KR101191726B1 - Damping device for structure - Google Patents

Abstract

The present invention relates to a vibration damping device for a structure that can satisfy both comfort and safety of a building employing the same by attenuating various external forces such as micro vibration and relatively high vibration. The proposed vibration damper for the structure includes a first support connected to one side of the structure; A second support connected to the other side of the structure; A sliding member slidably installed between the first support and the first support; A viscoelastic member interposed between the first support and the sliding member for vibration damping; A displacement limiting device provided on the first support and the sliding member to limit the slip displacement of the first support and the sliding member to a set range; Cover plates respectively covering both outer surfaces of the sliding member and fixed to the second support; Friction members interposed between the sliding member and the plate; It includes a fastening unit for fastening the plate to the sliding member to have a damping force greater than the damping force by the viscoelastic member.

Description

Damping device for structures {DAMPING DEVICE FOR STRUCTURE}

The present invention relates to a structure vibration suppression apparatus, and more particularly, to a structure vibration suppression apparatus capable of stably protecting a structure in response to various external forces such as micro vibration and relatively high intensity vibration.

External forces acting on building / civil engineering structures come in various forms such as wind loads and earthquake loads. Such external forces can cause torsion or similar deformation of the structure, which can cause serious damage or collapse of the structure.

As a method of protecting a structure from an external force such as an earthquake or wind, there is a method of reinforcing the structure itself and a method of installing a separate vibration damper in the structure to dissipate energy transferred to the structure. Among them, the latter is widely used because the external force acts on the vibration suppression device to prevent plastic deformation of the structure itself, thereby protecting the structure, and because it is easy to repair and reinforce and relatively inexpensive.

Among vibration damping devices, friction type vibration damping devices are known which dissipate energy by providing two members which are mutually slippery at a position where a displacement of a structure occurs so that friction acts between the two members.

However, since the conventional friction type vibration damping device is installed in a structure in a state set to have a constant frictional strength, there is a problem that it is difficult to effectively attenuate it when an external force of various sizes acts on the structure employing it. In other words, if it is set to have relatively large frictional strength, it does not attenuate small external forces such as a small earthquake or wind, and conversely, if it is set to have a small frictional strength, it can It was difficult to expect a substantial damping effect.

The present invention is to solve such a problem, an object of the present invention to provide a vibration damping device for a structure that can attenuate a variety of external forces, such as small vibration and relatively high intensity vibration.

The vibration suppression apparatus for a structure according to the present invention for achieving this object includes a first support connected to one side of the structure; A second support connected to the other side of the structure; A sliding member slidably installed between the first support and the first support; A viscoelastic member interposed between the first support and the sliding member for vibration damping; A displacement limiting device provided on the first support and the sliding member to limit the slip displacement of the first support and the sliding member to a set range; Cover plates respectively covering the outer surface of both sides of the sliding member and fixed to the second support; Friction members interposed between the sliding member and the plate; And a fastening unit for fastening the plate to the sliding member so as to have a damping force greater than that of the viscoelastic member.

The sliding member is disposed so as to face the first support body, the first sliding plate having the viscoelastic member coupled to the outer surface thereof, extending vertically from the first sliding plate toward the second support body, and the friction member on both outer surfaces thereof. It may include a second sliding plate in which the plate is installed in the state.

The displacement limiting device includes a protrusion that protrudes from the one of the first support and the first sliding plate to the opposite side, and a width wider than the protrusion on the other of the first support and the first sliding plate so that the protrusion enters. It may include a locking groove formed as.

The displacement limiting device may include: a protrusion that protrudes from any one of the first support and the first sliding plate so as to be slidably supported on the opposite side, and the slip of the first support and the first sliding plate is greater than or equal to a set range. It may include a locking groove formed in the other of the first support and the first sliding plate so that the protrusion can be caught and restrained.

The fastening unit includes a plurality of bolts passing through the second sliding plate, the friction members, and the plate, a plurality of nuts fastened to the respective bolts, and each of the bolts to maintain a fastening force even when the friction member is worn. A spring washer is installed in the bolt, and the second sliding plate includes a bolt coupling hole formed in a sliding direction in a portion through which the bolt passes.

The second support may include a fixed plate fixed to the structure, a support extending vertically from the fixed plate toward the second sliding plate to slidably support the second sliding plate, and both side surfaces of the support for coupling the plate. It includes a plurality of coupling protrusions protruding from the, the plate may include a plurality of coupling holes coupled to correspond to the coupling protrusion.

