JPH0439441A - Vibration-removing and earthquake-resisting unit - Google Patents

Abstract

PURPOSE:To easily and efficiently execute the work and modification in the case of constructing a vibration-removing and earthquake-resisting structure by building a damping mechanism and a rubber buckling-preventing mechanism in laminated rubber. CONSTITUTION:In the case of applying a shake to a vibration-removing and earthquake-resisting unit 40, a period of the shake is extended by laminated rubber 32, and the shake is damped by a damping mechanism 42 arranged in the vibration-removing and earthquake-resisting unit 40. As a result, execution work of the vibration-removing and earthquake-resisting unit 40 can be performed without individually providing this damping mechanism 42.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to vibration isolation/seismic isolation units, and in particular to vibration isolation units used to protect buildings, precision equipment, etc. from shaking during earthquakes and traffic vibrations. Regarding vibration/seismic isolation units.

[Conventional technology]

Traditionally, when installing precision equipment etc. on the factory floor,
Vibration isolation devices are used to isolate precision equipment from traffic vibrations and vibrations caused by earthquakes.

As shown in FIGS. 4 and 5, this vibration isolation/seismic isolation device mainly consists of an equipment mounting stand 10, laminated rubber 12, 12...attenuator 1.
4.14, and a stopper 16.16. The equipment mounting table 10 is supported on the floor 18 via laminated rubber 12, 12, etc., and a stopper 1 installed on the floor 18 is attached to the side end thereof.
6.16 sliding parts 16A, 16A are attached. The stopper 16 limits the buckling displacement of the laminated rubber 12, 12, . . . to within an allowable range. In addition, equipment mounting stand 10
An attenuator 14.14 is provided between and the floor 18. Precision equipment 20 is installed on this equipment mounting stand 10.

FIG. 6 is an enlarged view of the main parts of the laminated rubber 12, 12.... Laminated rubber 12, 12, . . . in FIG. 6 are formed by alternately stacking rubber 22 and metal plates 24, and flanges 26A, 26B are attached to the upper and lower ends thereof.

The laminated rubber 12 is attached to the equipment mounting base 10 and the floor 18 via the flanges 26A and 26B. Therefore,
When earthquake vibrations occur on the floor 18, the vibration period of the floor 18 is extended by the laminated rubber 12, and this vibration is damped by the attenuator 1.
4, the vibrations are not transmitted to the precision equipment 20. Note that if only one damper is installed, torsional vibrations centered around the damper will be induced, so at least two dampers 14.14 must be installed.

Therefore, a laminated rubber 30 shown in FIG. 7 has been proposed so that one attenuator or no attenuator is required. The center of the laminated rubber 30 shown in FIG. 7 is filled with lead 28, and vibration displacement is damped by the flow resistance of the lead 28.

[Problem to be solved by the invention]

However, when using the laminated rubber 30 shown in FIG.
There is a drawback that minute vibrations caused by an earthquake propagate to the equipment mounting base 10 via the lead 28, and the vibrations are transmitted to the precision equipment 20. In addition, when the laminated rubber 12 shown in Fig. 6 is used, at least two attenuators and a plurality of stoppers 16, 16, etc. are required, which increases the number of component parts and increases the equipment. There is a problem in that the structure is complicated and construction requires time and effort.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a vibration isolation/seismic isolation unit that has a simplified lid structure and can be easily and quickly constructed.

[Means to solve the problem]

In order to achieve the above object, the present invention provides a vibration isolation/seismic isolation unit configured by alternately laminating a plurality of rubbers and reinforcing plates between an upper flange and a lower flange. A hole is bored in the center of the plate, and the rubber is supported and laminated at multiple points via the plurality of reinforcing plates between the upper flange and the lower flange, and the rubber and the reinforcing plate are laminated. The present invention is characterized in that a damping mechanism for connecting the upper flange and the lower flange is disposed in the space formed, and the damping mechanism is provided with a mechanism for preventing buckling of the rubber.

Further, the reinforcing plate and the rubber are formed into a ring shape, and a damping mechanism for connecting the upper flange and the lower flange is disposed in a space formed by alternately stacking the reinforcing plate and the rubber. The mechanism is provided with a mechanism for preventing buckling of the rubber.

[Effect]

According to the present invention, when shaking is applied to the vibration isolation/seismic isolation unit 7), the period of shaking is extended by the laminated rubber, and the vibration isolation/seismic isolation unit 7) is
The vibration is attenuated by a damping mechanism installed inside the seismic isolation unit. Therefore, the vibration isolation/seismic isolation unit can be constructed without providing a separate damping mechanism. Furthermore, since the buckling prevention mechanism provided in the damping mechanism prevents the laminated rubber from buckling, there is no need to separately install a damper or buckling prevention device when constructing the seismic isolation structure. Furthermore, since the vibration isolation/seismic isolation unit has a built-in damping mechanism, torsional vibration can be prevented without installing a separate damper.

