KR102161201B1 - damping device - Google Patents

Abstract

The present invention relates to a new structural composite vibration damping device, which can be easily installed and damp all vibration in a side direction and a vertical direction. According to the present invention, the composite vibration damping device comprises: an upper support bracket (31) which is coupled to an upper end of a vibration damping plate (10) and of which an upper end portion is fixed to a slab (1) of an upper side; and a lower support bracket (32) which is coupled to a lower end of the vibration damping plate (10) and of which a lower end portion is fixed to a slab (1) of a lower side, thereby directly fixing the vibration damping plate (10) to the slabs (1) positioned on the upper and lower sides so that vibration damping performance can be improved.

Description

Composite vibration damping device {damping device}

The present invention relates to a complex vibration damping device having a new structure that is easy to install and attenuates both lateral and vertical vibrations.

In general, in a multi-storey building, a plurality of slabs are provided to be spaced apart from each other in a lateral direction, an outer wall is provided at a circumference of the slab, and an inner wall is provided at an upper portion of the slab.

And, in recent years, as the frequency of earthquake occurrence increases, the seismic design of buildings has been gradually strengthened.

However, in the case of an existing building, since it is not designed to be seismic or has a low-strength seismic design, various types of vibration suppression devices have been developed and used to reinforce the seismic performance of the structure installed in the same way.

1 to 3 show an example of such a vibration suppression device, wherein a plurality of slits 11 extending in the vertical direction and penetrating the front and rear surfaces thereof are formed to be laterally spaced apart from each other, and the vibration suppression plate It consists of a plurality of attenuation units 20 provided on the front and rear surfaces of (10).

The vibration suppression plate 10 is made of an elastic metal material, and is formed so that the fixing hole 12 and the guide hole 13 in the form of a long hole extending in the vertical direction pass through the front and rear surfaces.

In this case, the fixing hole 12 and the guide hole 13 are formed to be positioned on the upper and lower sides of the slit 11.

In addition, a plurality of upper fixing holes 14 and lower fixing holes 15 are formed at the upper and lower sides of the vibration isolation plate 10 so as to be spaced laterally from each other, so that the upper fixing holes 14 and the lower fixing holes 15 It is configured to fix the vibration isolation plate 10 to the building by using anchor bolts penetrating through the.

The attenuation unit 20 is configured in a plate shape extending in the vertical direction, is provided at the front and rear sides of the vibration suppression plate 10, and is side to the fixing hole 12 by a first fixing screw 23 penetrating the base end. Front and rear rotating plates 21 and 22 slidably coupled to the guide hole 13 by a second fixing screw 24 that is rotatably coupled in the direction and penetrating the front end, and the front and rear rotating plates 21 and 22 ) And a friction pad 25 fitted to the outside of the first fixing screw 23 so as to be positioned between the vibration isolation plate 10.

The front and rear rotating plates 21 and 22 are configured with a wide base end and a narrow front end.

The friction pad 25 has a through hole 25a through which the first fixing screw 23 passes.

At this time, the attenuation units 20 are composed of two and are provided on both sides of the vibration damping plate 10.

In addition, the attenuation unit 20 on one side is provided so that the base end of the front and rear rotating plates 21 and 22 is located at the lower side, and the attenuation unit 20 on the other side has the base end of the front and rear rotating plates 21 and 22 on the upper side. It is provided to be located in.

Therefore, when the vibration isolating plate 10 is fixed to the wall of a building using the anchor bolts, when an earthquake occurs and the upper and lower ends of the wall flow in different directions, the upper and lower ends of the vibration isolating plate 10 are twisted to each other. It flows in the other direction, and accordingly, the front and rear rotating plates 21 and 22 of the attenuation unit 20 are rotated in the lateral direction, and a damping force is generated between the front and rear rotating plates 21 and 22 and the friction member. It is configured to attenuate the torsion of.

However, when installing such a vibration suppression device, a new vibration suppression wall must be installed indoors, and the vibration suppression device must be fixed to the installed vibration suppression wall, resulting in a problem that requires a lot of cost and lengthens construction time.