In addition, the vibration suppression apparatus for a structure according to the present invention includes a first support plate connected to one side of the structure; A first sliding plate extending vertically from the first supporting plate; A second sliding plate whose end is slidably contacted with an end of the first sliding plate; A displacement limiting device provided at a portion in which the first sliding plate and the second sliding plate are in contact with each other to limit slip displacement of the second sliding plate to a set range; Cover plates installed to cover outer surfaces of both sides of the first sliding plate and the second sliding plate and having a length longer than that of the first and second sliding plates; Viscoelastic members interposed between both outer surfaces of the first sliding plate and the plate for vibration damping; Friction members interposed between both outer surfaces of the second sliding plate and the plate; Second and third support plates respectively coupled to longitudinal ends of the plate plates and connected to the other side of the structure to support the plate plates; And a fastening unit configured to press the plate to the second sliding plate so as to have a damping force greater than that of the viscoelastic member.

The displacement limiting device may further include a protrusion projecting from the one of the first sliding plate and the second sliding plate to the opposite side, and the other portion of the first sliding plate and the second sliding plate so that the protrusion enters. It may include a locking groove formed in a wide width.

The plate is installed on both sides of the outer side of the first sliding plate to support the viscoelastic member, the first plate with coupling protrusions coupled to the second and third support plate at both ends thereof, and both sides of the second sliding plate Pressurizing the friction members on an outer surface thereof, and second plate plates having coupling protrusions coupled to the second and third support plates at both ends thereof, wherein the second and third support plates are coupled with the coupling protrusions of the first plate plates. The first coupling holes may include second coupling holes coupled to the coupling protrusions of the second plate.

The fastening unit includes a plurality of bolts passing through the second sliding plate, the friction members, and the second cover plate, a plurality of nuts fastened to the respective bolts, and the fastening force even when the friction member is worn. A spring washer is installed on each of the bolts, and the second sliding plate may include a bolt coupling hole formed in a sliding direction in a portion through which the bolt passes.

The second coupling holes may include a long hole elongated in the pressing direction of the friction member so that at least one of the second cover plates may move in the direction of pressing the friction member.

In addition, the vibration suppression apparatus for a structure according to the present invention includes a first support plate connected to one side of the structure; A first sliding plate extending vertically from a lower surface of the first support plate; A second sliding plate having an upper end installed in contact with a lower end of the first sliding plate, and a third sliding plate having an upper end installed in contact with a lower end of the second sliding plate; A first displacement limiting device for limiting a slip displacement of the first sliding plate and the second sliding plate to a setting range and a second displacement limiting limiting slip displacement of the second sliding plate and the third sliding plate to a setting range An apparatus; First, second and third cover plates installed to cover both outer surfaces of the first to third sliding plates, respectively, and having a length longer than that of the first to third sliding plates; Viscoelastic members interposed between the outer surfaces of both sides of the first sliding plate and the first plate for vibration damping; First friction members interposed between both outer surfaces of the second sliding plate and the second plate, and second friction members interposed between the outer surface of the third sliding plate and the third plate; Second and third support plates respectively coupled to the longitudinal ends of the respective plate plates to support the first to third plate plates and connected to the other side of the structure; The first plate unit and the third plate plate with a greater force than the first plate unit and the first plate unit for pressing the second plate plate toward the second sliding plate so as to have a damping force greater than the damping force by the viscoelastic member. It characterized in that it comprises a second fastening unit for fastening by pressing toward.

The vibration damping device for a structure according to the present invention can dissipate an external force by damping a viscoelastic member when a small external force acts on the structure by a small earthquake or wind, and when a large external force acts like a earthquake with a relatively high strength, the friction member Because the external force can be dissipated by the friction attenuation of the structure, there is an effect that can stably protect the structure from various external forces. In other words, a building that adopts it by dissipating small vibration or vibration by damping the viscoelastic member can create a comfortable living environment, and by dissipating large external force such as a large earthquake by friction attenuation of the friction member, As it can be increased, it is possible to satisfy both comfort and safety simply by installing one type of vibration damper.

In addition, when the vibration damping device for a structure according to the present invention is installed in a building, the bolts and nuts of the fastening unit are exposed to the sides of the plates, so that the manager can easily access and maintain the maintenance such as controlling the tightening force or replacing some parts. There is an easy advantage

