JPH044336A - Vibration damping device - Google Patents

Abstract

PURPOSE:To easily vary or adjust the characteristic frequency of a main mass by elastically supporting the main mass on a supporting frame through a nonlinear coil spring, and varying the spring constant of a nonlinear coil spring by adjusting a preset deflection adjusting bolt installed on a supporting frame. CONSTITUTION:As for a vibration suppressing device 30, a main mass 20 is elastically held on a supporting frame 10 through coil springs 25 and 27 which possess the nonlinear load/deflection characteristic, and each spring constant of these springs 25 and 27 is the sum of the spring constant of the coil springs 25 and 27. Accordingly, the spring constant of each coil spring 25, 27 is varied by screwing or screwing back a preset deflection adjusting bolt 29 for the upper plate 101 of the supporting frame 10, and the spring constant of the whole can be varied, and the characteristic frequency of the main mass 20 can be adjusted easily.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a vibration damping device, and particularly to a vibration damping device whose natural frequency is adjustable.

2. Description of the Related Art Conventionally, it has been known to use passive vibration damping devices to damp vibrations of building structures.

For example, one example of this type of vibration damping device is shown schematically in FIG. 4 of the accompanying drawings, in which a support frame 1
, a mass 2 and a coil spring 3 for elastically supporting the mass 2 on a support frame 1 are known.

The vibration damping device having such a configuration can be appropriately attached to the floor structure of a building structure, for example, and
By selecting the optimum natural frequency of the vibration damping device with respect to the natural frequency of the floor structure, it is possible to effectively damp the vibrations of the floor structure.

In addition, as a means to select the optimal natural frequency of this type of vibration damping device, the spring constant of the coil spring can be adjusted to the optimal value, or the mass can be increased or decreased to the optimal value. There are two possible methods.

That is, the natural frequency f of such a damping device.

The mass of mass 2 is 1. When the spring constant of the coil spring 3 is k, it is expressed by the following formula (% formula %).As can be seen from this formula, the natural frequency f. This is because in order to make the optimum value, it is necessary to increase or decrease the mass M of the mass 2 or adjust the spring constant k of the coil spring 3.

However, when adjusting the natural frequency of this damping device, if this is done by increasing or decreasing the mass m of mass 2, then in order to increase or decrease the mass m of mass 2, it is necessary to compare It is easy to see that this requires a complex configuration.

[Note: For example, “Architectural Institute of Japan Structural System Paper Report Collection” No. 3
No. 87 (March 1987), pages 89 to 93, ``Experimental Report on Damping Performance of Floor Structures. Also, if you do this by adjusting the
It is easy to understand that similar difficulties are involved.

SUMMARY OF THE INVENTION Therefore, the present invention provides a vibration damping device that can easily adjust the natural frequency of a passive vibration damping device having the above-mentioned configuration. to get,
This is the issue to be addressed.

In order to solve this problem, in the present invention, as shown in FIGS. 1 and 2 of the attached drawings, the support frame (10)
and coil springs (25, 27) installed thereon,
The support frame (10
) and a main mass (20) elastically supported by an upper plate (101) and a lower plate (
The main mass (20) is arranged in the space between the upper and lower plates (101, 102), and the upper and lower parts of the main mass (20) and the upper and lower plates (106, 10 of the support frame (10)
2), respectively, with coil springs (25, 27) arranged between them, and at least one of the upper and lower coil springs (25, 27>) having non-linear load/deflection characteristics. The device is characterized by:

Hereinafter, the present invention will be described with reference to Nos. 1 to 1 of the attached drawings showing one embodiment thereof.
A detailed explanation will be given based on Figure 3.

As shown in FIGS. 1 and 2, a vibration damping device 30 according to an embodiment of the present invention includes a support frame 10 whose height does not change in the vertical direction, a main mass 20, and coil springs 25 and 27. There is.

First, the support frame 10 is made up of identical plate members having substantially rectangular planar contours arranged in parallel in the vertical direction at intervals corresponding to the height of the upper plate 10.
1 and lower plate 102, and these upper plate 101 and lower plate 10
These upper plates 10.2 are vertically supported at this spacing. and four wooden support columns 121 to 124 that firmly connect the four corner parts of the lower plate 102.

