JP5644492B2 - Vibration control system - Google Patents

Description

  The present invention relates to a vibration suppression system that controls vibration of a vibration suppression object.

  Conventionally, a vibration suppression system for controlling vibration of a vibration suppression object, an upper structure portion fixed to the vibration suppression object, a mass body suspended from the upper structure portion, and the mass body There is known a vibration suppression system including a damper that decelerates relative movement with respect to a vibration suppression target (for example, Patent Document 1).

JP-A-6-58012

  By the way, in order to control the vibration of the object to be controlled, it is necessary to design the period of the pendulum motion of the mass body to be synchronized with the natural period of the object to be controlled. Here, when the natural period of the vibration control object is long, the suspended length of the mass body needs to be increased. However, if the suspended length of the mass body is long, there is a problem that it may be difficult to secure a space for the vibration damping system.

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide a vibration damping system in which the suspension length of the mass body is short while the period of the pendulum motion of the vibration damping system is set to a predetermined period. .

The main invention for achieving this object is:
A vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
Equipped with a,
A vibration control system comprising a plurality of the hinge mechanisms, wherein a direction of the rotation shaft provided in the first hinge mechanism is different from a direction of the rotation shaft provided in the second hinge mechanism. .
According to such a vibration suppression system, the suspension length of the mass body can be shortened while the period that can be accommodated by the vibration suppression system is a predetermined period.
Further, when the vibration control system vibrates, relative movement in any horizontal direction between the first mass body and the second mass body can be suppressed.

Further, a vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
With
The vibration control system is characterized in that a plurality of the hinge mechanisms are arranged so as to be point-symmetric with respect to the center of gravity of the first mass body and the second mass body .

Further, a vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
With
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
A suspension member having rigidity and suspending the first mass body from the upper structure portion;
One end of at least one of the dampers is connected to a part of the suspension member in which the movement distance of the suspension member when the first mass body oscillates is smaller than the movement distance of the first mass body. ,
The other end of the damper which is connected to the first mass member in said one end is a damping system, characterized in that connected to the upper structure portion or the lower structure portion.

  According to such a vibration suppression system, vibration can be damped with a damper having a small stroke.

Further, a vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
With
A damper for reducing the speed of relative movement of the first mass body or the second mass body with respect to the object to be controlled;
One end of at least one of the dampers is connected to a part of the support member where the movement distance of the support member when the second mass body oscillates is smaller than the movement distance of the second mass body. ,
The other end portion of the damper connected to the second mass body at the one end portion is connected to the upper structure portion or the lower structure portion .

Further, a vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
With
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
A suspension member having rigidity and suspending the first mass body from the upper structure portion;
With
Said second mass body has a shape extending in four directions in the horizontal direction, a damping system, characterized in that connected to the support member at each end which extends in all directions of the second mass.

  According to the present invention, the suspended length of the mass body can be shortened while setting the period of the pendulum motion of the vibration suppression system to a predetermined period.

It is a conceptual diagram which shows typically the structure of the damping system 1 of 1st Embodiment from the side. It is a conceptual diagram which shows typically the structure of the vibration suppression system 1 from an upper surface. It is explanatory drawing which shows the structure of the hinge mechanism 30 in perspective. It is a figure which shows typically the state where the vibration suppression system 1 is vibrating because the vibration suppression object receives external force and vibrates from the side. It is a conceptual diagram for demonstrating the vibration period T [s] of the damping system.

=== First Embodiment ===
FIG. 1 is a conceptual diagram schematically showing the configuration of the vibration damping system 1 of the first embodiment from the side surface (some parts are omitted to make the drawing easier to see). FIG. 2 is a conceptual diagram schematically showing the configuration of the vibration damping system 1 from above. As shown in FIGS. 1 and 2, the vibration damping system 1 includes an upper structure portion 10, a first mass body 12, a suspension member 14, a lower structure portion 20, a second mass body 22, a support member 24, and a plurality of hinge mechanisms. 30 and a plurality of dampers 40 are provided.

  The upper structure portion 10 is a structure having a strength capable of bearing a load of a first mass body to be described later, and is fixed to a vibration suppression object (not shown) that is a vibration suppression object.

  The first mass body 12 is a mass body having a mass. A part of the first mass body 12 is a removable weight, and the mass of the first mass body 12 can be adjusted by attaching or removing a part of the weight.

  The suspension member 14 is a bar that suspends the first mass body 12 from the upper structure portion 10. The suspension member 14 has joint members 14a in the vicinity of the portion connected to the upper structure portion 10 and in the vicinity of the portion connected to the first mass body 12, thereby enabling the pendulum movement of the first mass body 12. To do.