1 is a perspective view of a vibration suppression apparatus according to a first embodiment of the present invention.
2 is an exploded perspective view of the vibration suppression apparatus according to the first embodiment of the present invention.
Figure 3 is a side view of the vibration suppression apparatus according to the first embodiment of the present invention, showing a state in which the damping by the viscoelastic member.
4 is a side view of the vibration suppression apparatus according to the first embodiment of the present invention, and shows a state where the damping is performed by the friction member.
5 is a side view of the vibration suppression apparatus according to the second embodiment of the present invention, and shows a state in which attenuation is performed by the viscoelastic member.
6 is a side view of the vibration suppression apparatus according to the second embodiment of the present invention, and shows a state in which the damping is performed by the friction member.
7 to 11 show an example in which the vibration damping device according to the present invention is installed in various ways in a building structure.
12 is a perspective view of a vibration suppression apparatus according to a third embodiment of the present invention.
13 is an exploded perspective view of a vibration suppression apparatus according to a third embodiment of the present invention.
FIG. 14 is a side view of the vibration suppression apparatus according to the third exemplary embodiment of the present invention and shows a state in which the damping is performed by the viscoelastic member.
15 is a side view of the vibration suppression apparatus according to the third exemplary embodiment of the present invention, and shows a state in which the damping is performed by the friction member.
16 is a perspective view of a vibration suppression apparatus according to a fourth embodiment of the present invention.
17 is an exploded perspective view of a vibration suppression apparatus according to a fourth embodiment of the present invention.
18 is a side view of a vibration suppression apparatus according to a fourth embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 show a vibration suppression apparatus according to a first embodiment of the present invention. 2 and 3, the vibration suppression apparatus 100 of the first embodiment includes an upper first support 110 supported on one side of a structure and a lower second support 120 supported on an opposite side of the structure. ), A sliding member 130 slidably installed between the first support 110 and the second support 120, and the first support 110 and the sliding member (a) to damp vibrations caused by wind or small earthquakes. 130 is provided between the viscoelastic member 140.

In addition, the vibration suppression apparatus 100 includes plate plates 150 having a lower portion fixed to the second support 120 and an upper portion covering both outer surfaces of the sliding member 130, the plate plates 150 and the sliding member ( The damping force (friction strength) by the friction members 160 and the friction members 160 installed between the 130 members is greater than the damping force by the viscoelastic member 140 mentioned above, thereby damping a relatively large magnitude of vibration. It includes a fastening unit 180 for fastening by pressing the plate 150 to the sliding member 130 to be able to.

The first support 110 is provided in the form of a rectangular flat plate, the upper surface is coupled to the connecting member 111 to be fixed to one side of the structure. The connecting member 111 may be provided in the form of a conventional H beam to reinforce the upper portion of the first support 110, but the shape thereof is not limited thereto. The connecting member 111 may be directly connected to the structure or connected to the structure through a separate support member (not shown) extending from the structure. As shown in FIG. 1, the connecting member 111 and the first support 110 may be firmly coupled to each other by fastening a plurality of coupling bolts 112.

The sliding member 130 is perpendicular to the second supporting member 120 from the lower surface of the first sliding plate 131 and the lower surface of the first sliding plate 131, the upper surface of which is disposed to face the lower surface of the first support 110. The second sliding plate 132 is extended to achieve a lower end of which is slidably supported by the second support member 120. The sliding member 130 is provided such that the first sliding plate 131 and the second sliding plate 132 have a T-shaped cross-sectional structure.

The viscoelastic member 140 is made of a material having both elasticity, which is a characteristic of a solid, and viscosity, which is a characteristic of a liquid. An upper surface of the viscoelastic member 140 is supported in contact with the lower surface of the first support 110, the lower surface is supported in contact with the upper surface of the first sliding plate 131. The viscoelastic member 140 dissipates energy applied from the outside while shearing when the relative displacement of the first support 110 and the first sliding plate 131 occurs due to the vibration of the structure, so that the earthquake of a small scale or wind It functions to attenuate vibration caused by the back.

The second support member 120 is fixed to the plate-shaped fixing plate 121 fixed to the other side of the structure, and extends perpendicularly from the upper surface of the fixing plate 121 toward the second sliding plate 132, the upper end of the second sliding plate ( 132) a support 122 for slidably supporting the lower end. The fixing plate 121 of the second support member 120 may be directly coupled to the structure by the fastening of the fixing bolt (not shown) or may be coupled to the structure via a separate support member (not shown) like the first support member 110. Can be.

The plate 150 is in the form of a flat plate that can cover the side of the support portion 122 of the second support 120 and the side of the second sliding plate 132 of the sliding member 130, the second sliding plate 132 ) It is installed on both sides. The plate 150 is fixed to the support 122 of the second support 120 so that the bottom plate 150 moves together with the second support 120. To this end, a plurality of coupling protrusions 123 protruding from both sides are provided at the support part 122 of the second support 120, and the plate 150 is coupled to a plurality of coupling protrusions corresponding to each coupling protrusion 123. The ball 151 is provided.

The friction members 160 are in the form of thin pads interposed between both sides of the second sliding plate 132 and the plate 150. The friction members 160 are attached to the fastening unit 180 so that both sides thereof are in close contact with the top plate 150 and the second sliding plate 132, respectively. These friction members 160 implement damping due to friction when relative slip displacement of the second sliding plate 132 and the face plate 150 occurs due to the vibration of the structure.

