KR200266458Y1 - Earthquake-proof Pot bearing for bridge - Google Patents

Abstract

The present invention relates to a seismic pot bearing, and more particularly, to a seismic pot bearing with an added seismic function.

A seismic port bearing according to the present invention for achieving the above object is a port bearing consisting of an upper plate and a lower plate, and a stopper bent upward at both ends of the lower plate is formed to cover the outer surface of the stopper and a portion of the upper surface of the upper plate. A side block of a shape bent at right angles to be contacted is installed, and a bolt hole is formed in the side block, and a bolt hole is formed at a position corresponding to the stopper, so that the side block is fastened to the stopper by bolts. The formed bolt hole is configured to be formed to a certain depth and wider to accommodate the bolt head, providing the effect of countering the larger stresses that can be generated by an earthquake without changing the existing design.

Description

Earthquake-proof Pot bearing for bridge

The present invention relates to a seismic pot bearing, and more particularly, to a seismic pot bearing with an added seismic function.

In general, the bridge device is installed between the bridge deck structure and the bridge concrete structure serves to transfer all the loads that are transferred to the top of the structure to the bridge concrete structure. Such a device is not only performing a function of transmitting a load, but research is being conducted to perform various functions in order to solve a problem that may be caused by connecting two structures.

In the 20th century, as the earthquake activity became more active worldwide, the analysis of various observation records showed that the probability of earthquake activity will be activated on the Korean peninsula, and the seismic design concept was introduced into the specification. It is under construction.

The seismic performance of the structure depends on the geometry of the bridge, the type of bridge, the connection situation between members, the support conditions of the structure, etc., and the vertical load, horizontal load, Issues related to anti-falling and uplifting are related to the present invention.

The vibrations of natural disasters caused by earthquakes, the causes of bridge vibration, wind loads, and constant loads (dynamic behavior due to the vehicle's movement), etc., cannot be accurately analyzed. The occurrence of a lot of fatigue cracks in the load transfer member causes the loosening of the anchor connecting the bridge bearing and the substructure and the local destruction, so the countermeasure is urgent.

There are various kinds of these devices according to their function and the purpose of installation. Among them, the port bearings have a simple function of vertical load and moving function. The present invention is improved by adding the function to endure the vertical load and the horizontal shear load to the port bearing, and the vertical loads, wind loads, earthquake loads, expansion and contraction such as dead load, live load, vehicle load, etc. It is a seismic stabilization device including a movement limiting device, a negative reaction device, an anti-falling device, an impact absorbing device, etc. to withstand the horizontal load generated by the behavior according to the above. Such a port bearing is advantageous for a bridge and a curved bridge in which the rotational direction and the moving direction do not coincide.

Conventional port bearings are composed of a lower plate installed in the lower portion of the anchor bolt embedded in the concrete from the lower portion, rubber, piston, bearing surface, sliding plate and the upper plate to mitigate the impact of the vertical load.

As described above, the conventional port bearing transfers the load of the bridge to the bottom and is moved according to the horizontal moving force to perform the bearing function.

However, such a conventional port bearing has a problem in that the above functions cannot be performed because side blocks are not provided to cope with horizontal movement restrictions and lift forces, and side blocks are installed to solve these problems. Since the size of the port bearing itself is changed and the entire design has to be redone, there is a problem in that it is better to use a different type of bearing in the end.

Therefore, the conventional port bearing has a problem that the seismic design is not easy.

The present invention has been made to solve the above problems of the prior art, to provide an earthquake-proof port bearing to improve the seismic performance by installing a side block and the like while maintaining the size of the port bearing to maintain the existing design There is this.

1 is a partial cross-sectional view of the seismic pot bearing according to the present invention,

Figure 2 is a bottom view of the seismic pot bearing according to the present invention,

3 is a plan view of the seismic pot bearing according to the present invention,

4 is a partial cross-sectional view according to another embodiment of the seismic pot bearing according to the present invention.

<Explanation of symbols on main parts of the drawings>

10: top plate 20: bottom plate

20a: Stopper 20b: Stepped portion

21: uneven portion 22: anchor bolt

40: side block 50: bolt

A seismic port bearing according to the present invention is a port bearing consisting of an upper plate and a lower plate, and a stopper bent upward at both ends of the lower plate is formed and bent at a right angle to contact the outer surface of the stopper and a part of the upper surface of the upper plate. Side block is installed, the bolt hole is formed in the side block and a bolt hole is formed at a position corresponding to the stopper, the side block is fastened to the stopper by the bolt, the bolt hole formed in the side block It is characterized in that formed in a predetermined depth more wide to accommodate.

In addition, the earthquake-resistant port bearing according to the present invention is a buried portion is embedded in the lower portion of the lower plate is formed, characterized in that the irregularities formed on the outside.

In addition, the seismic pot bearing according to the present invention is characterized in that the stopper of the lower plate is formed with a stepped portion on which the vertical surface of the side block is seated so that the vertical surface of the side block does not protrude outward when the side block is fastened.