  The lower structure portion 20 is a structure having a strength capable of bearing a load of a second mass body to be described later, and is fixed to a vibration suppression target (not shown) that is a vibration control target.

  The second mass body 22 is a mass body having a lighter mass than the first mass body 12. A part of the second mass body 22 is a detachable weight, and the mass of the second mass body 22 can be adjusted by attaching or removing a part of the weight. As shown in FIG. 2, the second mass body 22 has arm portions that extend in all directions, and is supported by being connected to the support member 24 on the lower surface of the distal end portion of each arm portion.

  The support member 24 is a bar that supports the second mass body 22 so that the second mass body 22 is positioned above the lower structure portion 20. The support member 24 has joint members 24 a in the vicinity of the portion connected to the lower structure portion 20 and in the vicinity of the portion connected to the second mass body 22, thereby enabling the pendulum movement of the second mass body 22. To do.

  The hinge mechanism 30 connects the first mass body 12 and the second mass body 22 so as to be relatively movable in the vertical direction. FIG. 3 is an explanatory view perspectively showing the configuration of the hinge mechanism 30. As shown in the figure, the hinge mechanism 30 includes a main rotating shaft 31 (corresponding to a rotating shaft), a first rotating member 32, a first rotating shaft 33, a first mounting member 34, a first nut 35, and a second rotating member. 36, a second rotating shaft 37, a second attachment member 38, and a second nut 39.

  The first rotating member 32 is a quadrangular plate member. The main rotating shaft 31 is attached to one side, and the first rotating shaft is located on the side opposite to the side to which the main rotating shaft 31 is attached (the side that is parallel). 33 is attached. That is, the main rotating shaft 31 and the first rotating shaft 33 are arranged so as to be parallel to each other. The first rotating member 32 can rotate about the main rotating shaft 31 and can rotate about the first rotating shaft 33. In addition to the 1st rotation member 32, the 1st attachment member 34 is attached to the 1st rotating shaft 33 so that rotation is possible. The first attachment member 34 is fixed to the first mass body 12 with a first nut 35.

  Similarly, the second rotating member 36 is a quadrangular plate member, and the main rotating shaft 31 is attached to one side, and the second rotating member 36 is arranged on the side opposite to the side to which the main rotating shaft 31 is attached (a side that is parallel). A two-rotation shaft 37 is attached. That is, the main rotating shaft 31 and the second rotating shaft 37 are arranged so as to be parallel to each other. The second rotating member 36 can rotate about the main rotating shaft 31 and can rotate about the second rotating shaft 37. In addition to the second rotation member 36, a second attachment member 38 is attached to the second rotation shaft 37 so as to be rotatable. The second attachment member 38 is fixed to the second mass body 22 with a second nut 39.

  As shown in FIG. 2, four hinge mechanisms 30 are provided. In other words, the hinge mechanism 30 is connected to the central portions of the four sides of the upper surface of the first mass body 12 in the first mounting member 34. Further, the hinge mechanism 30 is connected to the lower surface of the arm portion of the second mass body 22 extending in all directions. That is, when viewed from above the vibration damping system 1, the four hinge mechanisms 30 are arranged so as to be point-symmetric with respect to the center of gravity of the first mass body 12 and the second mass body 22.

  The damper 40 includes a cylinder and a piston rod. The cylinder of the first damper 40 a is fixed to the upper structure portion 10. The end of the piston rod of the first damper 40a is connected to a part of the suspension member 14 near the upper structure 10. The connection portion of the first damper 40a to the suspension member 14 includes a joint that can rotate on the pendulum motion surface of the suspension member 14, and the first damper 40a and the suspension member 14 are connected via this joint.

  Further, the cylinder of the second damper 40 b is fixed to the lower structure portion 20. The end of the piston rod of the second damper 40 b is connected to a part of the support member 24 near the lower structure 20. The connecting portion of the second damper 40b to the support member 24 is provided with a joint that can rotate on the pendulum motion surface of the support member 24, and the second damper 40b and the support member 24 are connected via this joint.

  Further, the cylinder of the third damper 40 c is fixed to the upper surface of the second mass body 22. The end of the piston rod of the third damper 40 c is connected to the lower surface of the first mass body 12.

  Next, the operation of the vibration suppression system 1 when the vibration suppression object receives an external force and vibrates will be described.

  FIG. 4 is a diagram schematically showing a state in which the vibration suppression system 1 vibrates (pendulum motion) from the side when the vibration suppression target object receives an external force and vibrates. As shown in the figure, when the first mass body 12 and the second mass body 22 move in the left-right direction by pendulum movement, the suspension member 14 and the support member 24 are tilted, and the hinge mechanism 30 is folded in the vertical direction. The first mass body 12 and the second mass body 22 relatively move in the vertical direction. The first damper 40 a connected to the suspension member 14 attenuates the vibration of the first mass body 12 through the suspension member 14, and the second damper 40 b connected to the support member 24 is connected to the second mass body 22 through the support member 24. Damping the vibration.

FIG. 5 is a conceptual diagram for explaining the vibration period T [s] of the vibration suppression system 1. Here, hanging member 14 and the length L of the support member 24 [m] and the mass _m 1 of the first mass body 12 [kg] mass _m 2 _[kg] of the second mass 22 (m 2 _<m 1) The relationship between these and the vibration period T [s] of the vibration suppression system 1 will be described. In order to simplify the explanation, it is assumed that the suspension member 14 and the support member 24 have no mass. In addition, as a mechanism for connecting the first mass body 12 and the second mass body 22, a slide mechanism 50 that can ignore the frictional force is used instead of the hinge mechanism 30.

In the drawing, the horizontal external force F ₁ acting on the mass point of the first mass body 12 acts on the mutual system via the slide mechanism 50 when the mass points of the first mass body 12 and the second mass body 22 are integrated. When the horizontal force F _s that is obtained by the following equation 1.
Similarly, the horizontal external force F ₂ acting on the mass point of the second mass body 22 is obtained by the following equation 2.
Now, since the mass points of the first mass body 12 and the second mass body 22 move integrally in the horizontal direction, the restoring force F acting on the system in which these masses are integrated is obtained by the following equation 3.

Equations 1 and 2 are restoring forces F ₁ and F ₂ acting on the mass points of the first mass body 12 and the mass point of the second mass body 22 when viewed individually. Represents the restoring force F when viewed as a unit. Since these three systems all have the same movement, the ratio of the restoring force to the inertial force needs to be the same. This condition is expressed by the following formula 4.
Here, the horizontal force F _s is expressed by the following Expression 5 when Expression 4 is substituted into Expression 1 and Expression 2.

Next, assuming that the mass point x of the first mass body 12 shown in FIG. 4 is the horizontal displacement x, the relationship between the displacement x and the length L of the suspension member 14 is expressed by the following formula 6.
When the mass point of the first mass body 12 vibrates with the period T, the acceleration a is expressed by the following expression 7.
The inertial force obtained by multiplying the mass of the first mass body 12 and the second mass body 22 by this is balanced with the restoring force of Equation 3, and the period T is expressed as Desired.
When the horizontal displacement x of the mass point of the first mass body 12 or the second mass body 22 is large, the value of the period T greatly fluctuates, but the horizontal displacement x is in a range where the deflection angle θ is 30 degrees or less. If there is, the fluctuation in the period is small, and there is no practical problem.

As described above, according to the vibration damping system 1 of the first embodiment, the suspended length of the mass body can be shortened while the period of the pendulum motion is set to a predetermined period.
Generally, the period of the suspended pendulum The T _g, when Tsucho of L _{g [m],} is represented by the following formula 9.
That is, the period T _g of the hanging pendulum depends only on Tsucho of L _g. Therefore, in order to lengthen the period T _g of the hanging pendulum, it is necessary to increase the Tsucho of L _g. For example, the natural period of a high-rise apartment is a long period of 5 to 10 seconds, but the hanging length of such a hanging pendulum is 10 m or more. Then, it does not fit very much on the first floor of the apartment (usually around 3m).

However, according to the damping system 1, as shown in Equation 8, the period T is the length of the hanging member 14 L, the mass _{m 1} of the first mass body 12, a function of the mass _{m 2} of the second mass 22 If the mass of the second mass body 22 relative to the mass of the first mass body 12 is increased within a range not exceeding the mass of the first mass body 12, the length L of the suspension member 14 is a predetermined value. Also, the period of the vibration suppression system 1 can be lengthened. That is, assuming that the height of the vibration damping system 1 needs to be within a predetermined length (for example, about 3 m) for the sake of design, the mass m ₁ of the first mass body 12 and the mass m of the second mass body 22 By adjusting the ratio of ₂ , it is possible to match the natural period of the structure to which the vibration damping system 1 is mounted.

