JP3738639B2 - Vibration control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to a vibration damping device that suppresses vibrations (vibrations) of structures such as buildings and warehouse racks caused by earthquakes and winds. In particular, an additional mass body that is tuned to a natural period of a structure is supported using laminated rubber. Related to the vibration damping device.
[0002]
[Prior art]
In general, a tuned mass damper (hereinafter abbreviated as TMD) known as a vibration damping device includes an additional mass body that can move relative to a structure to be damped. The vibration energy of the structure is reduced by tuning the vibration period to the natural period of the structure and giving the additional mass body appropriate damping.
[0003]
In a conventional vibration damping device with an elastic support system in which an additional mass body is supported by laminated rubber, the additional mass body is provided by a multi-stage laminated rubber bearing made of laminated rubber that is distributed on the rooftop or floor surface of a structure and polymerized vertically. Is supported. The additional mass body oscillates at a vibration period synchronized with the natural period of the structure. The natural period is mainly determined by the number of stacked stages of the multi-layer laminated rubber support that supports the additional mass body. Therefore, this TMD can change the natural frequency by adjusting the number of stacked stages of the multistage laminated rubber bearing.
[0004]
[Problems to be solved by the invention]
By the way, the natural period of a structure is influenced by the shape and internal structure of each structure, and generally varies depending on the swinging direction.
For example, when a structure having a substantially rectangular shape with a substantially uniform rigidity inside is oscillated, even if the same external force is input, the oscillating in the short direction is longer in the longitudinal direction. When the rocking is longer and longer than the rocking, and the rocking is performed in the longitudinal direction, the period is short and the rocking is small.
Even if the planar shape is a substantially square structure, if there is a bias in the structure, such as a large space inside a specific location, the structure will oscillate depending on the direction of the input external force. The period will be different.
[0005]
However, in the conventional vibration damping device of the elastic support system using the additional mass body and the laminated rubber, the additional mass body supported by the laminated rubber oscillates in the same period in any direction in the horizontal plane. That is, the swing that can be damped in synchronization with the vibration damping device is limited to a specific frequency, and therefore, there is a problem that only vibration in a specific direction can be damped.
[0006]
Therefore, the present invention has been made in view of such a conventional problem, and an object of the present invention is to provide an inexpensive vibration damping device capable of attenuating vibrations having different vibration periods generated in a structure.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, a vibration damping device according to claim 1 of the present invention includes an additional mass body and a plurality of elastically deformable laminated rubber units that support the additional mass body on a structure. An elastic deformation restraining means for restraining elastic deformation of the laminated rubber unit in a predetermined direction is provided in a part of the laminated rubber unit. It is characterized by that.
[0008]
According to the vibration damping device of the present invention, the elastic deformation restraining means for constraining the elastic deformation of the laminated rubber unit in a predetermined direction is provided in a part of the laminated rubber unit of the supporting means. It is possible to restrict elastic deformation of the laminated rubber unit in a predetermined direction and allow elastic deformation in an unregulated direction. Therefore, the support means as a whole can have high rigidity in the direction in which the elastic deformation is restricted by the elastic deformation restraining means, and the natural vibration period of the additional mass body can be shortened. As a result, the additional mass body can be swung in a short cycle with respect to the direction in which the elastic deformation is restricted, and can be swung in a long cycle with respect to the direction in which the elastic deformation is not restricted. In the device, different natural vibration periods are obtained depending on directions, and oscillations with different vibration periods can be attenuated.
[0009]
Further, by adjusting the number of laminated rubber unit for restricting the elastic deformation by the elastic deformation restriction means, so that the vibration period of the vibration damping device the vibration period of the structure to tune easily the vibration period of the vibration damping device Can be changed.
[0010]
The vibration damping device according to claim 2 of the present invention is the vibration damping device according to claim 1, wherein the elastic deformation restraining means is configured so that the structure receives a horizontal external force and is orthogonal to the horizontal direction. when it swung to any two directions, allowing the swinging of the orthogonal direction, characterized by a regulating child swing in the other direction orthogonal.
