KR20020095271A - Bridge having elasticity-slide base - Google Patents

Abstract

PURPOSE: An elastic slide bearing device of a bridge is provided to endure external force by absorbing horizontal force and vertical force. CONSTITUTION: The elastic slide bearing device of a bridge contains a bearing(5) installed on a pier(2) to support a floor slab(1) for absorbing horizontal, vertical force transferred to the floor slab(1). Wherein the bearing(5) comprises: an elastic bearing(3) provided with a pad(12) made of compressive rubber materials and a gusset plate(11) interposed in the pad(12) to place an upper plate(14) upward and a lower plate(20) downward; and a shock absorber(4) provided with a cylinder filled up with fluids, a piston connected to the side of the pad(12) to support the side of the pad(12) and a fixing shaft(18) to fix the cylinder to a fixed plate(6).

Description

Elastic slide support device of bridge {BRIDGE HAVING ELASTICITY-SLIDE BASE}

The present invention relates to an elastic slide support device for a bridge, and more particularly, to an elastic slide support device for a bridge to absorb the horizontal force and the vertical force to withstand external shock by combining the elastic support portion and the buffer unit integrally.

In general, a bridge includes a top plate that a vehicle or a person can pass, a plurality of piers supporting the top plate, and a bridge device mounted between the top plate and the piers to absorb shock and displacement.

The bridge is designed to withstand deformation loads by transmitting shock when a vehicle passes or an earthquake occurs. In particular, in recent years, seismic isolation and seismic preparation devices for earthquakes have been developed and installed in bridges.

These seismic and seismic isolation legs are the upper plate is mounted by a plurality of pier, and is supported by the bridge device in each pier. The bridge having such a structure has a structure in which the top plate is fixed by one of the plurality of bridge piers, and is not fixed to the other piers by the bridge arrangement. Therefore, when the horizontal force acts on the legs, the horizontal force is transmitted to another piers around the piers where the top plate is fixed, thereby pushing in one horizontal direction. At this time, since the bottom of the upper plate is in sliding contact with the upper surface of the chair, the chair is inclined to absorb the horizontal force.

As shown in FIG. 1, the bridge apparatus includes an elastic support member 52 having an appropriate elastic force, and the elastic support member 52 is installed on an upper portion of the bridge 51 to form an upper plate 50 of the bridge. Will be supported. The elastic support member 52 is made of compressed rubber having a predetermined elastic force, and has a shape in which a plurality of reinforcing plates are formed in a layer therein.

Therefore, when the elastic force member 52 is a vertical force is applied, the compression rubber is contracted to absorb the vertical force.

In addition, when the upper plate 50 is slid in the horizontal direction, the bottom surface of the upper plate 50 and the upper surface of the elastic support member 52 is in frictional contact, and the weight of the upper plate 50 is in the vertical direction. It is working. Thus, the elastic support member 52 is inclined in an oblique direction to absorb the horizontal force. At this time, since the shearing force is generated in the elastic support member 52, when the inclination is more than a predetermined angle, cracks are generated and the elastic support member 52 is damaged. In general, failure occurs when the shear strain is 70% or more of the effective compressive rubber thickness.

And, the horizontal force transmitted to each of the elastic support member 52, the greater the horizontal force acts as the top plate 50 is far away from the fixed piers 51. That is, as the upper plate 50 is farther from the fixed piers 51, the shear strain of the elastic support member 52 also becomes larger.

As a result, each bridge device installed in a plurality of bridge piers should design the size of the elastic support, the amount of elastic rubber deformation, the shear modulus of elasticity, the compression spring modulus, the shear spring modulus, etc. according to the horizontal and vertical forces caused by the working load. Therefore, when the bridge is applied by applying such a device, the construction period and the construction cost of the bridge increases, and there is a problem in that it takes a long design time.

An object of the present invention is devised to solve the above-mentioned problems, and is provided to each of the piers by having an elastic support unit and a shock absorber integrally provided, and by installing the elastic sliding support device having the same specification in each of the plurality of piers, An elastic sliding support device capable of absorbing horizontal and vertical forces is provided.

1 is a side view showing the elastic support of the conventional bridge.

Figure 2 is a side view showing a state in which the elastic slide support device mounted on the bridge according to an embodiment of the present invention.

Figure 3 is a side view showing the guide portion of the elastic slide support device shown in FIG.

4 is a plan view of the elastic slide support device shown in FIG.

Figure 5 is a side view showing a state in which the elastic slide support according to another embodiment of the present invention mounted on the bridge.

Figure 6 is a side view showing the guide portion of the elastic slide support device shown in FIG.

FIG. 7 is a plan view of the elastic slide support device shown in FIG. 5; FIG.