In particular, when the vibration suppression device is installed in this way, the vibration suppression device attenuates the vibration of the slab through the wall, and thus, it is difficult to effectively transmit the damping force to the building.

In addition, such a vibration suppression device can attenuate the vibration in the lateral direction, but there is a problem in that it cannot attenuate the vibration in the vertical direction.

Therefore, there is a need for a new method to solve this problem.

Registered Patent No. 10-1842593,

The present invention has been made to solve the above problems, and an object of the present invention is to provide a composite vibration damping device having a new structure capable of attenuating both lateral and vertical vibrations while being easy to install.

The present invention for achieving the above object is, a plurality of slits 11 extending in the vertical direction and penetrating through the front and rear surfaces are formed to be spaced apart from each other in the lateral direction, and the front and rear of the vibration isolation plate 10 Includes a plurality of attenuation units 20 provided on the surface, and the vibration isolation plate 10 has a fixing hole 12 and a guide hole 13 extending in the vertical direction so that it is located on the upper and lower sides of the slit 11. Is formed, the attenuation unit 20 is formed in a plate shape extending in the vertical direction, is provided on the front and rear sides of the vibration isolation plate 10, and is provided with the fixing hole 12 by a first fixing screw 23 penetrating the base end. ), the front and rear rotating plates 21 and 22 slidably coupled to the guide hole 13 by a second fixing screw 24 penetrating the front end, and the front and rear rotating plates ( It includes a friction pad 25 fitted to the outside of the first fixing screw 23 so as to be positioned between the 21 and 22 and the vibration suppression plate 10, and has a plurality of slabs 1 spaced upward and downward. In the vibration suppression device installed in a multi-storey building, the upper support bracket 31 is coupled to the upper end of the vibration isolation plate 10 and the upper end is fixed to the upper slab 1, and It is coupled and the lower part further includes a lower support bracket 32 fixed to the lower slab 1, and a plurality of upper fixing holes 14 and lower fixing holes 15 are mutually formed at the upper and lower ends of the vibration suppression plate 10. It is formed to be spaced apart in the lateral direction, and at the lower end of the upper support bracket 31 and the upper end of the lower support bracket 32, upper and lower coupling holes 31b corresponding to the upper fixing hole 14 and the lower fixing hole 15, 32b) is formed to extend in the vertical direction, the upper and lower fixing screws 33, which penetrate the upper fixing hole 14 and the upper coupling hole 31b, and the lower fixing hole 15 and the lower coupling hole 32b. 34), the upper and lower support brackets 31 and 32 are fixed to the upper and lower ends of the vibration isolation plate 10, and the upper and lower ends and upper and lower support brackets 31 and 32 of the vibration isolation plate 10 Between the upper and lower fixing screws (33,34) A composite vibration damping device is provided, characterized in that a first auxiliary friction pad 35 coupled to the outside is provided.

According to another feature of the present invention, the slide block 36 is coupled to the guide hole 13 so as to be liftable and has a communication hole 36a through which the second fixing screw 24 passes, and the slide block ( The composite characterized in that it further comprises a second auxiliary friction pad (37) that is fitted to the outside of the second fixing screw (24) so as to be positioned between the front and rear surfaces of the front and rear rotating plates (21, 22) A vibration damping device is provided.

According to another feature of the present invention, a pressure sensor 41 that is provided on the vibration isolation plate 10 and measures the pressure at which the friction pad 25 is in close contact with the vibration isolation plate 10, and the pressure sensor 41 ) And further comprises a control means 42 configured to enable data communication with the manager's smart phone 43, wherein the control means 42 receives the signal from the pressure sensor 41 and the friction pad A composite vibration damping device is provided, characterized in that when the pressure in close contact with the vibration damping plate (25) falls below a preset pressure, data notifying the manager's smartphone (43) is transmitted.

