KR20090071059A - Lead rubber bearing - Google Patents

Abstract

A removable lead rubber bearing with a wedge is provided to improve damper function effectively because the maximum generation displacement of the bridge structure can be smoothly absorbed. A removable lead rubber bearing with a wedge comprises an upper support(1) which includes an elastic member, and a lower support(2) which is integrated in the upper support. The lower support comprises a wedge(4). The upper support comprises a primary elastic member placed between a cover plate(11) and a middle plate(13). The lower support comprises a secondary elastic body(22) arranged between a fastened plate(21) and a lower plate(23). The wedge(41) comprises an upper wedge part which protrudes toward the lower part of the middle plate of the upper support, and a lower wedge(42) which protrudes toward the upper side of the lower plate and contacts the upper wedge.

Description

Lead-free seismic bearing with wedges

The present invention relates to a lead seismic bearing, and more specifically, to the stability of the initial and secondary stiffness in the constant and design earthquake to achieve stability and to the maximum seismic level of more than 150% shear strain in the existing seismic isolator The present invention relates to a removable lead isolation bearing with a wedge that can maintain the durability of the isolation function without damaging the device by preventing additional load from occurring at the same level as the response to the design earthquake.

In general, there has been no consideration of horizontal forces such as seismic forces except wind loads in the design of bridge structures. However, in recent years, the seismic design of bridge structures using bridge bearings is a breakthrough design technology that can satisfy both sides of bridge economy and safety. As it is important.

In general, low-rise buildings with short natural periods are destroyed by earthquake resonance and high-rise buildings with relatively long periods of earthquake are relatively safe due to their short and long periods. This is big.

The seismic isolating design is to make the natural period of the structure longer so that the vibrational energy of the ground does not propagate greatly to the structure. The seismic isolating structure uses the characteristics of the earthquake movement to artificially lengthen the natural period of the structure to increase the response of the structure to the earthquake. It refers to a structure with a significantly reduced seismic design.

In other words, low-rise buildings cannot extend their natural periods by inserting a seismic isolation device such as laminated rubber into the ground and building connections. It shows the buckling phenomenon against dead load, so the reinforcing steel plate is installed horizontally between the rubber and the rubber so that it can withstand the vertical load stably and maintain the flexibility of the rubber against the horizontal load. The base is in practical use.

However, the disadvantage of the elastic bearing is that displacement is largely generated with respect to the horizontal load. As a method of reducing such displacement, a method of absorbing vibration energy by using a viscous damper proportional to speed or by using a non-linear behavior of a metal body may be used. It is widely used. The lead bearing is a kind of isolating bearing that tries to reduce the magnitude of seismic force induced on the upper structure by lengthening the intrinsic period of the upper structure like the elastic bearing. It is an energy absorber and inserts core-shaped lead into the elastic bearing. Therefore, the characteristics of the damper using the nonlinearity of the metal and the long period of the natural period are simplified in one device.

FIG. 4 is a perspective view illustrating a soldering base support in general. An elastic rubber layer 101 having a hollow portion and a reinforcing plate 102 are alternately stacked, and an elastic body 100 having a lead rod 103 forcedly pressed into the hollow portion. It is composed of the lead rod 103 by the earthquake load absorbs the vibration energy while plastic deformation. In addition, the elastic body 100 is integrally formed by fastening the upper plate 120 and the lower plate 130 with bolts to the connecting steel sheets 110 and 110a provided at the upper and lower ends of the laminate.

In the case of the earthquake-resistant earthquake bearing configured in this way, the elastic rubber layer 101 shears and insulates the earthquake motion in the event of an earthquake, and after the vibration is completed, it has a function of restoring to the original position by the elastic recovery force possessed by the elastic rubber layer 101, and also the wind load. With respect to the micro vibration as described above, the initial horizontal stiffness of the lead rod 103 is to be able to resist the vibration.

In addition, the vibration energy in the relative horizontal direction between the upper structure and the base is dissipated by the plastic deformation of the lead rod 103, thereby reducing the vibration acceleration of the upper structure.

As such, the conventional lead-free earthquake bearings can fully function without damage at the level of constant and earthquake-based earthquake (DBE), but in terms of stiffness at the maximum earthquake (MCE) level of 150% or more strain. There was a problem that the seismic isolation function is lost due to the breakdown of the device, such as hardening, rubber penetration of the lead rod, overturning.