〔Example〕

Preferred embodiments of the vibration isolation/seismic isolation unit according to the present invention will be described in detail below with reference to the accompanying drawings.

FIG. 1 is a perspective view showing the structure of a vibration isolation/seismic isolation unit according to the present invention. The vibration isolation/seismic isolation unit shown in FIG. 1 is mainly composed of rubber 32, 32, reinforcing plates 34, 34, an upper flange 3B, a lower flange 38, etc.

Rubbers 32, 32... have a circular shape, are laminated in a cylindrical shape via a plurality of reinforcing plates 34, 34... with circular holes, and are arranged between the upper flange 36 and the lower flange 38. 4
It is supported by points.

The upper flange 36 and the lower flange 38 are provided with installation holes 36A and 36B, and the vibration isolation/seismic isolation unit 40
This is the bolt hole when installing it on the floor etc. In addition, vibration isolation and
A damping mechanism 42 is disposed in the center of the seismic isolation unit 40 from the top to the bottom.

The damping mechanism 42 includes an upper casing 44A, a lower casing 44B, a viscous liquid 46, a resistor 48, a stopper 50, and the like. As shown in FIG. 1, an upper casing 44A formed in a cylindrical shape is attached to the upper flange 36, and a lower casing 44B is attached to the lower flange 38.
is installed. A shaft 52 is attached to the lower part of the upper casing 44A via a nut 54, and the shaft 52 can be moved up and down by adjusting the nut 54. The lower casing 44B is filled with a viscous liquid 46, and the lower casing 44B functions as a dashpot that dampens the displacement of the shaft 52. A resistor 48 that moves within the casing 44B is attached to the tip of the shaft 52, and the vibrational displacement of the shaft 52 is damped by the flow resistance that the resistor 48 receives from the viscous liquid 46 within the casing 44B. Damping force is viscous liquid 46
It is set to an appropriate value by appropriately setting the viscosity of the resistor 48, the diameter of the resistor 48, etc.

Furthermore, the damping mechanism 42 is provided with a buckling prevention mechanism, and a tapered stopper 50 is screwed into the approximate center of the threaded portion formed on the shaft 52, so that the shaft 52 is prevented from being subjected to severe displacement exceeding the allowable range. When this happens, the stopper 50 comes into contact with the upper end of the lower casing 44B to prevent the rubbers 32, 32, . . . from buckling. Furthermore, since the position of the stopper 50 can be adjusted up and down, the permissible displacement of the vibration isolation/seismic isolation unit 40 can be adjusted.

FIG. 2 is a front view showing a vibration isolation/seismic isolation device constructed using the vibration isolation/seismic isolation unit 40 according to the present invention. Second
As shown in the figure, the vibration isolation/seismic isolation unit 40 consists of an equipment mounting stand 10 and a concrete floor 1, as in the case of conventional laminated rubber.
Crotch between 8! be done. The vibration isolation/seismic isolation unit 40 has a damping mechanism 42 and a stopper 50 in advance (vibration isolation/seismic isolation unit) 4
Since they are built into 0, there is no need to install them separately. As a result, it is only necessary to fix the vibration isolation/seismic isolation unit 40 between the equipment mounting stand 10 and the concrete floor 18, allowing quick and easy construction.

The action of the vibration isolation/seismic isolation unit 40 configured as described above is as follows. When an earthquake occurs, buildings lose their rigidity.
It vibrates at regular intervals, and when this natural period resonates with the ground, the shaking is amplified, causing damage to precision equipment. Therefore,
First, in the event of an earthquake, the period of shaking transmitted from the concrete floor 18 is lengthened by the laminated rubber 32 and converted into slow shaking. Furthermore, a damping mechanism 42 built into the vibration/seismic isolation unit 40 attenuates the displacement transmitted from the concrete floor 18 to the equipment mounting base 10, thereby insulating the precision equipment from shaking during an earthquake.

Further, when the displacement of the equipment mounting base 10 exceeds the permissible range, the stopper 50 comes into contact with the lower casing 44B, thereby preventing the laminated rubber 32 from buckling. As mentioned above, the position of the stopper 50 can be changed arbitrarily, so vibration isolation and seismic isolation can be achieved by appropriately changing the position of the stopper 50 within a range that does not cause buckling of the vibration isolation/seismic isolation unit 40. Units) 400 strokes can be adjusted. Further, since the damping mechanism 42 is built into the vibration isolation/seismic isolation unit 40, there is no need to separately install a damper, and the structure can be simplified. In addition, vibration isolation/seismic isolation unit 4
Since attenuators will be installed as many as 0,
Torsional vibration of the equipment mounting base 10 is prevented. Furthermore, since the displacement is attenuated by the flow resistance of the viscous liquid 46, slight vibrations are not transmitted to the equipment mounting base 10.