The fastening unit 180 includes a plurality of bolts 181 installed to penetrate the second sliding plate 132, the friction members 160, and the plate 150, and a plurality of nuts fastened to the respective bolts 181 ( 182 and spring washers 183 installed in each bolt 181 to maintain the fastening force even when the friction members 160 are worn after the bolt 181 and the nut 182 are fastened. In addition, the second sliding plate 132 is provided with a bolt coupling hole 133 formed long in the sliding direction at a portion through which the bolts 181 pass. Even after mounting of the fastening unit 180, the second sliding plate 132 can be slid within the length of the bolt coupling hole 133 so that the relative displacement of the second sliding plate 132 and the plate 150 may occur. In this way, the friction damping can be realized.

The fastening unit 180 may adjust the vertical drag applied to both sides of the friction member 160 by adjusting the fastening force through a conventional torque wrench. That is, the frictional force can be easily adjusted by adjusting the clamping force. The fastening force of the fastening unit 180 is preferably adjusted to attenuate the vibration or external force of a relatively large scale because the damping force of the vibration by the friction member 160 is greater than the damping force of the vibration by the viscoelastic member 140. This allows a small amount of vibration to be attenuated by the viscoelastic member 140 and a relatively large amount of vibration to be attenuated by the frictional strength of the friction member 160. The purpose is to damp vibrations.

The first support 110 and the first sliding plate 131 are provided with a displacement limiting device 170 for limiting the slip displacement of the first support 110 and the first sliding plate 131 to a set range. This is caused by the friction caused by the relative slip displacement of the second sliding plate 132 and the plate 150 when an external force (relatively large earthquake, etc.) acts larger than the damping force of the vibration by the viscoelastic member 140 is applied. Attenuation can be made. That is, the viscoelastic member 140 may attenuate the small vibration, such as wind or small earthquake, but the frictional force of the friction member 160 may be applied to the large scale vibration exceeding the damping ability of the viscoelastic member 140. It can be attenuated by

The displacement limiting device 170 includes a plurality of protrusions 171 protruding from the lower surface of the first support 110 toward the first sliding plate 131, and an upper surface of the first sliding plate 131 to enter the protrusion 171. It may be made of a locking groove 172 formed in a wider width than the protrusion 171 to. This causes the vibration to be attenuated only by the viscoelastic member 141 by causing the protrusion 171 to move within the range of the locking groove 172 as shown in FIG. 3. And when the vibration of a relatively large scale as shown in Figure 4 as the behavior of the protrusion 171 increases, the protrusion 171 is caught on both sides of the locking groove 172 to push the sliding member 130, friction members ( Attenuation by 160). 2 to 4 illustrate only the shape in which the protrusion 171 is provided on the first support 110 and the locking groove 172 is provided on the first sliding plate 131, but the protrusion 171 is the first sliding plate ( 131 and the locking groove 172 is provided in the first support 110, their position can be interchanged.

5 and 6 show another embodiment of the displacement limiting device 270 to the vibration suppression apparatus 200 according to the second embodiment. In the second embodiment, the displacement limiting device 270 may include a plurality of protrusions 271 that protrude from the lower surface of the first support 210 and are slidably supported on the upper surface of the first sliding plate 231 of the sliding member 230. When the slip of the first support 210 and the first sliding plate 231 is greater than or equal to a predetermined range, the plurality of locking grooves 272 formed on the upper surface of the first sliding plate 231 may be engaged to be caught and restrained. Equipped. In the initial state, the protrusions 271 are set so as to enter the engaging grooves 272 respectively provided on both sides of the opposite side. When small vibration occurs, as shown in FIG. 5, the protrusion 271 behaves in a range not caught by the locking groove 272 so that the damping is performed by the viscoelastic member 240, and the vibration is relatively large. 6, when the movement of the protrusion 271 increases, as shown in FIG. 6, the protrusion 271 is caught by one of the locking grooves 272 on both sides thereof, thereby causing slippage of the sliding member 230 and rubbing. Attenuation by the member 260 can be implemented. In the second embodiment, the positions of the protrusion 271 and the locking groove 272 may be interchanged. A protrusion 271 may be provided in the first sliding plate 231, and a locking groove 272 may be provided in the first support 210.

7 to 11 show examples in which the vibration suppression apparatus 100 of the first embodiment is installed in a building structure. 7 is a form in which the rectangular frame 20 is installed in the structure 10, and the vibration suppression apparatus 100 is mounted on the lower center portion of the frame 20. In this case, the vibration isolator 100 has two lower support members 120 fixed to the frame 20 and an upper first support member 110 to two support members 30 extending from an upper corner of the frame 20. Can be supported by.

When an external force acts on the structure 10 by an earthquake or strong wind in the state in which the vibration isolator 100 is installed, the external force causes a relative slip displacement of the first support 110 and the second support 120 while the viscoelastic member It is transmitted to the 140 or the friction member 160. The transmitted external force (vibration) is attenuated by the viscoelastic member 140 or the friction member 160. In particular, when a small scale external force acts due to a small earthquake or strong wind, relative slip displacement of the first support 110 and the sliding member 130 occurs and is attenuated by the viscoelastic member 140. When a relatively large external force is applied to the structure 10 such as an earthquake with a large intensity (external force is applied beyond the attenuation range of the viscoelastic member), the relative slip displacement of the sliding member 130 and the plate 150 is generated. The external force is attenuated by the frictional strength of the friction member 160. Therefore, the structure 10 may be stably protected in response to various external forces.

