner plate.
The width of the second plate portion is wider than that of the first plate portion.
Seismic control unit. The splicing plate according to claim 1, wherein the splicing plate has a corner portion at a portion where the width of the second plate portion is wider than that of the first plate portion, and the corner portion is subjected to relief processing. Seismic control unit. The vibration control unit according to claim 2, wherein the relief processing has an arcuate shape. A splicing plate that is superposed on a plate on the structural material side and a plate on the vibration control device side and joined to the plate on the structural material side and the plate on the vibration control device side.
The first plate part attached to the plate on the vibration control device side and
It has a second plate portion that is attached to the plate on the structural material side.
The width of the second plate portion is wider than that of the first plate portion.
Splicing board. The splicing plate according to claim 4, wherein the second plate portion has a corner portion at a portion where the width of the second plate portion is wider than that of the first plate portion, and the corner portion is subjected to relief processing. The splicing plate according to claim 5, wherein the relief processing shape is an arc.

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