Next, another embodiment of the vibration isolation/seismic isolation unit according to the present invention will be described. FIG. 3 is a front view showing another embodiment of the vibration isolation/seismic isolation unit according to the present invention. Figure 3 vibration isolation/
The seismic isolation unit 56 mainly includes rubber 58, 58..., reinforcing plates 60, 60..., a flange 62, and an upper flange 64.
, a lower flange 66, a damping mechanism 70, and the like. Rubbers 58, 58... and reinforcing plates 60, 60...
has a ring shape, and is stacked alternately to form a vibration isolation/seismic isolation unit 56, similar to the vibration isolation/seismic isolation unit 40 shown in Fig. gJ1. A space formed inside the vibration isolation/seismic isolation unit 56 is filled with a viscous liquid 68.

Laminated rubber 58.58... and reinforcing plate 60.60
A flexible metal plate 72A is attached to the inner surface of.... Moreover, an upper flange 64 and a lower flange 66 are installed at the upper and lower parts, respectively.

The damping mechanism 70 includes a viscous liquid 68, a shaft 76, and a resistor 78.
The main structure is The flange 62 is mounted on the upper flange 64 via bolts 74 and 74,
A shaft 76 is attached to the flange 62 from the top to the bottom.

The shaft 76 is threaded, and a tapered resistor 78 is screwed into the lower part of the shaft 76 . By moving in the viscous liquid 68, the resistor 78 receives flow resistance from the viscous liquid 68,
Attenuates the displacement of shaft 76. Further, the resistor 78 has a function as a buckling prevention mechanism, and when the shaft 76 moves up and down beyond the allowable displacement, the receiver formed on the lower flange 66 comes into contact with the portion 66A, and the rubber 58, 58...・Prevents buckling.

The vibration isolation/seismic isolation unit 56 configured as described above is approximately the first
By being used in the same manner as the vibration isolation/seismic isolation unit 40 described in the figure, shaking and vibrations caused by earthquakes, traffic vibrations, etc. are attenuated. This facilitates construction and simplifies the device structure.

In this example, we have explained the case where the target is precision equipment etc. installed in a building, but this is not limited to this example. Seismic isolation devices can also be targeted. Further, although a combination of a viscous liquid and a resistor is used as the damping mechanism, a damping mechanism composed of fine powder or other continuous bodies may also be used.

〔Effect of the invention〕

As explained above, according to the vibration isolation/seismic isolation unit according to the present invention, since the damping mechanism and the rubber buckling prevention mechanism are built into the laminated rubber, a vibration isolation/seismic isolation structure is constructed. Construction and modification can be carried out easily and efficiently. Further, torsional vibration can be prevented without installing a damper, and the structure of the vibration isolation/seismic isolation device can be simplified.

[Brief explanation of drawings]

Fig. 1 is a perspective view showing the structure of a vibration isolation/seismic isolation unit according to the present invention, and Fig. 2 shows a vibration isolation/seismic isolation device constructed using the vibration isolation/seismic isolation unit according to the present invention. Front view shown, 3rd
The figure is a front view showing another embodiment of the vibration isolation/seismic isolation unit according to the present invention, and FIG.
FIG. 5 is a plan view showing a seismic isolation device, FIG. 5 is a front view, and FIGS. 6 and 7 are enlarged views of main parts of a conventional laminated rubber. 32.58... Laminated rubber, 34.60... Reinforcement plate, 40.56... Vibration isolation/seismic isolation unit, 64.36
...Upper flange, 66.38...Lower flange, 42.70...Dampening mechanism.

Claims (2)

[Claims] (1) In a vibration isolation/seismic isolation unit constructed by alternately laminating a plurality of rubber and reinforcing plates between the upper rudder flange and the lower flange, the reinforcing plate has a hole bored in the center. The rubber is supported and laminated at multiple points between the upper flange and the following flange via the plurality of reinforcing plates, and the upper flange is placed in the space formed by laminating the rubber and the reinforcing plate. A vibration isolation/seismic isolation unit characterized in that a damping mechanism is provided to connect a flange and a lower flange, and the damping mechanism is provided with a mechanism for preventing buckling of the rubber. (2) In a vibration isolation/seismic isolation unit configured by alternately laminating a plurality of rubber and reinforcing plates between the upper rudder flange and the lower flange, the reinforcing plates and rubber are formed into a ring shape. A damping mechanism for connecting the upper flange and the lower flange is disposed in a space formed by alternately laminating the reinforcing plate and the rubber, and the damping mechanism is provided with a mechanism for preventing buckling of the rubber. A vibration isolation/seismic isolation unit characterized by: