KR101244717B1 - A rolling bearing with a friction with a shock absorber - Google Patents

Abstract

PURPOSE: A friction pendulum bearing equipped with a shock-absorbing function is provided to minimize the defection of a sliding surface and the generation of a gap when an external force such as a vertical and live load arises and stably maintains the functions for preventing damages to the upper and lower parts of a concrete when a shock load arises and the friction pendulum support. CONSTITUTION: A friction pendulum bearing equipped with a shock-absorbing function includes a spherical member(100), an upper and a lower plate(200,300), friction plates(400,410) and an upright type separation prevention protrusion(500). The spherical member has an upper and a lower projecting spherical surface with the form of the radius of a curvature on the disc-shaped upper and lower surfaces. The upper and the lower plate have curvature spherical grooves(220,320) which are mutually symmetrical with top and bottom to contact the upper and the lower projecting surfaces to be wrapped around on the position of the upper and lower part. The friction plate is installed for sliding on the upper and lower projecting surfaces, and in the curvature spherical grooves of the upper and lower plates. The separation prevention protrusion is formed to prevent the breakaway of the spherical member on the inner rim of the curvature spherical grooves of the upper and lower plates.

Description

Friction pendulum base with shock absorber {a rolling bearing with a friction with a shock absorber}

The present invention relates to a friction pendulum bearing installed on a bridge structure to dissipate energy through friction, and more particularly, to minimize the defects of the sliding surface structure in the spherical member constituting the friction pendulum bearing and to increase durability. The present invention relates to a friction pendulum bearing equipped with a shock absorbing function to increase the construction cost and to greatly reduce the processing cost and ease the construction and maintenance by minimizing the weight.

In general, the bridge structure is a flow force generated by the temperature change, wind power, external shock vibration, earthquake, etc. in the state that the bridge is installed, for this purpose, the bridge through the seismic design between the upper structure of the bridge deck and the lower structure of the bridge Various types of bridge feet are installed to ensure the stability of the bridge.

One example is the seismic isolation base that can seismically segregate between the upper structure that forms the bridge deck and the lower structure that forms the bridge.

The seismic support is such that the friction plate of the spherical member considering the coefficient of friction with respect to the vertical load in the upper and lower plate curvature spherical grooves is dissipated and dissipates energy, and provides the restoring force with geometric potential energy through the radius of the spherical spherical groove and spherical member. It absorbs the relative displacement force of the upper and lower structures, and the surface surface of the sliding surface according to the exact dimensions and tolerances due to the inaccuracy due to the flexibility and adjustability of the material and the deviation from the geometric setting value and the set curvature sphere and spherical member radius. There is a problem that is difficult to manufacture.

In addition, the surface surface of the sliding surface due to long-term vertical load after installation is completed, the spherical member is made of steel only, so the impact load is transmitted to the lower part as it is, the local settlement of the sliding surface occurs. When the live load acts as the heavy vehicle progresses, the girder sags and the rotation of the bearing is required due to the point rotation.The momentary load causes the play between the curvature spherical grooves and the spherical members of the upper and lower plates. There is a problem at work.

Korea Patent Registration No. 10-0635478 Low friction rolling motion pendulum support Korea Patent Publication No. 10-2008-0097405 Friction Pendulum Bearing Korea Patent Registration No. 10-0769818 Variable Friction Registration of Korean Patent No. 10-0660035

Accordingly, the present invention has been made to solve the above problems,

SUMMARY OF THE INVENTION

Minimizes the occurrence of sliding surface defects and play when the external force such as vertical load and bow load occurs, and maintains the function of the upper and lower concrete breakage and friction pendulum support stably when impact load is generated, and makes manufacturing and construction simple And construction cost can be greatly reduced.

The present invention to achieve the above object,

Upper and lower plates having a curved spherical groove that is symmetrically curved so as to be slidable in contact with a spherical member having upper and lower protruding spherical surfaces in the form of a radius of curvature on the upper and lower surfaces of the spherical member, and wrapped in upper and lower protruding surfaces of the spherical member. In the friction pendulum support consisting of, the friction plate for the slide is provided in the upper and lower projection spheres of the spherical member and the curvature spherical grooves of the upper and lower plates in contact with the spherical member, the spherical surface of the spherical spherical grooves of the upper and lower plates The fall prevention jaw of an upright form should be formed so that the detachment of a member may be prevented.

In addition, at least one of the outer edge of the spherical member and the upstanding surface of the fall prevention jaw which is in contact with the spherical member is provided with a shock absorbing material to absorb the shock.

In addition, it will be possible that the spherical member is made of a polyurethane material.

In addition, the outer edge of the spherical member may be provided with a reinforcement of the fiber or pipe material for reinforcement.

In addition, a plurality of reinforcement rings for reinforcement may be coupled to the outer edge of the spherical member up and down.