In addition, the earthquake-resistant port bearing according to the present invention is characterized in that the rubber is provided on the inner surface of the lower plate stopper the elastic means on the portion where the upper plate is hit by an external force.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

The seismic port bearing according to the present invention has a bottom plate 20 having an anchor bolt 22 embedded in concrete as shown in FIGS. 1 to 3, and simultaneously transfers load from a bridge to the bottom plate 20. The upper plate 10 is moved by a predetermined amount according to the horizontal force, and the side block 40 formed by bending at a right angle to cover a portion of the upper plate 10 and a portion of the lower plate 20.

The lower plate 20 has a buried portion 21 is formed in the lower bar, the buried portion 21 is formed with an unevenness (21a) on the outer surface, the stopper (20a) is bent to the upper side is provided The movement of the upper plate 10 is limited. The stopper 20a has a stepped portion 20b formed on an outer surface thereof to accommodate the vertical surface of the side block 40. Further, a bolt hole is formed in the upper surface of the stopper 20a.

The upper plate 10 is installed on the rubber 30, the piston 33, the bearing surface 31, the sliding plate 32, which is an elastic means on the lower plate 20, a portion of the upper plate 10 As described above, the upward movement is limited by the horizontal surface of the side block 40.

The side block 40 is bent at right angles to cover the outer surface and the upper surface of the stopper 20a and a portion of the upper plate 10, and a bolt hole 40a is formed on the upper surface thereof, and the bolt hole is formed. The bolt 50 is inserted into the 40a, and the lower portion of the bolt 50 is fastened to the bolt hole of the stopper 20a. The bolt hole 40a of the side block 40 may accommodate the head of the bolt 50. So that it is wide.

2 is a bottom view of the seismic pot bearing according to the present invention, and it is reliably shown that the unevenness 21a is formed in the buried portion 21 of the lower plate 20.

3 is a plan view of the seismic pot bearing according to the present invention, in which a stopper 20a of the lower plate 20 is formed on both sides, and a part of the upper plate 10 is covered by the side block 20a. , The bolt 50 is fastened downward from the side block 40 top.

In the present invention configured as described above, the seismic port bearings transmit the load of the bridge to the lower plate 20 by the upper plate 10, and the piston 33 and the rubber 30 are installed and shocked against the suddenly applied vertical stress. Absorb it. In addition, the movement by the horizontal force is solved by the sliding by the sliding plate 32 and the bearing surface 31, the horizontal movement to some extent is limited by the stopper (20a), the rubber (inside the stopper 20a) 34) is installed to absorb the sudden impact by the rapid horizontal force.

In addition, the lifting force is controlled by the horizontal plane of the side block 40.

On the other hand, Figure 4 is a cross-sectional view showing another embodiment of the port bearing according to the present invention, first to secure the removable base plate 60 using the anchor bolt 22 on the top of the pier or alternating concrete structure, the port thereon The rest of the bearing is to be placed to improve the workability.

As shown in FIG. 4, the buried portion 21 formed on the lower plate 20 is formed below the base plate 60, and the lower plate 20 on which the buried portion 21 is removed is disposed on the base plate 60. This will be put on. Of course, the structure of the upper plate 20 is as described above.

As such, the seismic pot bearing according to the present invention is provided with a stopper and a side block so as to counter a greater horizontal force, and at the same time, the stopper is configured to protrude to both outer sides of the lower plate and the side block is fitted into the stepped portion. Because it is configured to maintain the existing size without increasing the volume provides an effect that can be applied immediately without changing the existing design.

In addition, the seismic pot bearing according to the present invention can be more effectively cope with the lifting force because the side block is fastened by the vertically standing bolt.

In addition, the seismic pot bearing according to the present invention has an uneven portion formed in the buried portion of the lower plate to increase the adhesive force with the concrete and at the same time provide an effect that can counter the greater horizontal force.

In addition, the seismic pot bearing according to the present invention is provided with rubber to provide an effect of mitigating a sudden impact.

In addition, the earthquake-resistant port bearing according to the present invention is to be separated by the lower structure and the anchor base plate in consideration of the workability to facilitate the construction and repairability.

The present invention is not limited to the above embodiments and may be variously modified and implemented by those skilled in the art without departing from the technical gist of the present invention.

Claims (5)

A port bearing consisting of an upper plate and a lower plate, a stopper bent upward at both ends of the lower plate is formed, and a side block having a shape bent at a right angle to contact the outer surface of the stopper and a portion of the upper surface of the upper plate is installed. A bolt hole is formed in the block, and a bolt hole is formed at a position corresponding to the stopper so that the side block is fastened to the stopper by the bolt, and the bolt hole formed in the side block is formed to have a predetermined depth to accommodate the bolt head. A seismic port bearing, characterized in that. The method of claim 1, The lower portion of the lower plate is buried in the concrete buried portion is formed, seismic resistance port bearing, characterized in that the irregularities formed on the outside. The method of claim 1, The stopper of the lower plate is a seismic port bearing, characterized in that the stepped portion is formed so that the vertical surface of the side block is seated so that the vertical surface of the side block does not protrude outward when the side block is fastened. The method of claim 1, An inner surface of the lower plate stopper is an earthquake-proof port bearing, characterized in that the rubber means is installed on the portion where the upper plate is hit by an external force. The method of claim 1, A seismic port bearing, characterized in that the groove is formed in which the port bearing is seated, and further comprising a base plate fixed to the pier or alternating concrete structure by anchor bolts.