For example, according to Equation 8, if the natural period of a high-rise apartment that is a vibration control object is 8 seconds, the period of the vibration suppression system 1 must also be set to 8 seconds. Here, if the ratio of the mass m ₁ to the mass m ₂ is 8: 7 and the length L of the suspension member 14 is 1 [m], the period of the vibration damping system 1 can be about 8 seconds. In this case, the length of the support member 24 is also 1 [m], and the total length of the suspension member 14 and the support member 24 is about 2 [m], and the vibration damping system 1 can be stored on one floor. it can. On the other hand, in order to set the period to 8 seconds with a general pendulum as shown in Equation 9, the arm length of the pendulum needs to be about 16 [m], and a space for storing this is secured. It is difficult.

  Furthermore, according to the vibration damping system 1 of the first embodiment, since the first mass body 12 and the second mass body 22 are connected by the hinge mechanism 30, the first mass body 12, the second mass body 22, The friction during the relative movement of the vibration control system 1 can be further reduced, so that the vibration suppression performance of the vibration suppression system 1 can be made more accurate. That is, if a damping force that attenuates the vibration of the damping system 1 other than the damper 40 is generated, the damping system 1 must be designed in consideration of the damping force. That is, the design of the vibration suppression system 1 becomes complicated, and it becomes difficult to ensure accurate vibration suppression performance. However, according to the vibration damping system 1 of the first embodiment, the friction during the relative movement between the first mass body 12 and the second mass body 22 can be further reduced. The generation of a damping force that attenuates the vibration of 1 can be suppressed. Therefore, the design of the vibration damping system 1 is simplified, and it is easy to ensure accurate vibration damping performance.

  Further, according to the vibration damping system 1 of the first embodiment, there are a plurality of hinge mechanisms 30, the direction of the main rotation shaft 31 provided in a certain hinge mechanism 30, and the main rotation shaft 31 provided in another hinge mechanism 30. By being different from the direction of facing, the relative movement of the first mass body 12 and the second mass body 22 in any horizontal direction can be suppressed.

  Further, according to the vibration damping system 1 of the first embodiment, when the vibration damping system 1 is viewed from above, the point is symmetrical with respect to the center of gravity of the first mass body 12 and the second mass body 22. By arranging the plurality of hinge mechanisms 30, it is possible to suppress the load in the twisting direction on the hinge mechanism 30.

  As shown in FIG. 1, the first mass body 12 and the second mass body 22 are located at positions separated in the vertical direction and are connected via a hinge mechanism 30, so that the height of the vibration damping system 1 is The total length of the suspension member 14 and the support member 24 can be made shorter. That is, the height of the vibration damping system 1 is approximately the sum of the lengths of the suspension member 14 and the support member 24, and the location where the hinge mechanism 30 is connected to the first mass body 12 and the hinge mechanism 30 is the second mass body 22. The distance between the connecting points can be subtracted.

Further, according to the vibration suppression system 1, at the construction site where the vibration suppression system 1 is installed, the mass of at least one of the first mass body 12 and the second mass body 22 is adjusted, and the ratio of the mass m ₂ to the mass m ₁ By changing, the period T of the vibration damping system 1 can be easily adjusted.

  Moreover, according to the vibration suppression system 1, since the damper is provided at a portion with a small amplitude such as the suspension member 14 and the support member 24, a damper having a short movable range can be used. Generally, the cost of the damper increases as the stroke length of the damper increases. In the vibration suppression system 1, a damper having a short stroke can be used, so that the cost can be kept low.

  In addition, according to the vibration damping system 1, by making the length of the suspension member 14 equal to the length of the support member 24, the amplitude of the first mass body 12 and the second mass body 22 can be increased, and thus the larger Vibration control performance can be obtained. That is, when the deflection angle of the suspension member 14 and the support member 24 exceeds 30 degrees, the period of the vibration suppression system 1 varies greatly. Therefore, if the total length of the suspension member 14 and the support member 24 is predetermined, the deflection angle of the suspension member 14 and the support member 24 is within 30 degrees if the lengths of the suspension member 14 and the support member 24 are equal. However, the horizontal displacement x can be maximized, and a large vibration control performance can be obtained.

  In addition, the third damper 40c that reduces the speed of relative movement of the first mass body 12 or the second mass body 22 with respect to the vibration suppression target, and a suspension that is rigid and suspends the first mass body 12 from the upper structure 10. And the second mass body 22 has a shape extending in all directions in the horizontal direction, and is connected to the support member 24 at each end portion extending in the four directions of the second mass body 22. The torsional load on the 3 damper 40c can be suppressed.

=== Second Embodiment ===
In the first embodiment, the lengths of the suspension member and the support member are equal, but in the vibration damping system of the second embodiment, the length of the support member L _s is shorter than the length of the suspension member L _h. . Other configurations are the same as those of the first embodiment.