8 illustrates an example in which the vibration isolator 100 is installed at the center of the frame 20 as another example of the vibration isolator 100. In this case, the vibration suppression apparatus 100 may be supported by the support members 30 extending from four corners of the frame 20. 9 and 10 are to install the vibration damping device 100 in the structure 10 without the frame 20, respectively. The installation method is similar to the example mentioned above. 11 is a form in which the vibration suppression apparatus 100 is installed in the middle portion of the auxiliary pillar 50 in a state in which the auxiliary pillar 50 is installed in the vertical direction in the structure 10.

As described above, the vibration suppression apparatus 100 of the present invention can be installed in various ways in the structure 10, and when installed in a building in the above manner, as shown in FIG. 1, the bolt 181 of the fastening unit 180 is plated. Since it is exposed to the outside of the side of the field 150, it is easy to manage or maintain. That is, since the manager can easily access the fastening unit 180 when the initial installation or after the management is necessary, the operation of adjusting the fastening force can be easily performed. Even when the viscoelastic member 140 or the friction member 160 is replaced, the plate 150 and the sliding member 130 can be easily separated by releasing the fastening unit 180 to easily perform the replacement operation. can do.

12 to 15 show the vibration suppression apparatus 300 according to the third embodiment. The vibration suppression apparatus 300 of the third embodiment includes a first support plate 310 connected to one side of the structure, a first sliding plate 320 extending vertically downward from a lower surface of the first support plate 310, and an upper end thereof. In order to limit the slip displacement of the second sliding plate 330 and the first sliding plate 320 and the second sliding plate 330 which are slidably contacted to the lower end of the first sliding plate 320 to the set range. Displacement limiting device 340 provided in the mutually contacting portion is provided.

In addition, the vibration damping device 300 covers the outer surfaces of both sides of the first sliding plate 320 and the second sliding plate 330 and has a length longer than the first and second sliding plates 320 and 330. 351 and lower second plate 352, both sides of the first sliding plate 320 and the viscoelastic members 360 interposed between the first plate 351 and both sides of the second sliding plate 330. The first and second plates (351, 352) and the friction member 370 interposed between the outer surface and the second plate 352, respectively coupled to the longitudinal end of each plate and connected to the other side of the structure Fastening unit 390 for pressing the second plate 352 toward the second sliding plate 330 to exert a damping force greater than that of the second and third support plates 381 and 382 and the viscoelastic member 360. It includes.

As shown in FIGS. 13 and 14, the displacement limiting device 340 includes a plurality of protrusions 341 protruding upward from an upper end of the second sliding plate 330, and first sliding so that the protrusions 341 enter. The lower surface of the plate 320 is formed with a locking groove 342 formed in a wider width than the protrusion 341. In the case of a small vibration, as shown in FIG. 14, the first sliding plate 320 is slipped within the range where both sides of the locking groove 342 does not catch the protrusion 341, thereby vibrating the viscoelastic member 360. When the vibration of the relatively large scale is generated, as shown in FIG. 15, both sides of the engaging groove 342 are caught by the protrusions 341 so as to cause slippage of the second sliding plate 330. It is intended to implement attenuation by the members 370. Herein, the protrusion 341 is provided on the second sliding plate 330 and the locking groove 342 is provided on the first sliding plate 320. However, the position of the protrusion 341 is the first sliding plate. It is provided in the 320 and the locking groove 342 may be changed to the form provided in the second sliding plate 330.

Engaging protrusions 351a and 352a coupled to the second and third support plates 381 and 382 are provided at both ends of the first and second plates 351 and 352, and the second support plate 381 and the second The third support plate 382 has a first coupling hole 384 to which the coupling protrusion 351a of the first plate 351 is coupled, and a second coupling protrusion 352a of the second cover plate 352 to the third support plate 382. Coupling holes 385a and 385b are provided.

In addition, the second coupling holes 385b may have long holes formed in the direction in which the friction member 370 is pressed so that at least one of the second cover plates 352 moves in a predetermined section in the direction of pressing the friction member 370. Include. That is, as shown in FIG. 13, one side of the second coupling holes 385b is provided in the form of a long hole. Of course, all of the second coupling holes 385a and 385b may be formed in the form of long holes. This allows the second cover plate 352 to move in the direction in which the friction member 370 is pressed to adjust the fastening force of the fastening unit 390.

