JPH01244081A - Suspension type vibration control device of structure - Google Patents

Abstract

PURPOSE:To change vibration characteristics into non-linear ones and to avoid a resonance phenomenon by inserting a horizontal cushion material between the perimeter of an anchor plate fixed to a structure and a stopping section erected to the periphery of a base. CONSTITUTION:A part of a structure (S) is suspended from a bearing bridge structure arranged to the upper part of the structure (S) through a suspension material (B), the period of vibration allover the structure (S) is periodically extended, and a suspension type vibrator is so constituted that horizontal response acceleration against outer vibration can be reduced. The horizontal displacement of the suspension material (B) for a part of the structure (S) is limited by a displacement control mechanism, and an energy consumption therefor is brought about. The displacement control mechanism is constituted of an anchor plate 2 bridged to a hanging root of the suspension material (B), a base 4 supporting the anchor plate 2 fixed to the structure (S) so that it is capable of sliding in the horizontal direction, and a horizontal cushion material 6 inserted and loaded into surfaces opposite to the base 4 and anchor plate 2.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a suspension-type vibration damping device that reduces horizontal vibration acceleration acting on a structure.

(Prior art) Conventional suspension-type vibration damping devices lengthen the vibration period of the entire structure by suspending a part of the structure, such as the floor, from a support frame via a suspension material, thereby reducing the vibration disturbance. This reduces horizontal response acceleration.

This is an application of the principle of a pendulum, and its period is proportional to the length of the pendulum, that is, the square root of the length of the suspension material.

(Problems to be Solved by the Invention) In the conventional suspension-type vibration damping device, since the hanging length of the suspension material corresponding to the camera part is constant,
It has a specific natural period, and therefore there is a risk that large vibrations may occur due to resonance phenomena, leading to damage.

A damper may also be used to suppress the response, but as long as the basic natural vibration characteristics remain unchanged,
Response suppression effect is not sufficient.

The present invention has been proposed in view of the problems of the prior art, and its purpose is to nonlinearly change the vibration characteristics of the suspension material according to the magnitude of the vibration displacement of the suspension material, thereby reducing resonance. The object of the present invention is to provide a suspension type vibration damping device for a structure that avoids this phenomenon.

(Means for Solving the Problems) In order to achieve the above object, a suspension type vibration damping device for a structure according to the present invention limits the horizontal displacement of the suspension material to a part of the structure, and It is constructed with a displacement control mechanism that causes energy consumption of the material.

The present invention also provides, in the suspended ceiling of the suspension material, in order to control the horizontal displacement of the suspension material, the displacement control mechanism is connected to a fixing plate mounted on the suspended ceiling of the suspension material, and a fixing plate fixed to a structure. It is composed of a base that is slidably supported in the horizontal direction, and a horizontal cushion material that is interposed between the base and the opposing surface of the fixing plate.

In order to control the horizontal displacement of the same village in the longitudinal middle part of the suspension member, the present invention also provides the displacement control mechanism in the longitudinal middle part of the suspension member.
A horizontal frame member is fixed to the structure and surrounds the suspension member with a certain clearance.

Furthermore, the present invention provides, at the tip of the suspension material,
In order to control the horizontal displacement of the village, a movable structure suspended from the lower end of the suspension member and a part of the horizontal plate protruding from the structure are slidably connected to the street, and one plate is A friction-type displacement control mechanism is provided in which the implanted bolt is dynamically inserted into the slot of the other plate.

Furthermore, the present invention provides a movable structure suspended from the lower end of the suspension material and a portion of a horizontal plate movable relative to the structure, in order to control the horizontal displacement of the suspension material at the tip end of the suspension material. A stopper-type displacement control mechanism is provided by protruding from the other plate and inserting a cushioned stopper implanted from the other plate into a through hole with clearance. .

(Function) Since the suspension type vibration damping device according to the present invention is configured as described above, the horizontal displacement of the suspension member is controlled to a required magnitude by the displacement control mechanism provided in a part of the structure. The vibration characteristics of the suspension material are changed non-linearly depending on the magnitude of the vibration displacement of the suspension material, and resonance phenomena are avoided and vibrations are reduced.