In order to realize the object of the present invention, a preferred embodiment of the present invention includes a lower plate mounted on the upper portion of the piers; An upper plate integrally mounted to a lower portion of the upper plate; An elastic part mounted between the upper and lower plates to absorb the vertical force by supporting the upper plate; It provides an elastic slide support of the leg including a buffer for absorbing the horizontal force by connecting the elastic portion and the top plate.

According to a preferred embodiment of the present invention, the elastic portion is a pad having an elastic force, at least one reinforcement plate mounted inside the pad, and is mounted on the upper surface of the pad and the guide jaw is formed protruding from the top It includes a bearing consisting of a flat plate slidably coupled to the guide groove formed on the bottom of the top plate.

The elastic part is a pad having elastic force, at least one reinforcing plate mounted inside the pad, and a guide jaw protrudingly formed on an upper surface of the pad and protruding from the upper surface of the pad to slide in a guide groove formed on the bottom of the upper plate. And a pair of lower wedges protruding downward from the bottom of the upper plate, and a pair of upper wedges protruding upward from the upper surface of the lower plate.

A fluororesin plate is attached to the upper surface of the flat plate around the guide groove, and a stainless steel plate is attached to the bottom of the upper plate to make sliding contact with each other.

The buffer unit has a space formed therein, the cylinder is filled with fluid, the cylinder is movably mounted inside the cylinder and one side is connected to the side of the pad to support the side of the pad and the cylinder is fixed It includes a fixed shaft.

Hereinafter, with reference to the accompanying drawings will be described in detail the elastic slide support of the leg according to an embodiment of the present invention.

As shown in Figures 2 to 4, the elastic slide support device disclosed in the present invention includes a bearing (5) of the LRB method, such a bearing (5) is installed on the top of the piers (2) and the upper plate (1) ) Absorbs the horizontal and vertical forces transmitted from the upper plate (1).

The bearing (5) is installed between the upper plate (1) and the piers (2) to absorb the vertical force, the elastic bearing portion (3), and the horizontal force by connecting the elastic bearing portion (3) and the upper plate (1) It includes a buffer (4) for absorbing.

The elastic support portion 3 includes a pad 12 of a compressed rubber material having a predetermined elastic force, and a reinforcement plate 11 formed in a multilayer is embedded in the pad 12. In addition, an upper plate 14 in which the guide groove 15 is formed is positioned at an upper portion of the pad 12, and the upper plate 14 is fixed to the fixing plate 6 attached to the bottom surface of the upper plate 1. .

A flat plate 7 is integrally formed on the pad 12, and the guide jaw 13 protrudes upward from the middle of the flat plate 7. The guide jaw 13 is slidably coupled to the inside of the guide groove 15 of the upper plate 14. Therefore, when the pad 12 is deformed in the horizontal direction by the horizontal force, the guide jaw 13 slides along the guide groove 15.

The lower plate 20 is integrally mounted to the lower portion of the pad 12, and the lower plate 20 is fixed to the support plate 8 by a fixing screw 10. The support plate 8 is fixed by being anchored in the interior of the piers 2 through the anchor bolt 9 through the support plate 8. Therefore, the pad 12 is integrally fixed to the upper portion of the piers 2 by the lower plate 20 and the anchor bolt (9).

On the other hand, the buffer part 4 is to absorb the horizontal force transmitted to the elastic support by the hydraulic method, and includes a viscous damper. The buffer part 4 has a space formed therein so that the cylinder 16 is filled with fluid, and is movably mounted in the cylinder 16, and one side 19 is provided at the side of the pad 12. It is connected to include a piston 17 for supporting the side of the pad 12, and a fixed shaft 18 for fixing the cylinder 16 to the fixed plate.

Since the predetermined fluid is filled in the cylinder 16, the shock is absorbed by the fluid when the piston 17 moves by an external impact.

Therefore, when the pad 12 causes shear deformation by the horizontal force, the piston 17 moves inside the cylinder 16 to absorb the shock, thereby preventing the pad 12 from being deformed over a predetermined range.

As described above, when the vertical force and the horizontal force act on the bearing 5 by the external load, the elastic support portion 3 absorbs the vertical force, and the shock absorbing portion 4 absorbs the horizontal force. Thus, the chair apparatus absorbs horizontal and vertical forces within a certain range.

On the other hand, Figure 5 to Figure 7 shows a teaching apparatus according to another embodiment of the present invention.

The chair apparatus according to another embodiment includes an elastic sliding pedestal 25, the elastic sliding pedestal 25 has the same structure as in the case of the embodiment. That is, the elastic sliding pedestal is installed between the upper plate 21 and the piers 22 to absorb the vertical force, and the horizontal force by connecting the elastic bearing portion 23 and the upper plate 21 to each other It includes a buffer 24 for absorbing.