The fastening unit 390 includes a plurality of bolts 391 passing through the second sliding plate 330, the friction members 370, and the second cover plates 352, and a plurality of nuts fastened to the respective bolts 391. 392 and a spring washer 393 installed on each bolt 391 to maintain a fastening force even when the friction member 370 is worn. In addition, the second sliding plate 330 includes a bolt coupling hole 331 formed in a sliding direction in a portion through which each of the bolts 391 penetrates so as to be slipped with respect to the second cover plates 352. The fastening unit 390 may adjust the frictional force by adjusting the fastening force of the bolt 391 through a torque wrench. The fastening force of the fastening unit 390 is adjusted so that the damping force of the vibration by the friction member 370 is greater than the damping force of the vibration by the viscoelastic member 360 to attenuate the vibration or external force of a relatively large scale.

The vibration damping device 300 has a sliding displacement between the first sliding plate 320 and the first plate 351 when a small vibration is applied to the structure due to a small earthquake or strong wind. At this time, vibration is attenuated by the viscoelastic member 360. In the case where a relatively large vibration such as an earthquake with a high intensity is applied (when an external force exceeding the attenuation range of the viscoelastic member is applied), the second sliding plate 330 is pushed by the displacement limiting device 340 and the second sliding plate ( A sliding displacement occurs between the 330 and the second cover plates 352. At this time, the vibration is attenuated by the frictional strength of the friction member 370. As a result, like the first embodiment, the third embodiment can stably protect the structure in response to various types of external forces.

16 to 18 show the vibration suppression apparatus 400 according to the fourth embodiment. As shown, the vibration suppression apparatus 400 of the fourth embodiment includes a first support plate 410 connected to one side of the structure, a first sliding plate 411 extending vertically from the bottom surface of the first support plate 410, and an upper end thereof. The second sliding plate 412 provided in contact with the lower end of the first sliding plate 411 and the third sliding plate 413 and the first sliding plate 411 installed in contact with the lower end of the second sliding plate 412. The first displacement limiting device 420 restricts the slip displacement of the two sliding plates 412 to the set range, and the second displacement limits the slip displacements of the second sliding plate 412 and the third sliding plate 413 to the set range. First, second, and third cover plates installed to cover the outer surfaces of both sides of the displacement limiting device 430 and the first to third sliding plates 411, 412, and 413, respectively, and having a longer length than the first to third sliding plates 411, 412, and 413. Fields 441, 442, and 443.

In addition, the vibration isolator 400 includes viscoelastic members 451 interposed between both outer surfaces of the first sliding plate 411 and the first covering plates 441, and both outer surfaces and the second covering plate of the second sliding plate 412. Second friction members 453 interposed between the outer surfaces of both sides of the first friction members 452 and the third sliding plate 413 and the third cover plates 443 interposed between the holes 442, and the first to the second friction members. Second and third support plates 461 and 462 coupled to the other end of each plate to support the third plates 441, 442 and 443, respectively, and having a damping force greater than the damping force by the viscoelastic member 451. Third sliding of the third plate 443 with a greater force than the first fastening unit 470 and the first fastening unit 470 which presses the second plate 442 toward the second sliding plate 412. It includes a second fastening unit 480 is pressed to the plate 413.

The first displacement limiting device 420 may include the first protrusion 421 protruding from the one of the first sliding plate 411 and the second sliding plate 412 to the opposite side, similar to the displacement limiting device of the third embodiment; The first projection groove 422 is formed to have a wider width than the first projection portion 421 on the other of the first sliding plate 411 and the second sliding plate 412 so that the first projection portion 421 enters. The second displacement limiting device 430 also includes a second protrusion 431 and a second locking groove 432 of this type. The width of the first locking groove 422 and the second locking groove 432 may be different depending on the design.

The first to third cover plates 441, 442 and 443 have coupling protrusions 441a, 442a and 443a coupled to the second and third support plates 461 and 462 at both ends thereof, and the second and third support plates 461 and 462. Is provided with coupling holes (464, 465, 466) to which the engaging projections (441a, 442a, 443a) of each plate. In addition, the coupling holes 465b and 466b of some of the coupling holes to which the coupling protrusions 442a and 443a of the second or third plate plates 442 and 443 are coupled may be at least one of the second or third plate plates 442 and 443. Is made of a long hole formed in the pressing direction so as to move in the direction of pressing the first or second friction member (452, 453).

The first fastening unit 470 includes a plurality of first bolts 471 passing through the second sliding plate 412, the first friction members 452, and the second cover plates 442, and each first bolt 471. A plurality of first nuts 472 fastened to the first nut 472 and first spring washers 473 installed at each of the first bolts 471 to maintain a fastening force even when the first friction member 452 is worn. The second fastening unit 480 also has a plurality of second bolts 481, a plurality of second nuts 482, and a plurality of second spring washers 483 having substantially the same shape as the first fastening unit 470. Include. In addition, the second sliding plate 412 and the third sliding plate 413 pass through the first bolt 471 or the second bolt 481 so as to be slipped with respect to the second or third covering plates 442 and 443. Each portion is provided with bolt coupling holes 412a and 413a elongated in the sliding direction, respectively.