According to the invention of claim 2, when the amplitude of the suspension material increases and the horizontal force acting on the suspended ceiling exceeds a certain limit,
A fixing plate mounted on the suspension slides on a base fixed to the structure and presses a horizontal cushion material interposed between the fixing plate and the base, thereby improving the vibration characteristics of the structure. change.

According to the invention of claim 3, when the amplitude of the suspension material exceeds a certain limit, the middle part of the suspension material comes into contact with the inner part of the frame fixed to the structure, and the contact part is used as a fulcrum. This causes vibrations that change the vibration characteristics of the structure.

According to the invention of claim 4, the movable structure suspended at the tip of the suspension shrine and some of the plates protruding from the structure, respectively, are connected to the bolts protruding from one plate and the other plate. The amount of horizontal displacement of the suspension material is controlled by the frictional resistance that occurs when it slides with the grooves as a guide, and the vibration characteristics of the structure change.

According to the invention of claim 5, the movable structure suspended from the tip of the suspension material and some of the plates respectively protruding from the structure include a cushioning material planted from one of the plates. The vibration characteristics of the structure change depending on the resistance when the stopper slides inside the hole in the other plate and collides with the edge of the hole.

(Example) The present invention will be described below with reference to the illustrated embodiments.

1 to 3 show a first embodiment of the present invention, (A
) is the upper support frame of the structure (S), and the same support frame (A
) The upper end of the suspension material (B) made of a PC steel material or the like passes through the through hole (1) of the steel fixing plate (2),
It is fixed by the fixing device (3), and the fixing plate (2) is attached to the support frame (
A) It is slidably loaded on a sliding material (5) made of a tetrafluoride resin plate layered on the upper surface of a steel base (4) fixed thereon, and is placed around the fixing plate (2). , the base (4
) A horizontal cushioning material (6) made of synthetic rubber is interposed between the locking portion (4a) and the locking portion (4a) erected on the outer periphery of the cushion member (6).

In the figure, (C) is a movable structure such as a floor suspended from the tip of the suspension member (B).

Since the illustrated embodiment is configured as described above, when the horizontal amplitude of the suspension material (B) is small, the fixing plate (2) maintains its original position, but when the amplitude becomes large, the fixing plate (2) moves to the suspension material CB). The horizontal force acting becomes larger,
The fixing plate (2) slides on the sliding material (5) of the base (4).

At this time, the fixing plate (2) has a cushioning material (6) around it.
Since the spring is compressed, a hard spring-type restoring force can be obtained.

The nonlinear restoring force characteristics in the horizontal direction at the tip of the suspension material are as shown in FIG. 4, and such nonlinearity prevents resonance and provides a large damping effect.

In addition, in FIG. 4, δ1. δ2 is the displacement at the start of sliding and the maximum sliding displacement of the fixing plate (2), respectively, and Ql is the displacement of the fixing plate (2) at the start of sliding.
2), the horizontal force at the start of sliding, Q2 is the horizontal force at the maximum sliding displacement of the fixing plate (2), and in the warm state, the suspension member (B) is rotating by the movable structure (C). can be,
The fixing plate (2) does not slide. Furthermore, between i, the horizontal force acting on the anchoring part of the suspension material (B) exceeds a certain limit,
The fixing plate (2) is in a sliding state.

5 and 6 show a second embodiment of the present invention, in which the longitudinal intermediate portion of the suspension material (B) is connected to the structure (S).
A certain clearance (8) is attached to the horizontal frame (7) fixed to the
) and is surrounded by

In the figure, parts equivalent to those of the above embodiment are given the same reference numerals.

Since the illustrated embodiment is configured as described above, when the horizontal amplitude of the suspension member (B) is equal to or less than the clearance (8) between the suspension member (B) and the horizontal frame member (7),
The suspension member (B) vibrates without any restraint from the horizontal frame member (7).

When the amplitude of the suspension material (B) reaches the limit of the clearance (8), no further displacement occurs, and the vibration is centered at the point where it collides with the inner peripheral edge of the horizontal frame material (7). Changes to

The nonlinear restoring characteristics at the tip of the suspension material (B) are as shown in Figure 7, and δ1 is the suspension material (B).
, Ql is the horizontal force at this time, and δ2 is the suspension material (
The maximum displacement of B), Q2 is the horizontal force at this time,
Between i, suspension material (B) is placed within the horizontal frame material (7).
) rotates. After the force applied to the suspension member (B) exceeds a certain limit Q, the suspension member ([1)] moves between - and uses the collision part with the inner peripheral edge of the horizontal frame member (3) as a fulcrum. While rotating and preventing the resonance phenomenon of the structure,
A great damping effect is achieved.

Figures 8 to 1O show a third embodiment of the present invention, in which a movable structure (C) is suspended from the support frame (^) via a suspension member (B) to the lower end of the same village (B). A part of the horizontal play 1- (9100) is protruded from the end of the structure (S), and is slidably polymerized. It is slidably fitted into the slot (9a) of 9).

Since the illustrated embodiment is constructed as described above, when the horizontal force reaches the frictional force between the plates (9) GO), the (9a) as a guide, and the frictional force at that time causes a large amount of energy to be consumed due to the nonlinear restoring force characteristics shown in Figure ti, which prevents resonance of the structure and reduces the amplitude. Ru.

The clearance between them can be adjusted by adjusting the diameter of the bolt θ0 and the width of the slot (9a), and by adjusting the tightening force of the bolt (11), the clearance of the plate (9)001 can be adjusted. The horizontal force at the start of sliding can be changed, and thus the restoring force characteristics can be adjusted freely.

In FIG. 11, no sliding occurs between some of the plates (91Go) between i and the same pair of plates (9) Qω are in a sliding state between 2.

12 and 13 show a fourth embodiment of the present invention,
The stopper (11') planted from the plate 0IID protruding from the structure (S) is attached to the suspension material (
It is inserted into the through hole (9b) of the plate (9) protruding from the movable structure (C) suspended from the lower end of B) with a clearance, and the outer peripheral surface is covered with cushioning material OZ. ing.

Since the illustrated embodiment is configured as described above, the horizontal displacement of the suspension material ([l) reaches the limit of the clearance between the suspension material (B) and the transparent 7L (9b) of the plate (9). Then, depending on the behavior of the elastic region and the elastic region of the stopper (11') and the cushion material 02+, a restoring force characteristic as shown in FIG. 14 can be obtained. Such nonlinear restoring characteristics prevent resonance of the structure and reduce the amplitude.

In the above embodiment, the size of the clearance between the stopper (11') or the cushion material and the peripheral plate (9), the dimensions of the stopper (11'), the bending length,
The restoring force characteristics can be adjusted freely depending on the material, thickness, etc. of the cushion material.

In Figure 14, in Kinutama, play) (9) i3 hole (9
The suspension material (B) rotates within the clearance between b) and the stopper (11'), and the displacement of the suspension material (B) reaches the limit of the clearance between the two.
The stopper (11'') is in an elastic-plastic behavior state, and the stopper (11') further deforms between C.

(Effect of the invention) In the suspension-type vibration damping device for a structure according to the present invention, a part of the structure is suspended from the upper part of the structure by a displacement control mechanism provided in the part of the structure. The horizontal displacement of the suspension material in the suspension material is limited to the required size, and the vibration characteristics of the suspension material are nonlinearly changed according to the magnitude of the vibration displacement of the suspension material, thereby avoiding resonance of the structure and damping the vibration. This is to prevent damage to things.

The invention according to claim 2 provides the displacement control mechanism with a fixing plate mounted on a hanging ceiling of a suspension member, a base fixed to a structure side that slides the fixing plate in a horizontal direction, and the base and the fixing plate. The suspension material has a larger amplitude due to the cushioning material interposed between the suspension material and the suspension material.
When the horizontal force acting on the suspended ceiling exceeds a certain limit, the fixing plate slides, changing the vibration characteristics of the structure, avoiding resonance, damping vibrations, and preventing damage to the structure. .

The invention of claim 3 is based on the displacement system? By configuring the nJa structure by fixing a horizontal frame member that surrounds the suspension material with a certain clearance to the structure at the midpoint in the longitudinal direction of the suspension material, the suspension material does not exceed the amplitude limit. In this case, the structure changes the vibration characteristics of the structure by making a pendulum movement using the portion that contacts the inner peripheral edge of the horizontal frame as a fulcrum, thereby avoiding resonance, damping the vibration, and preventing damage.