According to another feature of the present invention, the upper and lower guide guides extending laterally from the lower one side of the upper support bracket 31 and the upper one side of the lower support bracket 32 and having rack gear rows 51a and 52a formed on the adjacent surface Rails 51 and 52 and an upper vibrating bar 53 configured in a bar shape extending in the vertical direction and having a lower end rotatably coupled to the front of the upper support bracket 31 in the vertical direction, and extending in the vertical direction The lower vibration bar 54 is composed of a bar shape and the upper end is pivotably coupled to the front of the lower support bracket 32 in a lateral direction, and the upper and lower additional rails 51 and 52 are slidable in the lateral direction. The combined support 55 and a pinion gear 56 rotatably coupled to the support 55 and having a circumferential surface engaged with the rack gear rows 51a and 52a of the upper and lower side rails 51 and 52, An electric cylinder device 57 which is provided to extend laterally to the support 55 and has a piston rod 57a that slides laterally according to the operation of the driving motor, and is operated and controlled by the control means 42, and , When both ends are hinged to the piston rod (57a) and the upper and lower vibration bars (53, 54), respectively, when the piston rod (57a) slides in the lateral direction, the connecting rod to rotate the upper and lower vibration bars (53, 54) ( 58), and a vibration detection sensor 59 that is provided on the support 55 and measures the amplitude and frequency at which the support 55 vibrates when the support 55 vibrates in the lateral direction, and the control means ( 42) responds to the amplitude and frequency of the support 55 measured by the vibration detection sensor 59 when it is detected that the support 55 vibrates in the lateral direction by receiving the signal from the vibration detection sensor 59 There is provided a composite vibration damping device, characterized in that the electric cylinder device 57 is expanded and contracted to rotate the upper and lower vibration bars 53 and 54 in the lateral direction.

The composite vibration damping device according to the present invention is coupled to the upper end of the vibration damping plate 10 and the upper end is coupled to the upper support bracket 31 fixed to the upper slab 1, and the lower end of the vibration damping plate 10. The lower part is provided with a lower support bracket 32 fixed to the lower slab 1, and the vibration isolation plate 10 is directly fixed to the upper and lower slabs 1, thereby improving vibration isolation performance.

1 is a front view showing a conventional vibration suppression device,
2 is a front view showing a vibration suppression plate of a conventional vibration suppression device;
3 is a side cross-sectional view showing a cross section taken along line AA of FIG. 1;
4 is a front view showing a vibration suppression device according to the present invention,
5 is a side cross-sectional view of a vibration suppression device according to the present invention,
6 and 7 are side cross-sectional views showing an enlarged main part of the vibration suppression device according to the present invention;
8 is a front view showing a guide ball, a slide block, and a second auxiliary friction pad of the vibration suppression device according to the present invention;
9 is a circuit configuration diagram of a vibration suppression device according to the present invention,
10 is a front view showing a second embodiment of a vibration suppression device according to the present invention;
11 is a front view showing a coupling state of the upper and lower additional guide rails and the pinion gear of the second embodiment of the vibration suppression device according to the present invention;
12 is a side view showing a second embodiment of a vibration suppression device according to the present invention;
13 to 16 are reference diagrams for explaining the operation of the second embodiment of the vibration suppression device according to the present invention.

Hereinafter, the present invention will be described in detail on the basis of the accompanying drawings.

4 to 9 show a composite vibration damping device according to the present invention, wherein a plurality of slits 11 extending in the vertical direction and penetrating through the front and rear surfaces are formed to be spaced laterally from each other; A plurality of damping units 20 provided on the front and rear surfaces of the vibration suppression plate 10 are the same as those of a conventional vibration suppression device.

In this case, in the vibration isolation plate 10, a fixing hole 12 and a guide hole 13 extending in the vertical direction are formed to be positioned at the upper and lower sides of the slit 11.