Therefore, the present invention was devised to solve the conventional problems as described above, and its purpose is to achieve stability by acting with greater initial stiffness and secondary stiffness at constant and design earthquakes, and to achieve a maximum earthquake level of 150% or more strain. In this regard, the additional load does not occur at the same level as the response to the design earthquake, so that the seismic function can be maintained without damaging the device.

In order to achieve the object of the present invention, the upper support and the lower support including the elastic body is integrally formed, and the lower support is provided with a detachable lead-free base bearing having a wedge, further comprising a wedge.

In addition, the upper support is configured to include a first elastic body between the upper plate and the intermediate plate; The lower support comprises a second elastic body between the fixed plate and the lower plate coupled to the intermediate plate of the upper support; The wedge portion is characterized by consisting of the upper wedge protruding to the lower side of the middle plate of the upper support and the lower wedge protruding to the upper side of the lower plate in contact with the side of the upper wedge.

In addition, an assembly groove having a shape corresponding to the fixing plate of the lower support is formed on the lower surface of the intermediate plate of the lower support is characterized in that the fixing plate of the lower support is configured to be inserted into the assembly groove.

In addition, the assembly groove of the intermediate plate includes a plurality of protrusion grooves on the outside, the fixing plate of the lower support is formed in a shape corresponding to the protrusion groove portion includes a plurality of protrusions inserted into the protrusion groove, the protrusion portion Characterized in that configured to be fixed to the protrusion groove by the upper wedge provided in the fixing plate of the lower support.

As described above, the present invention achieves stability by operating with greater initial stiffness and secondary stiffness at all times and in design earthquake, and the same level of response as design earthquake for the maximum earthquake level exceeding 150% of shear strain in the existing seismic isolator. By not causing additional loads, it is possible to maintain the continuity of the seismic isolation function without damaging the device, and thus not to cause excessive load on the structure, so that it can effectively function as a damper and absorb the maximum generated displacement of the bridge structure effectively. There is an advantage to that.

Hereinafter, with reference to the accompanying drawings, the configuration of the lead-free earthenware support according to the present invention will be described in detail according to the embodiment.

1 is an exploded perspective view showing the overall configuration of the present invention, Figure 2 is a longitudinal cross-sectional view of FIG.

As shown therein, the present invention is characterized in that the upper support 1 and the lower support 2 including the elastic body are integrally formed with each other, and the wedge portion 4 is formed in the lower support 2. .

That is, the upper support (1) and the lower support (2) is formed as a lamination layer of the elastic rubber layer and the reinforcement plate alternately stacked with each other, and the lead surface bearing support having an elastic body in which a lead rod is forcibly pressed in the central portion of the elastic rubber layer and the reinforcement plate, The base support consists of two stages up and down and the wedge portion 4 is formed on the lower support (2).

In more detail, the upper support 1 includes a first rubber layer 12a, a reinforcement plate 12b, and a lead rod 12c between the upper plate 11 and the intermediate plate 13. An elastic body 12 is formed, and the lower support 2 includes a elastic rubber layer 22a, a reinforcing plate 22b, and a lead rod 22c between the fixing plate 21 and the lower plate 23. As the elastic body 22 is formed, the fixing plate 21 of the lower support 2 is integrally coupled to the middle plate 13 of the upper support 1.

To this end, an assembly groove 3 into which the fixing plate 21 of the lower support 2 is inserted is formed on the lower surface of the intermediate plate 13 of the upper support 1, and the assembly of the intermediate plate 13 is formed. A plurality of protrusions outside the assembly groove 3 of the intermediate plate 13 to fix the fixing plate 21 of the lower support 2 inserted into the groove 3 to the intermediate plate 13 of the upper support 1. The groove part 30 is successively formed, and a plurality of protrusion parts 21a inserted into the protrusion groove part 30 of the assembly groove 3 are formed outside the fixing plate 21.

Here, the assembly groove 3 of the intermediate plate 13 and the fixing plate 21 of the lower support 2 is formed in a circular shape, but is not limited to the shape, the projection groove portion 30 of the assembly groove (3) ) And the protrusion 21a of the fixing plate 21 are formed at equal intervals of 90 degrees by using the wedge portion 4 formed on the lower support 2 without a separate fixing means, the protrusion 21a of the fixing plate 21. ) Is to fix the protruding groove portion 30 of the assembly groove (3).