[0011]
According to the vibration damping device of the present invention, when the vibration damping device is installed on the structure, a part of the support means of the vibration damping device is laminated in two directions perpendicular to the horizontal direction in which the structure swings. The direction in which the elastic deformation of the rubber unit is not regulated and the direction in which the structure swings in a long cycle coincide with each other, and the elastic deformation of the laminated rubber unit as a part of the support means of the vibration damping device is regulated. By matching the direction of oscillation with a short period, it is possible to attenuate the input vibration efficiently in accordance with the vibration period of the structure.
[0012]
Further, a vibration damping device according to a third aspect of the present invention is the vibration damping device according to the second aspect, wherein the elastic deformation restraining means includes a rail provided along a direction allowing swinging, It is a slide mechanism comprising a slider provided so as to be slidable along the rail .
[0013]
According to the vibration damping device of the present invention, the elastic deformation restraining means is constituted by the slide mechanism including the rail and the slider provided so as to be slidable along the rail, so that the structure can be simplified and attached, Removal can be facilitated, and the natural vibration period of the damping device can be easily synchronized with the vibration period of the structure.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 to 3 show an embodiment in which the vibration damping device of the present invention is applied to a hybrid vibration damping device, FIG. 1 is a front view of the vibration damping device, and FIG. 2 is a plan view of FIG. 3 is a side view of the elastic deformation restraining means applied to the present invention.
[0016]
The hybrid vibration damping device 30 of the present embodiment is provided on the roof of the building 1 to be vibration-damped, and includes passive vibration damping means 10 that constitutes the vibration damping device of the present invention that elastically supports the passive mass 12, and an active mass. Reference numeral 38 denotes an active vibration damping means 20 provided so as to be reciprocally movable.
[0017]
The passive vibration damping means 10 includes a passive mass 12 that is formed in a rectangular parallelepiped shape and has a predetermined mass and forms an additional mass, and a pair of support means 16 that supports the passive mass 12 on the roof of the building 1. ing. The support means 16 is provided at both ends of the passive mass 12 in the longitudinal direction with a space therebetween.
[0018]
Each of the support means 16 has a laminated rubber unit 14 composed of a support substrate 14b made of a steel plate having a predetermined strength and a rectangular planar shape, and laminated rubbers 14 standing at the four corners of the support substrate 14b. Are stacked in eight stages. Then, the passive mass 12 is bridged and placed on the uppermost laminated rubber unit 14 of each supporting means 16, and the passive mass 12 is fixed to each laminated rubber 14a.
[0019]
Of the eight laminated rubber units 14, the upper two laminated rubber units 14 have a sliding mechanism 18 serving as elastic deformation restraining means for restraining elastic deformation of the laminated rubber 14a in a predetermined direction. Are arranged side by side on the laminated rubber 14a. The slide mechanism 18 includes a rail 18a arranged in the slide direction and a slider 18b sliding on the rail 18a, and the directions of the rails 18a are arranged in a unified manner. The rail 18 a of the slide mechanism 18 is fixed on the support substrate 14 b of the laminated rubber unit 14, along the short direction of the passive mass 12, and between the laminated rubbers 14 a constituting each laminated rubber unit 14. Is provided. On the other hand, the slider 18b is fixed to the support substrate 14b or the passive mass 12 of the laminated rubber unit 14 located immediately above where the rail 18a is provided, and slides along the rail 18a. As an example of the slide mechanism 18 used here, a plurality of steel balls are interposed between the rail 18a and the slider 18b in order to ensure the durability performance, and the steel balls circulate and slide performance due to wear of the steel balls. A linear bearing that slides the slider 18b while preventing the deterioration is suitable.