In the vibration suppression apparatus 400 according to the fourth embodiment, when a small vibration is applied to a structure due to a small earthquake or strong wind, sliding motion is generated between the first sliding plate 411 and the first cover plates 441. Vibration is attenuated by 451. In the case where a relatively large vibration is applied by an earthquake of a relatively large magnitude (when an external force exceeding the attenuation range of the viscoelastic member is applied), slip of the second sliding plate 412 is performed by the first displacement limiting device 420. As a result, vibration is attenuated by the frictional strength of the first friction member 452. In addition, when an external force greater than the frictional force of the first friction member 452 is applied to the structure, the second sliding member 430 may be slipped by the second displacement limiting device 430, thereby causing the second friction member ( The vibration is attenuated by the frictional force of 453).

As described above, since the fourth embodiment can attenuate various types of external force from the small vibration to the relatively large vibration, the structure can be more stably protected.

[First Embodiment]
110: first support, 120: second support,
130: the sliding member, 140: viscoelastic member,
150: plate, 160: friction member,
170: displacement limiting device, 180: fastening unit.
Second Embodiment
210: a first support, 220: a second support,
230: sliding member, 240: viscoelastic member,
270: displacement limiting device.
Third Embodiment
310: first support plate, 320: first sliding plate,
330: the second sliding plate, 340: displacement limiting device,
351: first plate, 352: second plate,
360: viscoelastic member, 370: friction member,
381: second support plate, 382: third support plate,
390: fastening unit.
Fourth Embodiment
410: the first support plate, 411: the first sliding plate,
412: second sliding plate, 413: third sliding plate,
420: first displacement limiting device, 430: second displacement limiting device,
441: first plate, 442: second plate,
443: third plate, 451: viscoelastic member,
452: first friction member, 453: second friction member,
461: second support plate, 462: third support plate,
470: first fastening unit, 480: second fastening unit.

Claims (16)

