KR20190138954A - Bridge seismic reinforcement structure - Google Patents

Abstract

The present invention relates to an earthquake-proof reinforcing structure for a bridge, which increases seismic resistance after a coping unit of a bridge and a cross beam at an upper side of the coping unit are fastened to each other, and comprises: girders mounted after being spaced with predetermined intervals in a transverse direction at the upper side of the coping unit; the cross beam installed among the girders; a pair of mounting members coupled to the front and rear of the coping unit; a pair of shock absorbing sacrificial pillars individually coupled to the upper side of the pair of mounting members; a pair of shock absorbing members individually coupled to the upper side of the pair of shock absorbing sacrificial pillars; an elastic member coupled to the rear surface and the both side surfaces of each of the pair of shock absorbing members so as to come in contact with the cross beam and the girders; and a main control steel wire which penetrates the cross beam to fasten the pair of shock absorbing members to each other. Therefore, the earthquake-proof reinforcing structure can be installed while minimizing damage on a bridge structure, thereby providing an effect of preventing the girders from falling from the bridge structure by a horizontal force and a vertical force applied by an earthquake in an axial direction or a direction perpendicular to the axial direction.

Description

Bridge seismic reinforcement structure

The present invention relates to a bridge seismic reinforcement structure, and more particularly, to a bridge seismic reinforcement structure in which the seismic resistance is significantly increased by binding the coping portion of the bridge and the cross beams above the coping portion.

In general, bridge facilities are composed of substructures consisting of shifts and bridges and superstructures such as girders. Conventional bridges are often not designed for seismic loads.

In recent years, bridges equipped with seismic reinforcement devices have been constructed, and most of them have seismic reinforcement bridges, bond bridges and girders with steel, bond bridges and girders with hydraulic dampers, or bridge copings. The concrete block is installed in the upper part.

However, the prior art can only resist seismic forces in any part of the longitudinal horizontal force, the horizontal horizontal force, or the vertical vertical force acting on the bridge, so it is impossible to control all three seismic forces acting on the bridge. There is a problem in that seismic reinforcement devices must be separately installed so as to control the seismic force acting in each direction. In the prior art, there is a problem in that structures such as shifts or girders for installing seismic reinforcement devices are damaged. In addition, the prior art has a problem that the construction cost of the earthquake-resistant reinforcing device is complicated and difficult to construct the construction cost increases.

Therefore, there is a demand for technology development of a seismic reinforcing bridge structure that is inexpensive, easy to construct, and at the same time can control seismic force acting in all directions of up, down, left and right, and does not cause damage of structures such as bridges.

Patent 1: Republic of Korea Patent No. 10-1622626

In order to solve the above problems, the present invention by binding the cross beam and the pier coping unit installed between the girder, the construction is easy, the construction cost is saved and has resistance to earthquakes in all directions as well as the pier It is intended to provide a seismic reinforcement structure for bridges that does not cause damage.

Bridge seismic reinforcement structure according to an embodiment of the present invention, in the bridge seismic reinforcement structure in which the seismic resistance is increased by mutually binding the coping portion of the bridge and the cross beams on the upper side of the coping portion, spaced apart at a predetermined interval in the transverse direction above the coping portion Mounted girders; The cross beam installed between the girders; A pair of fixing members coupled to the front and rear of the coping portion; A pair of shock absorbing sacrificial columns respectively coupled to the upper sides of the pair of fixing members; A pair of shock absorbing members respectively coupled to an upper side of the pair of shock absorbing sacrificial pillars; an elastic member coupled to the rear surface and both sides of each of the pair of shock absorbing members to be in contact with the cross beam and the girder; And a main control steel wire penetrating the cross beams to mutually bind the pair of shock absorbing members to each other.

In addition, the main control wire may be characterized in that the loose coupling of the pair of shock absorbing members.

In addition, it may be characterized in that it further comprises an auxiliary control steel wire for binding the pair of shock absorbing sake mutually.

In addition, the auxiliary control steel wire may be characterized in that to loosely bind the pair of shock absorbing sake.

In addition, the auxiliary control steel wire may be located between the cross beam and the coping portion.