[0020]
The active vibration damping means 20 is provided on the passive mass 12 so as to be positioned at the center in the longitudinal direction of the passive mass 12. This active vibration damping means 20 is provided with a base board 32 on the passive mass 12, and along the short direction of the passive mass 12, that is, along the direction in which the passive mass 12 oscillates in a long cycle, at the center of the base board 32. A screw shaft 36 is provided, and an active mass 38 is screwed onto the screw shaft 36. The screw shaft 36 is rotatably supported via a bearing on a support member 34 erected on the base board 32 at an appropriate interval. One end of the screw shaft 36 is attached to a shaft of a servo motor 40 as a driving device. It is connected. The servo motor 40 is connected to a control unit that controls the rotation thereof, and the control unit is connected to a detection unit that detects vibrations of the building 1 and the passive mass 12. Further, a groove portion 42 is provided on the upper surface of the base board 32 along the screw shaft 36, and the lower end of the active mass 38 enters the inside thereof so that the active mass 38 does not rotate as the screw shaft 36 rotates. Is formed.
[0021]
With the above configuration, in the hybrid vibration damping device 30 of the present embodiment, the laminated rubber unit is provided by the slide mechanism 18 provided in the laminated rubber unit 14 at the upper two stages of the support means 16 constituting the passive vibration damping means 10. 14 is restrained from elastic deformation in the longitudinal direction of the passive mass 12. Therefore, even if a vibration that is displaced in the longitudinal direction of the passive mass 12 is input, the upper two-tiered laminated rubber unit 14 does not act, and only the laminated rubber 14a of the lower six-tiered laminated rubber unit 14 is elastically deformed. To reduce vibration. On the other hand, when vibrations in the short direction of the passive mass 12 are input, the laminated rubbers 14a of all eight laminated rubber units 14 function to reduce vibrations. That is, the number of the laminated rubber units 14 that function to suppress the vibration against the input vibration is different between the longitudinal direction and the short direction of the passive mass 12, and there are two types depending on the direction while being a single support means 16. Can be provided. Therefore, the passive damping means 10 has a short natural vibration period in the longitudinal direction of the passive mass 12 and a long natural vibration period in the short direction.
[0022]
That is, when installing the vibration damping device 30 of this hybrid system, the two orthogonal directions are specified, and the slide mechanism 18 is arranged side by side along the direction in which the oscillation cycle of the building 1 is long. The laminated rubber 14a is arranged to be elastically deformed. As a result, the direction in which the building 1 swings in a long cycle can coincide with the direction in which the passive mass 12 swings greatly. Therefore, it can be efficiently attenuated in accordance with the oscillation cycle of the building 1.
[0023]
Further, since the number of the laminated rubbers 14a in which the slide mechanism 18 is arranged side by side is arbitrary, by adjusting the number, it is possible to easily change the vibration cycle in which the passive vibration damping means 10 is tuned, and to vibrate the vibration. The period can also be set arbitrarily.
[0024]
In particular, since the slide mechanism 18 has a simple structure, it can be easily installed and removed, and the natural vibration period of the passive vibration damping means 10 can be synchronized with the vibration period of the building 1 only by this attachment / detachment. Is easy.
[0025]
In the active vibration damping device 20, the detection means detects the vibration of the building 1 and the vibration of the passive mass 12, and the control means controls the rotation of the servo motor 40 based on these detection data, so that the screw shaft 36 is The active mass 12 is rotated and moved in the axial direction of the screw shaft 36 while being guided by the groove 42. At this time, the servo motor 40 is rotated forward and backward in response to the input vibration, so that the active mass 38 reciprocates in the groove 42.
[0026]
That is, since the active mass 38 is provided so as to be able to reciprocate along the short direction of the passive mass 12 provided with the screw shaft 36, the detection frequency and the tuning frequency can be freely adjusted by the control means. Thus, long-period vibration can be more effectively suppressed.
[0027]
And, by combining the passive vibration damping means and the 10 active vibration damping means 20 which are the vibration damping devices of the present invention as described above, both the vibration damping means 10 and 20 interact with each other for vibration damping. Of course, even when the natural vibration period of the passive vibration damping device 10 and the vibration period of the building 1 are not synchronized, the active vibration damping device 20 can be controlled to effectively dampen the vibration.
[0028]
In the above embodiment, the number of stacking stages of the laminated rubber units 14 of the passive mass 12 is eight, and the number of stages where the slide mechanism 18 is juxtaposed with the laminated rubber 14a is two upper stages, but these are merely examples, The number of steps where the laminated rubber unit 14 is provided and the position where the slide mechanism 18 is provided are not limited thereto.
[0029]
In the above embodiment, the vibration of the passive mass 12 can be damped by the hysteresis damping of the laminated rubber 14a. However, if necessary, a vibration damping means such as an oil damper is provided between the building 1 and the passive mass 12. May be added.
[0030]
【The invention's effect】
As described above , according to the vibration damping device of the present invention , the elastic deformation restraining means for restricting the elastic deformation of the laminated rubber unit in a predetermined direction is provided in a part of the laminated rubber unit of the support means. The elastic deformation in a predetermined direction of a part of the laminated rubber units of the support means can be restricted, and the elastic deformation in an unregulated direction can be allowed.
Accordingly, since the support means as a whole has high rigidity in the direction in which the elastic deformation is restricted by the elastic deformation restraining means and the natural vibration period of the additional mass body can be shortened, the elastic means in the direction in which the elastic deformation is restricted. Thus, the additional mass body can be swung in a short cycle, and can be swung in a long cycle in an unregulated direction. As a result, since one vibration damping device can obtain different natural vibration periods depending on directions, it is possible to attenuate oscillations having different vibration periods.
[0031]
Further, when the vibration damping device is installed in the structure, the elastic deformation of a part of the laminated rubber units of the support means of the vibration damping device is not restricted with respect to two directions perpendicular to the horizontal direction in which the structure swings. The direction in which the structure and the direction in which the structure oscillates in a long cycle are matched, and the direction in which the elastic deformation of a part of the laminated rubber unit of the support means of the vibration damping device is regulated and the direction in which the structure oscillates in a short cycle By matching these, vibrations that are input efficiently can be damped in accordance with the vibration period of the structure.
[0032]
Furthermore, since the elastic deformation restraining means is constituted by a slide mechanism comprising a rail and a slider provided so as to be slidable along the rail, the structure can be simplified, and attachment and removal can be facilitated. Can do. Therefore, the natural vibration period of the vibration damping device can be easily synchronized with the vibration period of the structure.
[Brief description of the drawings]
FIG. 1 is a front view of a hybrid vibration damping device according to an embodiment of the vibration damping device of the present invention.
2 is a plan view of FIG. 1. FIG.
FIG. 3 is a side view of elastic deformation restraining means applied to the present invention.
[Explanation of symbols]
1 Building 10 Passive Damping Means 12 Passive Mass (Additional Mass)
14 Laminated rubber unit 14a Laminated rubber 14b Support substrate 16 Support means 18 Slide mechanism (elastic deformation restraining means)

Claims (3)

A damping device comprising: an additional mass body; and a support means for stacking elastically deformable laminated rubber units in a plurality of stages to support the additional mass body on a structure,
A vibration damping device , wherein elastic deformation restraining means for restraining elastic deformation of the laminated rubber unit in a predetermined direction is provided in a part of the laminated rubber unit of the support means . The elastic deformation restraining means allows the swinging in one orthogonal direction and the other direction orthogonal when the structure swings in any two directions orthogonal to the horizontal direction in response to an external force in the horizontal direction. vibration damping device according to claim 1, characterized that you restrict the swinging of the. The elastic deformation restraining means is a slide mechanism including a rail provided along a direction allowing swinging and a slider provided so as to be slidable along the rail . Damping device.

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