KR101007694B1 - Lead rubber bearing - Google Patents

Abstract

PURPOSE: A lead rubber bearing is provided to improve the compressive strength, adhesive strength, and elasticity of an elastic plate by using a connection groove formed in a deformation prevention ring. CONSTITUTION: A lead rubber bearing comprises upper and lower plates(10,20), an elastic body(30), a lead bar(L), and deformation prevention rings(40). The elastic body is formed between the upper and lower plates and is composed of multiple elastic plates(31) and metal plates(32). A hollow(33) is formed at the center of the elastic body. The lead bar is inserted into the hollow. The deformation prevention rings are formed between the elastic plates and the metal plates and have multiple connection grooves(H).

Description

Lead rubber bearing

The present invention relates to a lead seismic bearing for attenuating the horizontal / vertical load action, and more particularly, to form a strain relief ring between the elastic plate and the metal plate constituting the elastic body, the gap between the elastic plate and the metal plate as it is Maintains smooth attenuation of vertical loads and improves the seismic isolation characteristics by reducing the hollow portion of the elastic body and the bending amount of the lead rod when the lead rod is injected by the strain-resistant ring when the horizontal load occurs. By improving the adhesion of the elastic plate and the improvement of the compressive strength, and relates to the lead seismic bearing which can improve the elastic force.

In general, the bridge support is formed between the bridge deck and the bridge constituting the bridge, and is installed to prevent safety accidents by attenuating the vibration energy transmitted to the bridge when vertical / horizontal loads occur.

The bridge bearings are formed in various forms. In the case of the elastic bearings, which are commonly used, a large problem does not occur in the vertical load, but when the horizontal load occurs, a large displacement occurs.

On the other hand, the lead seismic support is used to fill the lead inside, by using the non-linearity of the lead filled inside to reduce the vibration energy by reducing the displacement even when a horizontal load occurs.

1 shows a general lead base bearing 1, wherein an elastic body 4 composed of an elastic plate 4a and a metal plate 4b is formed between upper and lower plates 2 and 3, and a hollow portion at an inner center thereof. (4c) is comprised.

In addition, a lead rod L is formed in the hollow portion 4c, and is disposed between the bridge deck and the bridge.

The lead seismic bearing 1 acts to absorb vibration energy through the elastic force of the elastic plate 4a of the elastic body 4 when the vertical load is generated, and the elastic plate of the elastic body 4 when the horizontal load is generated. By using the nonlinearity of (4a) and the lead bar (L) to reduce the displacement amount, it acts to attenuate the amount of vibration energy transmitted to the piers.

However, the conventional lead seismic bearing 1 having the structure as described above is filled with lead in the hollow portion 4c of the elastic body 4 in order to configure to act to attenuate the horizontal subweight through the lead rod L. Filled tightly at the time, should be configured to smoothly perform the seismic isolation action with the elastic plate (4a).

However, when the lead is tightly filled as described above, deformation of the shape does not occur at the position where the metal plate 4b of the elastic body 4 is formed as shown in FIG. 2, but the elastic plate 4a of the elastic plate 4a. (4a) The shape is deformed into an embossed shape by inherent properties.

The occurrence of such deformation causes a gap between the elastic plate 4a and the lead rod L of the elastic body 4 when the lead base bearing 1 receives the horizontal load, and thus the elastic plate 4a and the lead rod L. There was a problem that acts as a barrier to the isolation characteristics due to organic bonding of.

Lead isolation base of the present invention for solving the above problems, the upper and lower plates; An elastic body formed between the upper and lower plates, the elastic body including a plurality of elastic plates made of a rubber material as a whole, and a plurality of metal plates made of a metal material stacked between the elastic plates, and having a hollow formed at an inner center thereof; A lead rod inserted into the hollow portion of the elastic body; It is laminated and disposed between the elastic plate and the metal plate formed on the elastic body, it is made of a hollow shape, the inner diameter is composed of the same diameter as the hollow portion of the elastic body, the deformation preventing ring formed a connecting groove on the inside; do.

The deformation preventing ring of the lead seismic bearing of the present invention is characterized in that it is formed smaller than the thickness of the elastic plate formed between the metal plate of the elastic body.

The method of coupling the strain resistant ring of the lead-proof base bearing of the present invention to an elastic body includes a second elastic plate having a first elastic plate having the same inner diameter as the strain-resistant ring, and then having a second diameter equal to the outer diameter of the strain-proof ring. A second rubber plate having an inner diameter is laminated, and the first elastic plate is laminated in a state in which the first elastic plate is laminated, followed by thermal fusion to bond.

The strain-resistant ring of the lead seismic bearing of the present invention is formed of any one of a metal material and a synthetic resin material, and characterized in that the melting point is higher than that of the elastic plate.

Lead seismic bearing of the present invention forms a deformation preventing ring between the elastic plate and the metal plate constituting the elastic body, while maintaining the gap between the elastic plate and the metal plate while smoothly attenuating the vertical load, by the deformation preventing ring when the horizontal load occurs When the lead rod is injected, the seismic isolation property can be improved by reducing the hollow portion of the elastic body and the amount of bending of the lead rod.

In addition, it is a useful invention that can improve the elastic force as well as improving the adhesive strength and compressive strength of the elastic plate by the connection groove formed in the deformation preventing ring.

1 is a cross-sectional view showing a conventional lead seismic bearing.
Figure 2 is a state diagram showing an elastic body at the time of lead rod filling of the conventional lead seismic bearing.
Figure 3 is a cross-sectional view of the lead seismic bearing according to the present invention.
Figure 4 is a plan view showing a strain relief ring according to the present invention.
Figure 5 is a state diagram showing a combined state of the elastic body and the deformation preventing ring according to the present invention.
Figure 6 is a state diagram showing a state when the horizontal load of the lead seismic bearing according to the present invention.

Hereinafter, the configuration of the present invention with reference to the accompanying drawings in more detail.

As shown in FIG. 3, upper and lower plates 10 and 20 are configured.

An elastic body 30 is formed between the upper and lower plates 10 and 20.

The elastic body 30 is composed of a plurality of elastic plates 31 and a plurality of metal plates 32 are stacked in the vertical direction, the hollow portion 33 is formed in the inner center.

Here, the elastic plate 31 formed between the metal plate 32 is preferably formed to a thickness (t1) to support the vertical load to absorb the vibration.

On the other hand, the hollow portion 33 of the elastic body 30 is filled with a lead rod (L).

The lead rod (L) is to be installed to achieve the same characteristics as the damper of the conventional elastic bearing and intrinsic period using the nonlinearity of lead when the horizontal load occurs, it is preferable to be filled tightly during lead filling.

In addition, the deformation preventing ring 40 is configured between the elastic plate 31 and the metal plate 32 of the elastic body 30.

The deformation preventing ring 40 is formed between the elastic body 30 and the metal plate 32, the inner side is formed in a hollow shape, the inner diameter (D2) of the deformation preventing ring 40 is a hollow portion of the elastic body 30 It is preferable to form the same diameter as (33).

In addition, a plurality of connection grooves (H) is formed inside the strain preventing ring (40).

The connection groove (H) is a plurality of connection grooves (H) are arranged as shown in Figure 4, preferably formed at equal intervals.

In addition, the thickness t2 of the deformation preventing ring 40 is formed to be smaller than the thickness t1 of the elastic plate 31 of the elastic body 30, so that the metal plate 32 and the deformation preventing ring of the elastic body 30 ( 40 is not configured to abut each other, it is preferable that the elastic body 30 is configured to operate so as to attenuate it when a vertical load occurs.

Here, the method of coupling the deformation preventing ring 40 to the elastic body 30, as shown in Figure 5 is the first elastic formed a first inner diameter (d1) the same as the inner diameter (D2) of the deformation preventing ring 40 The inner diameter (D2) of the deformation preventing ring 40 and the first inner diameter (d1) are laminated on the plate (31a) so as to coincide with each other, and the second inner diameter equal to the outer diameter (D1) of the deformation preventing ring (40). After laminating the second elastic plate 31b having the (d2) formed on the upper side of the strain relief ring 40, heat is applied in a state where the first elastic plate 31a is laminated on the upper side of the second elastic plate 31b. It can be added to the bond by thermal fusion.

Of course, as described above, the operation of coupling the deformation preventing ring 40 to the elastic plate 31 of the elastic body 30 is not performed separately during the operation of manufacturing the elastic body 30, the elastic plate 31 and deformation prevention It is preferable to manufacture through heat fusion in a state in which both the ring 40 and the metal plate 32 are laminated.

On the other hand, the deformation preventing ring 40 may be formed of a metal material or synthetic resin-based material, in particular, the melting point of the deformation preventing ring 40 so that the deformation preventing ring 40 does not melt during the heat fusion operation elastic plate ( Naturally, it should be made of material higher than 31).

In addition, a connection groove H is formed inside the metal plate 32.

The connection groove (H) is preferably formed so as to penetrate a plurality, so that the elastic plate 31 formed between the metal plate 32 can be connected to each other.

Looking at the preferred embodiment of the lead seismic bearing of the present invention made as described above are as follows.

Lead isolation base 50 of the present invention is usually installed between the bridge deck and the pier.

Such, lead seismic bearing 50 is to act to minimize the load transmitted to the piers in response to the elastic body 30, when a vertical load occurs.

That is, in the present invention, by forming the separation between the elastic plate 31 and the metal plate 32 of the elastic body 30 in the same manner as before, it is possible to obtain the above-described action and the effect thereof.

On the other hand, when a load of a form that gradually acts over a long period such as a temperature load on a bridge deck, or a horizontal load that acts for a short period such as wind loads, live loads caused by braking of a vehicle, and an earthquake load is transmitted to a bridge by nonlinearity of lead It acts to minimize the load applied.

Looking at this in detail, in the present invention, the deformation preventing ring 40 is configured between the elastic plate 31 and the metal plate 32 constituting the elastic body 30.

When the deformation preventing ring 40 tightly fills the lead rod L in the hollow portion 33 of the elastic body 30, the metal plate 32 portion is maintained in its original state, but elasticity forming an elastic force The plate 31 is pushed to form an embossed curved surface. At this time, when the horizontal load is generated, the curved surface between the elastic plate 31 and the lead rod L of the elastic body 30 is formed. As a result, damping characteristics are weakened, and in particular, as the area amount of the curved surface increases, the damping characteristics become weaker.

However, in the present invention, even though the lead rod L is tightly filled in the hollow portion 33 of the elastic body 30, the bending deformation of the elastic plate 32 by the deformation preventing ring 40 and the lead rod L according thereto. By acting to make a minimum of the surface deflection of the surface area), it is possible to further improve the seismic isolation characteristics by reducing the gap between the hollow portion 33 and the lead bar (L) of the elastic body 30 when the horizontal load occurs.

In addition, even when the vertical load is applied, the deformation preventing ring 40 of the configuration as described above, because the elastic plate 32 of the elastic body 30 acts to reduce the gap generated by pushing, and when the horizontal load Likewise, it will work to improve the isolation characteristics.

Meanwhile, some sections of the elastic plate 31 have discontinuity by the deformation preventing ring 40 formed between the metal plates 32 by the connection grooves H formed in the deformation preventing ring 40. It is configured to be connected to the section, and acts to improve the elastic force with the adhesive force and the compressive strength of the elastic plate 31.

That is, since the deformation preventing ring 40 formed between the metal plate 32 is formed to overlap with the elastic plate 31 and a portion of the metal plate 32, the metal plate 31 and the deformation preventing ring ( The thickness of the elastic plate 31 disposed between the 40 is made thin.

In particular, the elastic plate 31 and the metal plate 32, the deformation preventing ring 940 is made of a different material, that is, of a release material, so as to the thickness of the elastic plate 31 as described above in the section of the adhesive force In addition to the deterioration phenomenon, the deterioration of the elastic force occurs.

In addition, in the general design, the elastic plate 31 and the metal plate 32 are calculated as the effective load interval until the section, the deformation prevention ring 40 is formed, as described above, the deformation prevention ring 40 is Compression stiffness in the formed section is bound to be high.

Accordingly, in the present invention, the adhesive force is improved by connecting the elastic plate 31 partitioned by the strain preventing ring 40 through the plurality of connection grooves H, and the elastic force and the compressive strength by the interconnected elastic plate 31. It will work to improve the.

Of course, the connection groove (H) may be selected in consideration of the weight or other conditions when reflecting the design.

Although the above-described embodiments are described with respect to the most preferred embodiments of the present invention, it is noted that the present invention is not limited thereto and may be modified in various forms without departing from the technical spirit of the present invention.

10: upper plate 20: lower plate
30: elastic body 31: elastic plate
31 a: first elastic plate d1: first elastic plate inner diameter
31b: 2nd elastic plate d2: 2nd elastic plate inner diameter
32: metal plate 33: hollow part
L: Lead rod t1: elastic plate thickness
40: Strain Relief Ring D1: Strain Relief Ring Outer Diameter
D2: Internal strain relief ring t2: Thickness of strain relief ring
H: Connecting groove
50: lead base

Claims (4)

Upper and lower plates 10 and 20;
The plurality of metal plates 32 formed between the upper and lower plates 10 and 20 and made of a plurality of elastic plates 31 made of rubber material and stacked between the elastic plates 31. It includes, the elastic body 30 is formed in the inner hollow portion 33;
A lead rod (L) inserted into the hollow part 33 of the elastic body 30;
It is disposed between the elastic plate 31 formed on the elastic body 30 and the metal plate 32 are laminated and disposed in a hollow shape, the inner diameter (D2) is composed of the same diameter as the hollow portion 33 of the elastic body (30) Lead-proof base is characterized in that consisting of; strain-resistant ring (40) formed a connecting groove (H) on the inside.
The method of claim 1, wherein the deformation preventing ring (40) is a lead seismic bearing characterized in that formed smaller than the thickness (t1) of the elastic plate (31) formed between the metal plate (32) of the elastic body (30).
The method of claim 1, wherein the method of coupling the deformation preventing ring (40) to the elastic body (30) comprises a deformation preventing ring on the first elastic plate (31a) having the same inner diameter (d1) as the deformation preventing ring (40). After stacking the 40, the second rubber plate 12a having the second inner diameter d2 equal to the outer diameter D1 of the deformation preventing ring 40 is laminated, and the first elastic plate 11a is stacked. Lead-based seismic isolator which is characterized by bonding by heat fusion in the state of re-lamination.
According to claim 1, wherein the deformation preventing ring 40 is formed of any one of a metal material, a synthetic resin material, the lead seismic bearing characterized in that the melting point is higher than the elastic plate used.

Images