The invention according to claim 4 includes a movable structure suspended from the lower end of the suspension member, and a part of the horizontal plate protruding from the structure, slidably abutting each other, and being planted from one plate. slidingly insert the bolt into the other slot,
The vibration characteristics of the structure are changed by the frictional resistance generated between the plates depending on the amount of displacement of the suspension material, thereby avoiding resonance, damping vibration, and preventing damage.

Furthermore, in the invention of claim 5, a movable structure suspended from the lower end of the suspension member and a part of horizontal plate movable relative to the structure are provided protrudingly, and a through hole provided in one plate is provided with a movable structure suspended from the lower end of the suspension member. A stopper with a cushion material planted from the plate is inserted with a clearance to constitute a displacement control mechanism, and when the amount of displacement of the suspension material exceeds the limit of the clearance, the vibration characteristics of the structure are changed. This is to avoid the resonance phenomenon, reduce the amplitude, and prevent I-damage.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view showing a first embodiment of the suspension type vibration damping device for structures according to the present invention, FIG. 2 is a partially enlarged view thereof, FIG. 3 is a plan view thereof, and FIG. A chart showing the nonlinear restoring force characteristics, FIG. 5 is a vertical cross-sectional view showing the second embodiment of the present invention, FIG. 6 is a view taken along arrow Vl-VI in FIG. 5, and FIG. 7 is the nonlinear restoring force characteristics. FIG. 8 is a front view showing the third embodiment of the present invention, FIG. 9 is an enlarged plan view of the main part thereof, FIG. 10 is a view taken along arrow XX in FIG. 9, and FIG. is a diagram showing the nonlinear restoring force characteristics, and FIG. 12 is the fourth diagram of the present invention.
FIG. 13 is a longitudinal sectional view showing the main part of the embodiment, FIG. 13 is a cross-sectional view taken along the arrow in FIG. 12, and FIG. 14 is a chart showing the nonlinear restoring force characteristics. (A) -4 supporting frame (B) - Suspension material (C
)~Movable structure (2)-Fixing plate (41-Base
(5) - Sliding material (6) --- Cushioning material (7)
...Horizontal frame material (9)--Horizontal play) (9a)-
...Groove (9b) - Through hole 0ω - - Horizontal plate (11) - Bolt (11') - Stopper 0 Ku Cushion material agent Patent attorney Shige Okamoto 2 people outside the text 1 figure 2 marks 3 Ward A4 figure A5 prisoner A7 figure 謬ej flash A6 figure) fs/2 flash

Claims (5)

[Claims] (1) A part of the structure is suspended from a support frame installed at the top of the structure via a suspension material to lengthen the vibration period of the entire structure and reduce the horizontal response acceleration to vibration disturbances. In the suspension type vibration damping device for a structure configured as above, a displacement control mechanism is provided in a part of the structure to limit horizontal displacement of the suspension material and to cause energy consumption of the suspension material. A suspension-type vibration damping device for structures characterized by: (2) The displacement control mechanism includes a fixing plate mounted on the hanging base of the suspension material, a base fixed to a structure and supporting the fixing plate slidably in a horizontal direction, and a connection between the base and the fixing plate. 2. A suspension-type vibration damping device for a structure according to claim 1, comprising a horizontal cushioning material interposed on opposing surfaces of the structure. (3) The displacement control mechanism is constituted by a horizontal frame member fixed to the structure at a longitudinally intermediate portion of the suspension member and surrounding the suspension member with a certain clearance. Suspension damping device for structures. (4) The displacement control mechanism slidably collides a movable structure suspended from the lower end of the suspension member and a part of the horizontal plate protruding from the structure, and implants the movable structure from one plate. 2. The suspension type vibration damping device for a structure according to claim 1, wherein said bolt is slidably inserted into a slot in the other plate. (5) The displacement control mechanism includes a movable structure suspended from the lower end of the suspension member and a portion of a horizontal plate that is movable relative to the structure, and includes a through hole provided in one of the plates. 2. The suspension-type vibration damping device for a structure according to claim 1, wherein a stopper with a cushioning material embedded from the other plate is inserted with a clearance.