In addition, the attenuation unit 20 is formed in a plate shape extending in the vertical direction, is provided on the front and rear sides of the vibration isolation plate 10, and is provided with the fixing hole 12 by a first fixing screw 23 penetrating the base end. The front and rear rotating plates 21 and 22 slidably coupled to the guide hole 13 by a second fixing screw 24 penetrating through the front end and the front and rear rotating plates 21 The friction pad 25 is fitted to the outside of the first fixing screw 23 so as to be positioned between the ,22) and the vibration isolation plate 10.

On the other hand, such a composite vibration damping device is installed in a multi-story building having a plurality of slabs 1 spaced up and down.

And, according to the present invention, upper and lower support brackets 31 fixed to the upper slab 1 and lower support brackets 32 fixed to the lower slab 1 are respectively coupled to the upper and lower ends of the vibration isolation plate 10 do.

The upper support bracket 31 and the lower support bracket 32 are formed by welding a metal bar having high strength in a square shape, and at an adjacent end, fixing portions 31a and 32a that are coupled to the upper and lower ends of the vibration isolation plate 10 ) Is formed.

In addition, a plurality of upper fixing holes 14 and lower fixing holes 15 are formed at the upper and lower ends of the vibration suppression plate 10 so as to be laterally spaced apart from each other, and the upper fixing holes ( 14) and the upper and lower coupling holes 31b and 32b corresponding to the lower fixing holes 15 are formed to extend in the vertical direction, the upper fixing holes 14 and the upper coupling holes 31b, and the lower fixing holes ( The upper and lower support brackets 31 and 32 are fixed to the upper and lower ends of the vibration isolation plate 10 by upper and lower fixing screws 33 and 34 penetrating through the 15 and lower coupling holes 32b. .

At this time, as shown in FIG. 6, between the upper and lower ends of the vibration isolation plate 10 and the upper and lower support brackets 31 and 32, a first auxiliary friction pad coupled to the outside of the upper and lower fixing screws 33 and 34 (35) is provided.

The first auxiliary friction pad 35 is made of the same material as the friction pad 25 described above, and a through hole 35a through which the upper and lower fixing screws 33 and 34 penetrate is formed in the central portion.

Therefore, when an earthquake vibrating in the vertical direction occurs and the slabs 1 on the upper and lower sides vibrate in different directions, the upper and lower support brackets 31 and 32 slide in the vertical direction, and the first auxiliary friction pad ( 35), a damping force is generated between the upper and lower support brackets 31 and 32 and the vibration isolation plate 10.

In addition, as shown in FIG. 7, a slide block 36 having a communication hole 36a through which the second fixing screw 24 penetrates is formed in the guide hole 13 so as to be liftably coupled, and the slide block A second auxiliary friction pad 37 that is fitted to the outside of the second fixing screw 24 is provided between the front and rear surfaces of the front and rear pivot plates 21 and 22.

The slide block 36 is configured to have the same thickness as the guide hole 13 in the front-rear direction, and is coupled to the guide hole 13 so that it is possible to move up and down, but not rotate.

To this end, as shown in Figure 8, the guide hole 13 is configured in a rectangular hole shape extending in the vertical direction so that both sides are vertical, and the slide block 36 has a width in the lateral direction of the guide It is composed of a square equal to the width of the ball (13).

The second auxiliary friction pad 37 is formed of a square having the same area as the slide block 36, and is adhesively fixed to the front and rear surfaces of the slide block 36, and the second fixing screw 24 at the center thereof Through-holes (37a) through which is formed.

Therefore, as the upper and lower slabs 1 flow in different directions, the upper and lower support brackets 31 and 32 flow in different directions, and accordingly, the front and rear rotating plates 21 of the attenuation unit 20 When ,22) is rotated laterally around the base end, additional friction is generated at the front ends of the second auxiliary friction pad 37 and the front and rear rotating plates 21 and 22, so that the vibration damping performance of the damping unit 20 This is improved.

In addition, as shown in FIGS. 7 and 9, the friction pad 25 on the vibration isolation plate 10 is a pressure sensor 41 that measures the pressure in close contact with the vibration isolation plate 10 and the slide block 36. ) Is provided, and a control means 42 configured to enable data communication with the manager's smartphone 43 is connected to the pressure sensor 41.

The pressure sensor 41 is provided at a portion of the vibration suppression plate 10 to which the friction pad 25 is in close contact, and the friction pad 25 is connected to the vibration suppression plate 10 by the front and rear rotating plates 21 and 22. By measuring the pressure in close contact with the friction pad 25, the friction force generated by the friction pad 25 is indirectly measured.

That is, the friction pad 25 is provided between the vibration isolation plate 10 and the base end of the front and rear rotating plates 21 and 22, and when the first fixing screw 23 is tightened, the front and rear rotating plates 21 and 22 The friction pad 25 is pressed so that the friction pad 25 is strongly in close contact with the vibration isolation plate 10.

However, when an earthquake occurs and the front and rear rotating plates 21 and 22 rotate in the lateral direction, the friction pad 25 is gradually worn, and accordingly, the friction pad 25 is in close contact with the vibration isolation plate 10. When the pressure is lowered and the pressure of the friction pad 25 in close contact with the vibration isolation plate 10 is lowered below a predetermined level, the friction pad 25 does not exhibit sufficient vibration isolation performance.

At this time, the control means 42 measures the pressure at which the friction pad 25 is in close contact with the vibration isolation plate 10, so that the friction force generated by the friction pad 25, that is, the vibration isolation performance, can be indirectly measured. There will be.

The control means 42 receives the signal from the pressure sensor 41, and when the pressure of the friction pad 25 in close contact with the vibration isolation plate 10 and the slide block 36 falls below a preset pressure, It is configured to transmit data notifying this to the smartphone 43.

Therefore, when the frictional force of the friction pad 25 is lowered to a predetermined level or less, the manager checks it in real time and tightens the first fixing screw 23 more strongly or replaces the friction pad 25 with a new one. By replacing, it is possible to maintain and maintain the frictional force of the friction pad 25 continuously.

The composite vibration damping device configured as described above is coupled to the upper end of the vibration damping plate 10, and the upper end is coupled to the upper support bracket 31 fixed to the upper slab 1, and the lower end of the vibration damping plate 10 The lower support bracket 32 fixed to the lower slab 1 is provided, and the vibration isolation plate 10 is directly fixed to the upper and lower slabs 1, thereby improving vibration isolation performance.

In addition, a plurality of upper fixing holes 14 and lower fixing holes 15 are formed at the upper and lower ends of the vibration isolation plate 10 so as to be laterally spaced apart from each other, and the lower end and the lower support bracket of the upper support bracket 31 ( The upper and lower fixing holes 31b and 32b corresponding to the upper fixing hole 14 and the lower fixing hole 15 are formed to extend in the vertical direction at the upper end of the upper fixing hole 14 and the upper fixing hole 14 (31b), and the upper support bracket 31 and the lower end of the vibration isolation plate 10 by upper and lower fixing screws 33 and 34 penetrating the lower fixing hole 15 and the lower coupling hole 32b. The support bracket 32 is configured to be fixed, and the first auxiliary friction pad is coupled to the outside of the upper and lower fixing screws 33 and 34 between the upper and lower ends of the vibration isolation plate 10 and the upper and lower support brackets 31 and 32 Since (35) is provided, there is an advantage of exhibiting a damping force even when the slab 1 is vibrated in the vertical direction.

In addition, the slide block 36 is coupled to the guide hole 13 so as to be able to move up and down and has a communication hole 36a through which the second fixing screw 24 passes, and the front and rear surfaces of the slide block 36 Since a second auxiliary friction pad 37 fitted to the outside of the second fixing screw 24 so as to be positioned between the rotating plates 21 and 22 is further provided, the base end of the front and rear rotating plates 21 and 22 In addition, since attenuation force is generated at the front ends of the front and rear pivot plates 21 and 22, there is an advantage of more effectively attenuating vibrations caused by earthquakes.

In addition, a pressure sensor 41 that is provided on the vibration isolation plate 10 and measures the pressure at which the friction pad 25 is in close contact with the vibration isolation plate 10, and the manager receives a signal from the pressure sensor 41 A control means 42 configured to enable data communication with the smartphone 43 of the above is further provided, and the control means 42 receives a signal from the pressure sensor 41 so that the friction pad 25 becomes a vibration damping plate ( 10) When the pressure in close contact with the pressure drops below a preset pressure, it is configured to transmit data notifying it to the manager's smartphone 43, so that the friction pad 25 wears out due to frequent earthquakes. If the attenuation power caused by this decreases, there is an advantage that the manager can check it in real time and quickly maintain it.

10 to 16 show a second embodiment according to the present invention, which extends laterally from a lower side of the upper support bracket 31 and an upper end of the lower support bracket 32, and a rack gear on the adjacent surface. Upper and lower side rails 51 and 52 in which rows 51a and 52a are formed, and a bar-shaped extending in the vertical direction, and the lower part is coupled to the front side of the upper support bracket 31 so as to rotate in the lateral direction. A bar 53 and a lower vibrating bar 54 configured in a bar shape extending in the vertical direction and having an upper end rotatably coupled to the front of the lower support bracket 32 in a lateral direction, and the upper and lower additional guide rails 51 The support 55 is slidably coupled to the lateral direction to 52, and the rack gear rows 51a and 52a of the upper and lower additional guide rails 51 and 52 are rotatably coupled to the support 55 and have a circumferential surface thereof. A pinion gear 56 engaged with the supporter 55 and a piston rod 57a which is provided to extend laterally to the support 55 and which slides in the lateral direction according to the operation of the driving motor are provided, and by the control means 42 When the hinged piston rod 57a slides in the lateral direction to the electric cylinder device 57 that is operated and controlled at both ends of the piston rod 57a and the upper and lower vibration bars 53 and 54, respectively, the upper and lower vibration bars 53 , A connecting rod 58 for rotating the 54, and a vibration detection sensor 59 that is provided on the support 55 and measures the amplitude and frequency at which the support 55 vibrates when the support 55 vibrates in the lateral direction. ) Is further provided.

The upper and lower additional rails 51 and 52 are provided to extend to the right from the lower end of the upper support bracket 31 and the upper end of the lower support bracket 32.

The upper vibration bar 53 is provided so that the upper end of the upper support bracket 31 rotates in the lateral direction by a rotation shaft 53a provided to be close to the lower end.

The lower vibration bar 54 is provided so that the lower end of the lower support bracket 31 rotates in the lateral direction by a rotation shaft 54a provided to be close to the upper end.

At this time, weights 53b and 54b are provided at an upper end of the upper vibration bar 53 and a lower end of the lower vibration bar 54.

The support 55 is configured such that the slide guide 55a provided on the rear side is slidably coupled to the upper and lower side guide rails 51 and 52 so that the upper and lower parts slide in the lateral direction along the guide rails 51 and 52. In the central portion of the rear side, a rotation shaft 55b extending rearward is provided.

The pinion gear 56 is coupled to the rotation shaft 55b, and the upper and lower circumferential surfaces are meshed with the rack gear rows 51a and 52a formed on the upper and lower side rails 51 and 52.

Therefore, in a state in which the slabs 1 located on the upper and lower sides are vibrated in opposite directions to each other, as shown in FIG. 13, the upper and lower parts are vibrated in opposite directions to the guide rails 51 and 52, and accordingly, the pinion gear ( 56) is rotated so that the support 55 does not move in the lateral direction.

Conversely, when the slabs 1 located on the upper and lower sides are vibrated in the same direction, as shown in FIG. 14, the upper and lower additional guide rails 51 and 52 are vibrated in the same direction together, and accordingly, the pinion gear (56) is not rotated and the upper and lower parts move in the lateral direction together with the guide rails (51, 52).

The electric cylinder device 57 is provided on the front surface of the support 55 so that the piston rod 57a is located on the left side, and a support part for coupling the connecting rod 58 to the front end of the piston rod 57a ( 57b) is formed.

The connecting rod 58 is composed of two, respectively, the lower end of the upper pivoting bar 53 and the support portion 57b of the piston rod 57a, and the upper end of the lower pivoting bar 54 and the piston rod 57a ) Is hinged to the support portion 57b.

In addition, when the control means 42 receives a signal from the vibration detection sensor 59 and detects that the support 55 is vibrated in the lateral direction, the control means 42 is sent to the vibration detection sensor 59. In order to correspond to the amplitude and frequency of the support 55 measured by the electric cylinder device 57, the upper and lower vibration bars 53 and 54 are rotated in the direction in which the support 55 is vibrated. Attenuate the phenomenon of vibration.

That is, when a building vibrates due to an earthquake, a phenomenon in which the slabs 1 located on the upper and lower sides vibrate in the same direction and the phenomenon that the slabs 1 located on the upper and lower sides vibrate in opposite directions occur simultaneously.

At this time, the support 55 is slidably coupled to the upper and lower side rails 51 and 52 in a lateral direction, and the circumferential surface of the rack gear rows 51a and 52a formed on the upper and lower side rails 51 and 52 Since the engaged pinion gear 56 is rotatably provided, as shown in FIG. 13, when the upper and lower slabs 1 vibrate in different directions, the support 55 does not vibrate in the lateral direction, As shown in Fig. 14, since the support 55 vibrates in the lateral direction only when the upper and lower slabs 1 slide in the same direction, the vibration detection sensor 59 is the frequency at which the entire building is vibrated in the lateral direction. And the amplitude can be detected.

In addition, when the electric cylinder device 57 is expanded and contracted so that the upper and lower vibration bars 53 and 54 rotate in the direction in which the support 55 is vibrated, that is, when the support 55 is vibrated to the right, FIG. As described above, when the electric cylinder device 57 is elongated to rotate the upper and lower vibration bars 53 and 54 to the right, and the support 55 is vibrated to the left, as shown in FIG. 16, the electric cylinder device When the upper and lower vibration bars 53 and 54 are rotated to the left by reducing 57, the repulsive force generated by the rotation of the upper and lower vibration bars 53 and 54 is reduced through the upper and lower support brackets 31 and 32. It is transmitted to the slab (1) to attenuate the vibration of the entire building.

Unlike the above-described first embodiment, in which a damping force is generated only when the upper and lower slabs 1 vibrate in opposite directions, the composite vibration damping device configured as described above can cause the upper and lower slabs 1 to vibrate in different directions. When the vibration is attenuated using the attenuation unit 20, when the upper and lower slabs 1 vibrate in the same direction, the upper and lower pivoting bars 53 and 54 are rotated to generate a damping force. There is an advantage of being able to respond more effectively to vibration.

10. Damping plate 20. Damping unit
31,32. Upper and lower support bracket 35. First auxiliary friction pad
36. Slide block 37. Second auxiliary friction pad
41. Pressure sensor 42. Control means

Claims (4)

A vibration isolation plate 10 extending in the vertical direction and formed so that a plurality of slits 11 penetrating the front and rear surfaces are spaced laterally from each other,
Includes a plurality of attenuation units 20 provided on the front and rear surfaces of the vibration suppression plate 10,
In the vibration suppression plate 10, a fixing hole 12 and a guide hole 13 extending in the vertical direction are formed to be positioned at the upper and lower sides of the slit 11,
The attenuation unit 20 is configured in a plate shape extending in the vertical direction, is provided at the front and rear sides of the vibration suppression plate 10, and is side to the fixing hole 12 by a first fixing screw 23 penetrating the base end. Front and rear pivoting plates 21 and 22 slidably coupled to the guide hole 13 by a second fixing screw 24 that is rotatably coupled in a direction and passes through the tip,
It includes a friction pad 25 fitted to the outside of the first fixing screw 23 so as to be positioned between the front and rear rotating plates 21 and 22 and the vibration suppression plate 10,
In the vibration suppression device installed in a multi-story building having a plurality of slabs (1) spaced up and down,
An upper support bracket 31 coupled to the upper end of the vibration isolation plate 10 and fixed to the upper slab 1,
A lower support bracket 32 coupled to the lower end of the vibration isolation plate 10 and fixed to the lower slab 1 at the lower end thereof,
A plurality of upper fixing holes 14 and lower fixing holes 15 are formed at the upper and lower ends of the vibration suppression plate 10 to be laterally spaced apart from each other,
At the lower end of the upper support bracket 31 and the upper end of the lower support bracket 32, upper and lower coupling holes 31b and 32b corresponding to the upper fixing hole 14 and the lower fixing hole 15 extend in the vertical direction. Is formed, the upper and lower fixing screws (33, 34) passing through the upper fixing hole (14) and the upper coupling hole (31b), and the lower fixing hole (15) and the lower coupling hole (32b). 10) is configured to be fixed to the upper and lower support brackets 31 and 32,
A first auxiliary friction pad 35 coupled to the outside of the upper and lower fixing screws 33 and 34 is provided between the upper and lower ends of the vibration isolation plate 10 and the upper and lower support brackets 31 and 32,
A slide block 36 coupled to the guide hole 13 so as to be able to move up and down and having a communication hole 36a through which the second fixing screw 24 passes,
Further comprising a second auxiliary friction pad 37 fitted to the outside of the second fixing screw 24 so as to be positioned between the front and rear surfaces of the slide block 36 and the front and rear rotating plates 21 and 22 Composite vibration damping device characterized by.
delete The method of claim 1,
A pressure sensor 41 provided on the vibration damping plate 10 and measuring a pressure at which the friction pad 25 is in close contact with the vibration damping plate 10,
Further comprising a control means 42 configured to receive a signal from the pressure sensor 41 and enable data communication with the manager's smartphone 43,
The control means 42 receives the signal from the pressure sensor 41 and when the pressure at which the friction pad 25 is in close contact with the vibration isolation plate 10 falls below a preset pressure, the manager's smartphone 43 Complex vibration damping device, characterized in that to transmit data notifying this.
The method of claim 3,
Upper and lower additional rails 51 and 52 extending laterally from one lower side of the upper support bracket 31 and one upper end side of the lower support bracket 32 and having rack gear rows 51a and 52a formed on the adjacent surface,
An upper vibration bar 53 configured in a bar shape extending in the vertical direction and having a lower end rotatably coupled to the front of the upper support bracket 31 in a lateral direction,
A lower vibrating bar 54 configured in a bar shape extending in the vertical direction and having an upper end rotatably coupled to the front of the lower support bracket 32 in a lateral direction,
A support 55 that is slidably coupled to the upper and lower side rails 51 and 52 in a lateral direction,
A pinion gear 56 rotatably coupled to the support 55 and having a circumferential surface engaged with the rack gear rows 51a and 52a of the upper and lower side rails 51 and 52;
An electric cylinder device 57 which is provided to extend laterally to the support 55 and has a piston rod 57a that slides laterally according to the operation of the driving motor, and is operated and controlled by the control means 42, and ,
When both ends are hinged to the piston rod (57a) and the upper and lower vibration bars (53, 54), respectively, when the piston rod (57a) slides in the lateral direction, the connecting rod (58) to rotate the upper and lower vibration bars (53, 54) )Wow,
It is provided on the support 55 and further comprises a vibration detection sensor 59 for measuring the amplitude and frequency of vibration of the support 55 when the support 55 vibrates in the lateral direction,
When the control means 42 receives a signal from the vibration detection sensor 59 and detects that the support 55 is vibrated in the lateral direction, the amplitude of the support 55 measured by the vibration detection sensor 59 The combined vibration damping device, characterized in that the electric cylinder device (57) is stretched and contracted to correspond to the frequency and the upper and lower vibration bars (53, 54) are rotated laterally.

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