In the vibration damping system of the second embodiment, when the mass of the first mass body 12 and the second mass body 22 and the length of the suspension member 14 are constant, the length of the support member 24 is shorter than the length of the suspension member 14. Since the horizontal displacements x of the mass points of the first mass body 12 and the second mass body 22 are equal, the swing angle of the support member 24 is increased. Then, the horizontal external force F ₂ that acts on the mass point of the second mass body 22 increases as determined by Equation 2. When the horizontal force F ₂ increases, it means that counteracting resiliency mass of the first mass body 12, it is possible to lengthen the period of damping system 1.

  As described above, according to the vibration damping system of the second embodiment, the length of the support member 24 is made shorter than the length of the suspension member 14, so that the period that can be supported by the vibration damping system is set to a predetermined period. The overall length can be shortened.

  Further, according to such a vibration suppression system, when the period of the vibration suppression system 1 is constant, the weight of the second mass body can be reduced while the length of the support member 24 is shortened, and thus the vibration suppression system 1 is controlled. The entire weight of the vibration system 1 can be reduced.

=== Third Embodiment ===
The vibration suppression system of the first embodiment and the second embodiment is a passive system, but the vibration suppression system of the second embodiment is a hybrid system that further includes an excitation device connected to the first mass body 12. .

  Here, the passive system does not actively act on the object to be controlled, and includes passive vibration control means such as a pendulum and absorbs the vibration of the object to be controlled by the vibration of the pendulum. Is. On the other hand, in the active method, an additional mass body is placed on the object to be controlled, and the object is controlled by displacing it according to the vibration state of the object to be controlled. Furthermore, the hybrid method is a combination of the passive method and the active method.

  According to the vibration suppression system 1, the vibration control performance can be improved while the masses of the first mass body and the second mass body are kept constant by providing the vibration control device.

=== Other Embodiments ===
As mentioned above, although embodiment of this invention was described, this invention is not limited to this embodiment, The deformation | transformation as shown below is possible in the range which does not deviate from the summary.

DESCRIPTION OF SYMBOLS 1 Damping system 10 Upper structure part 12 1st mass body 14 Suspension member 14a Joint member 20 Lower structure part 22 2nd mass body 24 Support member 24a Joint member 30 Hinge mechanism 31 Main rotating shaft 32 1st rotation member 33 1st rotation Shaft 34 First mounting member 35 First nut 36 Second rotating member 37 Second rotating shaft 38 Second mounting member 39 Second nut 40 Damper 40a First damper 40b Second damper 40c Third damper 50 Slide mechanism

Claims (5)

A vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
Equipped with a,
A vibration control system comprising a plurality of hinge mechanisms, wherein a direction of the rotation shaft provided in the first hinge mechanism is different from a direction of the rotation shaft provided in the second hinge mechanism . A vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
With
A vibration damping system, wherein the plurality of hinge mechanisms are arranged so as to be point-symmetric with respect to the center of gravity of the first mass body and the second mass body. A vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
With
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
A suspension member having rigidity and suspending the first mass body from the upper structure portion;
One end of at least one of the dampers is connected to a part of the suspension member in which the movement distance of the suspension member when the first mass body oscillates is smaller than the movement distance of the first mass body. ,
The other end of the damper connected to the first mass body at the one end is connected to the upper structure or the lower structure. A vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
With
A damper for reducing the speed of relative movement of the first mass body or the second mass body with respect to the object to be controlled;
One end of at least one of the dampers is connected to a part of the support member where the movement distance of the support member when the second mass body oscillates is smaller than the movement distance of the second mass body. ,
The other end of the damper connected to the second mass body at the one end is connected to the upper structure or the lower structure. A vibration control system for controlling vibration of a vibration control object,
An upper structure fixed to the vibration control object;
A first mass suspended from the upper structure,
A lower structure fixed to the vibration control object;
A support member rotatably connected to the lower structure part;
A second mass body lighter than the first mass body, supported by the support member and positioned above the lower structure portion;
A hinge mechanism for connecting the first mass body and the second mass body so as to be relatively movable in the vertical direction by having a rotation axis arranged in a direction intersecting the vertical direction;
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
With
A damper that decelerates the speed of relative movement of the first mass body or the second mass body relative to the object to be controlled;
A suspension member having rigidity and suspending the first mass body from the upper structure portion;
With
The second mass body has a shape extending in four directions in the horizontal direction, and is connected to the support member at each end portion extending in the four directions of the second mass body.