In addition, the edge outer surface of the spherical member may be formed to have an inclination angle in the vertical direction around the middle line.

In addition, the fiber board of the fiber or glass fiber material may be embedded in a plurality of layers inside the spherical member.

In addition, the spherical member may be made up of a first spherical member which is divided up and down and has a downwardly open downward groove and a second spherical member having a protrusion to be inserted into the downward groove.

Here, it will be preferable that a rubber plate is inserted into the downward groove so that the protrusion is supported.

In addition, the lower plate, the downwardly open insertion groove is formed, the lower plate of the lower plate may be further provided with a support plate formed with a protrusion to be inserted into the insertion groove.

In this case, it is preferable that a rubber plate is inserted into the insertion groove so that the protrusion is supported.

According to the present invention,

first; By applying the spherical member having elastic force, the impact load and rotation in the vertical and horizontal directions applied from the outside are controlled to stably absorb the deviation and rotation of the sliding surface.

second; The spherical member supporting the load is made of a material having elasticity such as polyurethane or composite fiber reinforced plastic having high durability, so that the structural rigidity as well as the ease of assembly, processing, and construction due to weight reduction can be controlled.

third; When the displacement force of the spherical member is exceeded, there is an effect of preventing the dropping phenomenon while absorbing the impact load.

1 is a cross-sectional view showing a friction pendulum bearing according to the present invention,
2 shows another embodiment according to FIG. 1, FIG.
3 is an operating state diagram according to the embodiment of FIG.
4 shows another embodiment according to FIG. 1, FIG.
5 shows another embodiment according to FIG. 1, FIG.
6 shows another embodiment according to FIG. 1, FIG.
7 shows another embodiment according to FIG. 1,
8 shows another embodiment according to FIG. 1, FIG.
9 shows another embodiment according to FIG. 1;

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may obscure the subject matter of the present invention. do.

The present invention relates to a friction pendulum bearing provided with a shock absorbing function installed on a bridge structure to dissipate energy by friction.

1, the spherical member 100 having upper and lower protruding spherical surfaces 120 and 140 in the form of a radius of curvature on the upper and lower surfaces of a disk shape, and the upper and lower portions of the spherical member 100 according to the present invention. Upper and lower plates 200 and 300 having upper and lower curvature spherical grooves 220 and 320 symmetric to be in contact with the protruding spheres 120 and 140 at the upper and lower positions, and the upper portion of the spherical member 100. And friction plates 400 and 410 and upper and lower friction projections 120 and 140 installed in the curvature spherical grooves 220 and 320 of the upper and lower plates 200 and 300 in contact therewith. Curvature spherical grooves 220 and 320 of the lower plate 200 and 300 is configured as a fall prevention jaw 500 of the upright shape to prevent the separation of the spherical member 200 in the inner edge.

The spherical member 100 has upper and lower protruding spherical surfaces 120 and 140 formed in a radius of curvature on upper and lower surfaces of a disc shape. And it is applied to the polyurethane or fiber reinforced plastics (fiber reinforced plastics) to have properties of high elasticity, high durability, high strength.

The upper plate 200 is formed with a curvature spherical groove 220 having a downwardly open shape on the bottom surface so as to be slidable in contact with the upper protruding sphere surface 120 of the spherical member 100.

The lower plate 300 is formed with a curvature spherical groove 320 having an upward open shape on the upper surface to be slidable in contact with the lower protruding surface 140 of the spherical member 100.

A gap is formed when the upper plate 200 and the lower plate 300 are combined to surround the spherical member 100 in an up and down position.

The upper and lower protruding spherical surfaces 120 and 140 and the curvature spherical grooves 220 and 320 of the spherical member 100 are integrally provided with friction plates 400 and 410 of a metal material for mutual slide during relative movement. Combined.

Accordingly, when a displacement force is generated relative to the upper plate 200 and the lower plate 300, the movable side of the upper plate 200 and the lower plate 300 is moved, and at this time, the displacement force is absorbed while moving together with the spherical member 100. Done. When the displacement force is continuously exceeded, the outer edge of the spherical member 100 is locked to the drop prevention jaw 500 while controlling the further movement while preventing the dropping of the spherical member 100.

Figure 2 is another example according to the present invention is to provide a shock absorbing material 600, 610 to secondarily absorb the impact on the fall prevention jaw 500 in contact with the spherical member 100.

That is, the shock absorbing material 600 is provided on an upright surface of the drop prevention jaw 500 formed at the inner edge of the curvature spherical grooves 220 and 320 of the upper plate 200 and the lower plate 300, and the drop prevention jaw. The shock absorbing material 610 is provided on an upright surface formed at the outer edge of the spherical member 100 in contact with the 500.

This, as shown in FIG. 3, when the edge of the spherical member 100, the displacement force is generated when the relative movement of the upper and lower plate 200, 300 is in contact with the fall prevention jaw 500 further absorbs the impact force It will be possible to solve the fall prevention.