In more detail, the wedge 4 has an upper wedge 41 protruding downward from the middle plate 13 of the upper support 1, and a lower plate 23 in contact with the side surface of the upper wedge 41. It consists of a lower wedge (42) protruding to the upper side of the), wherein the upper wedge (41) to block the protrusion (21a) of the fixing plate 21 inserted into the protrusion groove portion 30 of the assembly groove (3) The fixing plate 21 is to prevent the separation from the intermediate plate 13 of the upper support (1).

According to the present invention configured as described above, the upper and lower base isolation bearings, that is, the upper and lower bearings (1) and (2), as shown in FIG. Regarding the earthquake load of the design earthquake level which resists the large initial stiffness by 22c and surpasses the wind load, as shown in FIG. 3b, the lead rod 12c of the upper support 1 is completely surrendered, resulting in long periods of rubber As a result, the vibrational energy of the bridge deck is absorbed into the nonlinear behavior of the lead rod 12c while reducing the induction of seismic force, thereby suppressing the vibration displacement.

In addition, at the maximum earthquake load of 150% or more of strain of the seismic bearing, the vibration displacement is further suppressed by the deformation of the lower support 2 together with the function of the upper support 1 as described above as shown in FIG. 3C. It is possible to reduce the strain rate of lead seismic bearings to near the design earthquake level.

More specifically, in the maximum earthquake, first, the upper support 1 absorbs vibration energy due to plastic deformation of the lead rod 12c and shear deformation of the elastic rubber layer 12a with respect to the horizontal load.

Then, as the wedge portion 4 of the lower support 2 breaks, the lead rod 22c of the lower support 2 also causes plastic deformation to absorb vibration energy and at the same time displace the elastic rubber layer 22a with respect to the horizontal load. Since the long period is achieved, the upper and lower lead-free earthquake bearings are combined with the upper and lower lead-free earthquake bearings even at the maximum earthquake level of 150% or more without additional load as shown in FIG. This can be lowered, so that the local or overall defects of the naphtha bearings do not occur in a condition that the seismic bearings can behave more stably.

That is, as shown in FIG. 5, in the constant earthquake and the design earthquake, the initial stiffness and the secondary stiffness behave more stably, and even if the maximum deformation occurs, the response level does not generate additional load at the same level as the response during the design earthquake. It will not be.

1 is an exploded perspective view showing the overall configuration of the present invention.

2 is a longitudinal cross-sectional view of FIG.

3a to 3c are cross-sectional views showing the operating state of the present invention.

Figure 4 is a perspective view showing a conventional napjinjin bearing.

5 is a graph showing the relationship between force and displacement during the earthquake.

* Explanation of symbols for main parts of the drawings

1: upper support 2: lower support

3: Assembly groove 4: Wedge

11: Upper plate 12, 22: 1st, 2nd elastic body

12a, 22a: elastic rubber layer 12b, 22b: reinforcing plate

12c, 22c: sealed: middle plate

21: fixing plate 21a: protrusion

23: lower plate 30: protrusion groove

41: upper wedge 42: lower wedge

Claims (4)

The upper support (1) and the lower support (2) comprising an elastic body is formed integrally, the lower support (2) is a detachable lead-free base bearing with a wedge, characterized in that it further comprises a wedge (4). The method of claim 1, The upper support (1) comprises a first elastic body (12) between the upper plate (11) and the intermediate plate (13); The lower support (2) comprises a second elastic body (22) between the lower plate (23) and the fixed plate (21) coupled to the intermediate plate (13) of the upper support (1); The wedge part 4 is a lower wedge which protrudes toward the upper side of the upper plate 41 and the lower plate 23 protruding toward the lower side of the middle plate 13 of the upper support 1 in contact with the side of the upper wedge 41. Separable lead napjin bearing having a wedge, characterized in that consisting of (42). The method of claim 2, An assembly groove 3 having a shape corresponding to the fixing plate 21 of the lower support 2 is formed on the lower surface of the intermediate plate 13 of the lower support 2 so as to receive the lower support in the assembly groove 3. Separable lead napjin bearing having a wedge, characterized in that the fixing plate 21 of the needle (2) is configured to be inserted and fixed. The method of claim 3, The assembly groove 3 of the intermediate plate 13 includes a plurality of protrusion grooves 30 on the outer side, and the fixing plate 21 of the lower support 2 is formed in a shape corresponding to the protrusion groove 30. And a plurality of protrusions 21a inserted into the protruding grooves 30, and the protrusions 21a are protruding grooves 30 by an upper wedge 41 provided on the fixing plate 21 of the lower support 2. Separable lead surface bearing with wedge portion, characterized in that configured to be fixed to).

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