The apparatus may further include a front plate installed on the front side of the shock absorbing sacrificial column, and a triangular wedge plate coupled to a rear surface of the front plate and the side of the shock absorbing sacrificial column,

The auxiliary control steel wire may be coupled to the front plate.

In addition, it may be characterized in that it further comprises a fixed steel wire through the coping portion to bind the pair of fixing members to each other.

In addition, the fixing member includes a bottom plate which is installed in contact with the coping portion, the center member coupled to the center portion of the bottom plate in the vertical direction, and the brace plate coupled to the bottom plate and the center member on the left and right of the center member It can be characterized.

In addition, the shock absorbing sacrificial column and the shock absorbing member may be characterized in that the square tube or I-type steel.

Through the present invention, it is possible to minimize the damage of bridge structures, such as bridge piers, girders.

In addition, it may have resistance to earthquakes in the vertical direction as well as front, rear, left and right directions.

In addition, the structure is simple, the construction cost is saved and the construction period is shortened.

1A is a cross-sectional view showing a bridge seismic reinforcement structure according to an example of the present invention.
1B is a longitudinal cross-sectional view of FIG. 1A.
2A to 2C are perspective, front and side views showing the "detail A" part of FIGS. 1A and 1B.

Hereinafter, some embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the reference numerals to the components of the drawings, the same components are to have the same reference numerals as much as possible even if displayed on different drawings. In addition, in describing the embodiments of the present invention, when it is determined that a detailed description of a related well-known configuration or function interferes with the understanding of the embodiments of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but there is another component between each component. May be “connected”, “coupled” or “connected”.

Hereinafter, a bridge seismic reinforcement structure which is an example of the present invention will be described in detail with reference to FIGS. 1 and 2.

Bridge seismic reinforcement structure according to an embodiment of the present invention, in the bridge seismic reinforcement structure is increased seismic resistance by binding the coping portion 10 of the bridge and the cross beam 30 of the upper side of the coping portion 10, the nose Girders 10 spaced apart at regular intervals in a transverse direction on the upper side of the ping portion 10; The cross beam 30 is installed between the girder 10; A pair of fixing members 40 coupled to the front and rear of the coping part 10; A pair of shock absorbing sacrificial supports 50 respectively coupled to the upper side of the pair of fixing members 40; A pair of shock absorbing members 60 respectively coupled to the upper side of the pair of shock absorbing sacrificial supports 50; coupled to the back and both sides of each of the pair of shock absorbing members 60, the cross beam 30 ) And an elastic member 62 installed in contact with the girder 10; And a main control steel wire 68 penetrating the cross beam 30 to bind the pair of shock absorbing members 60 to each other.

The girder of the bridge seismic reinforcement structure of the present invention can be any of prestressed concrete (PSC) girder, reinforced concrete girder, steel girder, steel composite girder.

The girder 10 may be installed directly on the upper side of the coping portion 10 of the pier or mounted on the upper side of the bridge support. The girder 10 may be spaced apart at a predetermined interval in the transverse direction from the upper side of the coping portion 10.

Horizontal beams 30 may be installed between the girder 10. The cross beam 30 may be installed between the girders 10 to support or bind both girders 10. Reinforcing bars 30 in the longitudinal direction (or axial direction) or transverse direction (orthogonal direction) may be disposed in the cross beam 30 and concrete may be poured. The transverse bars may interconnect the girders 10 on both sides. The cross beam 30 may support the girders 10 on both sides, and may be connected to each other to be integrated. Anchor bolts and the like may be installed on the side of the girder 10 to be embedded in the concrete of the cross beam 30.

Before and after the coping part 10, a pair of fixing members 40 may be coupled. The fixing member 40 may be coupled to the front and rear walls of the coping part 10 by anchor bolts or the like.

The fixing member 40 may include a bottom plate 42 installed in contact with the wall surface of the coping part 10. The bottom plate 42 is in close contact with the front and rear walls of the coping portion 10 may be fixed by an anchor bolt or the like. The bottom plate 42 may be formed of a square steel sheet.