4 is another example according to the present invention, the spherical member 100 is to form a reinforcement 700 on the outside to reinforce the strength.

The spherical member 100 is made of polyurethane or fiber reinforced plastics so as to have characteristics of elasticity, high durability, and high strength.

The reinforcement body 700 is made of a fiber material or a pipe-shaped metal material, and in the case of a fiber material, the band may be joined in a form of winding upright surface formed on the outer edge of the spherical member 100. The spherical member 100 may be inserted into the coupling.

When the reinforcement 700 is coupled, the shock absorbing material 610 may not be applied, but when the reinforcement 700 is to be applied, the reinforcement 700 may be coupled to the outside of the reinforcement 700.

In addition, as another example, the outer surface of the edge of the spherical member is formed to have an inclination angle in the vertical direction around the middle line to reduce the weight as well as to enable the elastic force when the relative displacement force is generated.

5 is another example according to the present invention, the outer surface of the edge of the spherical member 100 is shown to be formed to have an inclination angle 180 in the vertical direction around the middle line.

This, as well as reducing the weight of the spherical member 100 is to enable the elastic force when the relative displacement force occurs.

6 illustrates another example according to the present invention, in which a plurality of reinforcing rings 800 for reinforcement are coupled to the outer edge of the spherical member 100.

This may be a ring-shaped metal or rubber material having elasticity, and controls the compressive force when a load is applied to the spherical member 100.

FIG. 7 illustrates another embodiment of the spherical member 100, in which a fiber board 160 made of fiber or glass fiber material is embedded along a circumference of a plurality of layers or vertically.

This enables the elastic force of the spherical member 100 as well as increasing the compressive strength when the external force is applied.

8 is another example according to the present invention, the spherical member 100 is vertically separated, the first spherical member (100a) is formed with a downward groove (102a) is opened downwardly and a projection (to be inserted into the downward groove) ( It may be made of a second spherical member (100b) having a (102b).

Preferably, the rubber plate 130a is inserted into the downward groove 102a so that the protrusion 102b is supported.

Reference numeral 150a in the drawing is a ring member to prevent the ring member 150a from being pushed into a gap during compression of the rubber plate 130a.

9 is another example according to the present invention, the lower plate 300, the downwardly open insertion groove 340 is formed, the lower portion of the lower plate 340 to be inserted into the insertion groove 340 the projection ( It is shown that the support plate 380 is formed 360 is provided.

Preferably, the rubber plate 130a is inserted into the insertion groove 340 to support the protrusion 360.

100: spherical member
100a: first spherical member 100b: second spherical member
102a: downward groove 102b: protrusion
120: upper protrusion surface 140: lower protrusion surface
150a: ring member 160: fiberboard
180: inclination angle
200: top plate
220: curvature spherical groove
300: bottom plate
320: curvature spherical groove 340: insertion groove
360: protrusion 380: support plate
400,410: friction plate
500: Dropout prevention jaw
600,610: shock absorber
700: reinforcement
800: reinforcing ring

Claims (12)

Upper and lower plates having a curved spherical groove that is symmetrically curved so as to be slidable in contact with a spherical member having upper and lower protruding spherical surfaces in the form of a radius of curvature on the upper and lower surfaces of the spherical member, and wrapped in upper and lower protruding surfaces of the spherical member. In the friction pendulum stand consisting of
The spherical member is made of polyurethane or fiber-reinforced plastic material, and the friction plate for the slide is provided in the upper and lower protruding spherical surface of the spherical member and the curvature spherical grooves of the upper and lower plates in contact with the spherical member, Friction pendulum bearing with shock absorbing function, characterized in that the outer surface of the edge has an inclination angle in the vertical direction around the middle line.
The method of claim 1,
Friction pendulum bearing with a shock absorbing function, characterized in that the fall prevention jaw of the upright form is formed on the inner edge of the curvature spherical groove of the upper and lower plates to prevent the spherical member from being separated.
The method of claim 2,
And at least one of an outer edge of the spherical member and an upstanding surface of the drop prevention jaw which is in contact with the spherical member, the shock absorber having a shock absorbing function, characterized in that a shock absorbing member is provided.
delete The method of claim 1,
Friction pendulum bearing with a shock absorbing function, characterized in that the outer edge of the spherical member is made of a fiber or metal material for reinforcement and a reinforcement having a pipe shape.
The method of claim 1,
A friction pendulum bearing with a shock absorbing function, characterized in that a plurality of reinforcing rings are coupled to the outer edge of the spherical member up and down.
delete delete delete delete The method according to claim 1 or 2,
And a support plate having a protrusion formed downwardly in the lower plate in contact with the spherical member and having a protrusion formed to be inserted into the insertion groove in a lower portion of the lower plate.
The method of claim 11,
And a rubber plate is inserted into the insertion groove so that the protrusion is supported.

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