Further, the main mass 20 includes the upper and lower plates 10 . of the support frame 10 .
．． It has a rectangular plane profile smaller than the plane profile of 102 and a rectangular hexahedral shape having a height smaller than the interval between them, and the center O thereof is located at the upper plate of the support frame. 10. and coincides with the center O of 102, and
Its top surface 201 and bottom surface 202 are parallel to and spaced from the upper and lower plates 101 and 1o2 of the support frame 1o, and its side walls 203-206 are parallel to and spaced from the upper and lower plates 101 and 1o2 of the support frame 1o.
．． and 10□ are arranged so as to be parallel to each corresponding side.

Furthermore, the coil spring consists of four coil springs 25 and one coil spring 27, both of which have nonlinear "load/deflection" characteristics.
The four coil springs 25 are attached to the bottom surface 202 of the main mass 20.
The other coil spring 27 is disposed perpendicularly between the corner and the upper surface of the lower plate 102 of the support frame 10, and supports the weight of the main mass 2o in the deflected state. Top surface 20 of mass 20. It is placed upright on top of the support frame 10, with its upper end attached to the top plate 101 of the support frame 10, and the top plate 10.
A press plate 29. is attached to the lower end of the preset deflection adjustment bolt 29 screwed vertically through the press plate 29. It is made to be pressed through.

One embodiment 30 of the vibration damping device according to the present invention has such a configuration, and the main mass 20 is connected to the coil springs 25 and 27 having nonlinear "load/deflection" characteristics. These coil springs 25 and 27 are elastically held by the support frame 10, and the spring constant of these coil springs 25 and 27 is the sum of the spring constants of each of these coil springs 25 and 27.

Therefore, the preset deflection adjustment bolt 29 is attached to the upper plate 10 of the support frame 10. By screwing in or unscrewing the coil springs 25 and 27, the spring constant of each coil spring 25 and 27 can be changed, and the overall spring constant can be changed. It can be adjusted.

Note that the nonlinear coil spring 25 used in the present invention
．． 27 can be implemented as an unequal pitch coil spring, a conical coil spring, or the like.

In addition, Fig. 3 shows the "
"Load/Deflection" curve in a Cartesian coordinate system, with the load on the vertical axis,
Deflection is shown qualitatively on the horizontal axis.

In addition, in the above embodiment, the coil springs 25 and 2
All of 7 are explained as having non-linear [load/deflection characteristics -1, but even if one of them has linear "load/deflection characteristics", Similarly, it is clear that the preset deflection adjustment bolt 29 allows the overall spring constant to be adjusted.

Published by 0g Treatment The present invention has the above-described configuration and operation, and includes a main mass that is elastically supported on a support frame via a nonlinear coil spring, and a nonlinear coil spring that is attached to the support frame. By adjusting the preset deflection adjustment bolt, it is possible to provide a vibration damping device that can easily change or adjust the natural frequency of the main mass.

[Brief explanation of drawings]

FIG. 1 is a front view showing one embodiment of the present invention, and FIG. 2 is a front view showing one embodiment of the present invention.
The plan view, FIG. 3, is a qualitative "load/deflection" diagram showing the relationship between the load and deflection of the nonlinear coil spring used in the embodiment shown in FIGS. 1 and 2, and FIG. The figure is a schematic front view showing a typical example of a conventional vibration damping device. 10... Support frame, 101... Top surface, 102...
...Bottom surface, 20...Main mass, 201...Top surface, 20
゜...Bottom surface, 25.27...Nonlinear coil spring, 2
9...Preset deflection adjustment bolt. Deflection

Claims (1)

[Claims] 1. In a vibration damping device consisting of a support frame, a coil spring installed on the support frame, and a main mass elastically supported by the support frame via the coil spring, the support frame is vertically Consisting of an upper plate and a lower plate fixedly arranged at intervals in the direction, the main mass is arranged in the space between the upper and lower plates,
Coil springs are arranged between the upper and lower parts of the main mass and the upper and lower plates of the support frame, and at least one of the upper and lower coil springs has non-linear load/deflection characteristics. vibration damping device. 2. The vibration damping device according to claim 1, wherein the deflection of the upper coil spring is adjustable by a preset deflection adjusting bolt attached to the upper plate of the support frame.