The central portion 44 may be coupled to the central portion of the bottom plate 42 in the vertical direction. The core member 44 may be coupled to the bottom plate 42 by welding or the like. The central member 44 may be formed of steel materials such as a c-shape, a square shape, and an i-shape.

The bracing plate 46 is coupled to the left and right sides of the center member 44 to couple the bottom plate 42 and the center member 44 to each other. That is, the prop plates 46 may be welded to the bottom plate 42 and the central member 44 at the left and right sides of the central member 44. The support plates 46 are formed in a triangular or trapezoidal shape, and the height thereof may be gradually lowered away from the central member 44. The bracing plate 46 increases the rigidity of the bottom plate 42, and at the same time, the core member 44 is firmly coupled to the bottom plate 42 so that it can cope well with the earthquake.

The pair of fixing members 40 configured as described above may be bound to each other by a fixed steel wire 48 such as a steel bar and a strand wire passing through the coping part 10. The fixed steel wire 48 allows the fixing member 40 to be firmly coupled to the coping portion 10, and at the same time, increases the structural rigidity of the coping portion 10 together with the fixing member 40.

The shock absorbing sacrificial column 50 may be coupled to the upper side of the pair of fixing members 40, respectively. The shock absorbing sacrificial column 50 may be coupled to an upper side of the central member 44 of the fixing member 40. The shock absorbing sacrificial column 50 may be coupled to the upper side of the center member 44 by welding, or may be integrally formed with the center member 44. The shock absorbing sacrificial column 50 may be formed of a square tube or an I-type steel.

The shock absorbing member 60 may be coupled to the upper side of the shock absorbing sacrificial column 50. The shock absorbing member 60 may be formed of a square tube or an I-type steel. The shock absorbing member 60 may be installed before and after the cross beam 30, respectively.

An elastic member 62 may be coupled to the back and both sides of the shock absorbing member 60. The elastic member 62 may be installed on the rear surface and both sides of the impact absorbing member 60, that is, the surface in contact with the horizontal beam 30 and both girders 10. The elastic member 62 may be formed of elastic rubber or the like. The elastic member 62 may absorb shock when an earthquake occurs and minimize damage to the girder 10, the cross beam 30, the shock absorbing member 60, and the shock absorbing sacrificial column 50.

The shock absorbing members 60 may be bound to each other by the main control wire 68 passing through the cross beam 30. That is, the main control wire 68 binds the cross-beam 30 and the shock absorbing member 60 positioned before and after the cross-beam 30, thereby not only firmly binding the shock-absorbing member 60 to the cross-beam 30, Together with the shock absorbing member 60 can increase the structural rigidity of the cross beam 30. The main control wire 68 may be fixed by the fixing plate and the fixing unit.

The main control wire 68 may loosely bind the pair of shock absorbing members 60. The loosely bound main wire 68 may prevent sudden breakage of the crossbeam 30, the shock absorbing member 60, the shock absorbing sacrificial column 50, and the lower structure by mitigating the rapid transmission of seismic force.

It may further include an auxiliary control steel wire (58) for binding the pair of shock absorbing sake 50 mutually. The auxiliary control steel wire 58 may increase the stability of the shock absorbing sacrificial column 50 by binding the pair of shock absorbing sacrificial columns 50 to each other, and at the same time, stably transmit the seismic force.

The auxiliary control steel wire 58 may loosely bind the pair of shock absorbing sashes 50. The loosely bound auxiliary control steel wire 58 may prevent sudden breakage of the pair of shock absorbing sacrificial columns 50. That is, loose binding of the auxiliary control steel wire 58 can widen the behavior range of the shock absorbing sacrificial column 50 to prevent sudden damage and further prevent falling of the girder 10.

The auxiliary control steel wire 58 may be located in the space portion between the cross beam 30 and the coping portion 10. That is, the auxiliary control steel wire 58 may be located at a height at which a bridge bearing between the girder 10 and the coping part 10 is installed. The auxiliary control steel wire 58 may be coupled to the front plate 52 installed on the front of the shock absorbing sacrificial column 50. The front plate 52 may be formed with an auxiliary control steel wire 58 fixing unit for fixing the auxiliary control steel wire 58. The auxiliary control steel wire 58 fixing unit may be composed of a fixing plate and a fixing unit. The front plate 52 may further include a triangular wedge plate 54 coupled to the rear surface of the front plate 52 and the side of the shock absorbing sacrificial unit 50 to firmly couple the front plate 52 to the shock absorbing sacrificial unit 50. have.