A first support connected to one side of the structure;
A second support connected to the other side of the structure;
A sliding member slidably installed between the first support and the second support;
A viscoelastic member interposed between the first support and the sliding member for vibration damping;
A displacement limiting device provided on the first support and the sliding member to limit the slip displacement of the first support and the sliding member to a set range;
Cover plates respectively covering the outer surface of both sides of the sliding member and fixed to the second support;
Friction members interposed between the sliding member and the plate;
And a fastening unit configured to press and fasten the plate to the sliding member to have a damping force greater than that of the viscoelastic member. The method of claim 1,
The sliding member is disposed so as to face the first support body, the first sliding plate having the viscoelastic member coupled to the outer surface thereof, extending vertically from the first sliding plate toward the second support body, and the friction member on both outer surfaces thereof. Vibration damping device for a structure, characterized in that it comprises a second sliding plate that the plate is installed in the state. The method of claim 2,
The displacement limiting device includes a protrusion that protrudes from the one of the first support and the first sliding plate to the opposite side, and a width wider than the protrusion on the other of the first support and the first sliding plate so that the protrusion enters. Damping device for a structure comprising a locking groove formed in the. The method of claim 2,
The displacement limiting device may include a protrusion projecting from one of the first support and the first sliding plate so as to be slidably supported on the other side, and the slip when the slip of the first support and the first sliding plate is greater than or equal to a set range. And a catching groove formed in the other of the first support and the first sliding plate so as to be caught and restrained. The method of claim 2,
The fastening unit includes a plurality of bolts passing through the second sliding plate, the friction members, and the plate, a plurality of nuts fastened to the respective bolts, and each of the bolts to maintain a fastening force even when the friction member is worn. A spring washer installed on the bolt,
The second sliding plate is a vibration suppression apparatus for a structure, characterized in that it comprises a bolt coupling hole formed in the sliding direction in the portion through which the bolt penetrates. The method of claim 2,
The second support may include a fixed plate fixed to the structure, a support extending vertically from the fixed plate toward the second sliding plate to slidably support the second sliding plate, and both side surfaces of the support for coupling the plate. A plurality of coupling protrusions protruding from the
The plate is a vibration damping device for a structure, characterized in that it comprises a plurality of coupling holes coupled to correspond to the coupling projection. A first support plate connected to one side of the structure;
A first sliding plate extending vertically from the first supporting plate;
A second sliding plate whose end is slidably contacted with an end of the first sliding plate;
A displacement limiting device provided at a portion in which the first sliding plate and the second sliding plate are in contact with each other to limit slip displacement of the second sliding plate to a set range;
Cover plates installed to cover outer surfaces of both sides of the first sliding plate and the second sliding plate and having a length longer than that of the first and second sliding plates;
Viscoelastic members interposed between both outer surfaces of the first sliding plate and the plate for vibration damping;
Friction members interposed between both outer surfaces of the second sliding plate and the plate;
Second and third support plates respectively coupled to longitudinal ends of the plate plates and connected to the other side of the structure to support the plate plates;
And a fastening unit configured to press the fastening plate toward the second sliding plate so as to have a damping force greater than that of the viscoelastic member. The method of claim 7, wherein
The displacement limiting device may include a protrusion projecting from the one of the first sliding plate and the second sliding plate to the other side, and the other portion of the first sliding plate and the second sliding plate so that the protrusion enters. Vibration damping device for a structure comprising a locking groove formed in a wide width. The method of claim 7, wherein
The plate is installed on both sides of the outer side of the first sliding plate to support the viscoelastic member, the first plate with coupling protrusions coupled to the second and third support plate at both ends thereof, and both sides of the second sliding plate Pressurizing the friction members on an outer surface thereof and including second plate plates having coupling protrusions coupled to the second and third support plates at both ends thereof;
The second and third supporting plates include first coupling holes coupled to the coupling protrusions of the first plate, and second coupling holes coupled to the coupling protrusions of the second plate. . 10. The method of claim 9,
The fastening unit includes a plurality of bolts passing through the second sliding plate, the friction members, and the second cover plate, a plurality of nuts fastened to the respective bolts, and the fastening force even when the friction member is worn. A spring washer installed on each of the bolts,
The second sliding plate is a vibration suppression apparatus for a structure, characterized in that it comprises a bolt coupling hole formed in the sliding direction in the portion through which the bolt penetrates. 10. The method of claim 9,
The second coupling holes are structured vibration suppression apparatus comprising a long hole formed in the pressing direction of the friction member so that at least one of the second cover plate can move in the direction of pressing the friction member. A first support plate connected to one side of the structure;
A first sliding plate extending vertically from a lower surface of the first support plate;
A second sliding plate having an upper end installed in contact with a lower end of the first sliding plate, and a third sliding plate having an upper end installed in contact with a lower end of the second sliding plate;
A first displacement limiting device for limiting a slip displacement of the first sliding plate and the second sliding plate to a setting range and a second displacement limiting limiting slip displacement of the second sliding plate and the third sliding plate to a setting range An apparatus;
First, second and third cover plates installed to cover both outer surfaces of the first to third sliding plates, respectively, and having a length longer than that of the first to third sliding plates;
Viscoelastic members interposed between the outer surfaces of both sides of the first sliding plate and the first plate for vibration damping;
First friction members interposed between both outer surfaces of the second sliding plate and the second plate, and second friction members interposed between the outer surface of the third sliding plate and the third plate;
Second and third support plates respectively coupled to the longitudinal ends of the respective plate plates to support the first to third plate plates and connected to the other side of the structure;
The first plate unit and the third plate plate with a greater force than the first plate unit and the first plate unit for pressing the second plate plate toward the second sliding plate so as to have a damping force greater than the damping force by the viscoelastic member. And a second fastening unit for fastening by pressing toward the side. The method of claim 12,
The first displacement limiting device may include a first protrusion projecting from the one of the first sliding plate and the second sliding plate to the opposite side, and the first sliding plate and the second sliding plate to enter the first protrusion. A first catching groove formed in a wider width than the first protrusion in another one;
The second displacement limiting device includes a second protrusion projecting from the one of the second sliding plate and the third sliding plate to the opposite side, and the second sliding plate and the third sliding plate to enter the second protrusion. A vibration damping device for a structure comprising a second catching groove formed in a width wider than that of the second protrusion. The method of claim 12,
The first to third plate plates are provided with coupling protrusions coupled to the second and third support plates at both ends thereof.
The second and third support plate is a vibration suppression apparatus for a structure, characterized in that it comprises coupling holes coupled to the engaging projection of each of the plate. 15. The method of claim 14,
The first fastening unit includes a plurality of first bolts passing through the second sliding plate, the first friction members, and the second cover plate, a plurality of first nuts fastened to the first bolts, and the first 1 includes a first spring washer installed in each of the first bolt to maintain the fastening force even when the friction member is worn,
The second fastening unit includes a plurality of second bolts passing through the third sliding plate, the second friction members, and the third cover plate, a plurality of second nuts fastened to the second bolts, 2 includes a second spring washer installed in each of the second bolt to maintain the tightening force even when the friction member is worn,
The second sliding plate and the third sliding plate is a vibration damping device for a structure, characterized in that it comprises a bolt coupling hole formed in the sliding direction in each of the portion through which the first bolt or the second bolt penetrates. 15. The method of claim 14,
The coupling holes coupled to the coupling protrusions of the second or third plate plates are formed to be elongated in the pressing direction so that at least one of the second or third plate plates may move in the direction of pressing the first or second friction member. Vibration damping device for a structure comprising a.

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