The elastic support part 23 includes a pad 29 of a compressed rubber material having a predetermined elastic force, and the reinforcement plate 28 formed in multiple layers is embedded in the pad 29. In addition, an upper plate 26 in which a guide groove 31 is formed is positioned at an upper portion of the pad 29, and the upper plate 26 is attached to a bottom surface of the upper plate 21.

A flat plate 27 is integrally formed on the pad 29, and the guide jaw 30 protrudes upward from the middle of the flat plate 27. The guide jaw 30 is slidably coupled to the inside of the guide groove 31 of the upper plate 26. Therefore, when the pad 29 is deformed in the horizontal direction by the horizontal force, the guide jaw 30 slides along the guide groove 31.

In addition, a fluororesin plate 29a is attached to the upper surface of the flat plate 27, and the fluororesin plate 29a is located at both sides of the guide groove 31, respectively. Then, a stainless steel plate 28a is attached to the bottom of the upper plate 26. Therefore, when the pad 29 moves in the horizontal direction, the fluororesin plate 29a is prevented from being deteriorated and burned out by frictional contact with the stainless steel plate 28a.

The lower plate 33 is integrally mounted to the lower portion of the pad 29, and the anchor bolt 35 protrudes downward from the lower surface of the lower plate 33 and is fixed by being embedded in the piers 22. Therefore, the pad 29 is integrally fixed to the upper portion of the piers 22 by the lower plate 33 and the anchor bolt 35.

In addition, a pair of upper protrusions 32 which are spaced apart from each other by a predetermined distance are formed on both side surfaces of the upper plate 26, and a pair of lower protrusions 34 is also formed on the upper surface of the lower plate 33. In addition, the pair of lower protrusions 34 are positioned inside the pair of upper protrusions 32. Therefore, when an external load acts on the pad 29, the pair of lower protrusions 34 may move in a horizontal direction in contact with the inside of the pair of upper protrusions 32.

In addition, the buffer part 24 also has a structure similar to the case of the above embodiment. That is, the shock absorbing portion 24 has a space formed therein, the cylinder 36 is filled with fluid, the cylinder 36 is movably mounted inside one side 39 of the pad 29 It is connected to the side includes a piston 37 for supporting the side of the pad 29, and a fixed shaft 18 for fixing the cylinder 36 to the upper plate 26.

Therefore, when the pad 29 causes shear deformation by the horizontal force, the piston 37 moves inside the cylinder 36 to absorb the shock, thereby preventing the pad 29 from being deformed for a predetermined range or more.

As described above, when the vertical force and the horizontal force act on the elastic sliding pedestal 25 by external load, the elastic support 23 absorbs the vertical force, and the shock absorber 24 absorbs the horizontal force. . Thus, the chair apparatus absorbs horizontal and vertical forces within a certain range.

As such, the elastic slide support device of the leg according to the preferred embodiment of the present invention has an advantage of absorbing a relatively wide range of vertical force and horizontal force by forming a single device by including the elastic support part and the buffer part integrally.

In addition, it is possible to absorb a relatively wide range of vertical and horizontal forces, without having to install a different device for each bridge, it can absorb the external load by a device having the same specifications, construction time, construction cost, etc. This has the advantage of being saved.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications can be made within the scope of the claims, the detailed description of the invention, and the scope of the accompanying drawings. It goes without saying that it belongs to the scope of the present invention.

Claims (5)

A lower plate mounted on an upper portion of the piers; An upper plate integrally mounted to a lower portion of the upper plate; An elastic part mounted between the upper and lower plates to absorb the vertical force by supporting the upper plate; An elastic slide receiving device of the legs comprising a buffer for absorbing the horizontal force by connecting the elastic portion and the top plate. The bottom surface of the upper plate of claim 1, wherein the elastic part has a pad having elastic force, at least one reinforcing plate mounted inside the pad, and a guide jaw protruded from an upper surface of the pad, the guide jaw protruding from the pad. An elastic slide support device of a leg comprising a bearing consisting of a plate slidably coupled to a guide groove formed in the. The bottom surface of the upper plate of claim 1, wherein the elastic part has a pad having elastic force, at least one reinforcing plate mounted inside the pad, and a guide jaw protruded from an upper surface of the pad, the guide jaw protruding from the pad. A flat plate slidably coupled to the guide grooves formed in the groove, a pair of lower wedges protruding downward from the bottom of the upper plate, and a pair of upper wedges protruding upward from the upper surface of the lower plate. Elastic slide support of legs. The apparatus of claim 3, wherein a fluororesin plate is attached to an upper surface of the flat plate around the guide groove, and a stainless steel plate is attached to a bottom surface of the upper plate to make sliding contact with each other. The side of the pad according to claim 2 or 3, wherein the buffer part has a space formed therein so that the fluid is filled, and the cylinder is movably mounted inside the cylinder and one side is connected to a side surface of the pad. An elastic slide support device of the leg comprising a piston for supporting the, and a fixed shaft for fixing the cylinder.