When an earthquake occurs, the longitudinal and lateral horizontal forces generated in the bridge may be absorbed by the elastic member 62 and the shock absorbing sacrificial column 50. In addition, the vertical force in the vertical direction may be absorbed by the tensile force of the impact absorbing sacrificial column (50).

As a result, a pair of fixing members 40 are installed and coupled to the pier coping part 10 before and after, and a pair of shock absorbing members 60 are installed and coupled to the front and rear of the cross beam 30 to impact the fixing member 40. By connecting the absorbing member 60 to the shock absorbing sacrificial column 50, the seismic performance of the bridge can be increased, and the falling of the girder 10 can be prevented.

In the above description, all elements constituting the embodiments of the present invention are described as being combined or operating in combination, but the present invention is not necessarily limited to the embodiments. In other words, within the scope of the present invention, all of the components may be configured or operated by selectively combining one or more of them. In addition, the terms "comprise", "comprise" or "having" described above mean that the corresponding component may be inherent unless specifically stated otherwise, and thus excludes other components. It should be construed that it may further include other components instead. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Terms used generally, such as terms defined in a dictionary, should be interpreted to coincide with the contextual meaning of the related art, and shall not be interpreted in an ideal or excessively formal sense unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

10: coping part
20: girder
30: crossbeam
40: fixing member
42: bottom plate
44: core material
46: Brace
48: fixed steel wire
50: Shock Absorbing Sacrifice
52: front panel
54: wedge plate
58: auxiliary control steel wire
60: shock absorbing member
62: elastic member
68: Main Liner

Claims (9)

In the bridge seismic reinforcement structure in which the seismic resistance is increased by binding the coping portion of the bridge and the cross beams on the upper side of the coping portion,
Girders spaced apart at regular intervals in the transverse direction on the upper side of the coping part;
A cross beam installed between the girders;
A pair of fixing members coupled to the front and rear of the coping portion;
A pair of shock absorbing sacrificial columns respectively coupled to the upper sides of the pair of fixing members;
A pair of shock absorbing members respectively coupled to the upper sides of the pair of shock absorbing sacrificial pillars;
An elastic member coupled to the rear surface and both sides of each of the pair of shock absorbing members and installed in contact with the cross beam and the girder; And
Bridge seismic reinforcement structure comprising ;;
The method according to claim 1,
The main control wire is seismic reinforced structure of the bridge, characterized in that for loosely binding the pair of shock absorbing members.
The method according to claim 1,
And an auxiliary control steel wire which mutually binds the pair of shock absorbing sacrificial pillars.
The method according to claim 3,
The auxiliary control steel wire bridge seismic reinforcement structure, characterized in that for loosely binding the pair of shock absorbing sacrificial.
The method according to claim 3,
The auxiliary control steel wire bridge seismic reinforcement structure, characterized in that located between the cross beam and the coping portion.
The method according to claim 5,
And a triangular wedge plate coupled to the front plate and the rear surface of the front plate and the side of the shock absorbing sacrificial body installed on the front side of the shock absorbing sacrificial column,
The auxiliary control steel wire bridge seismic reinforcement structure, characterized in that coupled to the front plate.
The method according to claim 1,
The seismic reinforcing structure of the bridge further comprising a fixed steel wire passing through the coping portion to bind the pair of fixing members to each other.
The method according to claim 1,
The fixing member may include a bottom plate installed in contact with the coping portion, a center member coupled to the center portion of the bottom plate in a vertical direction, and support plates coupled to the bottom plate and the center member at left and right sides of the center member. Bridge seismic reinforcement structure.
The method according to claim 1,
The shock absorbing sacrificial column and the shock absorbing member is a bridge seismic reinforcement structure, characterized in that the square tube or I steel.

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