KR100680596B1 - Superstructure double joint structure of bridge - Google Patents

Abstract

The present invention relates to a two-stage joint structure of the upper structure of the bridge to increase the bending stiffness of the girder by installing a simple bridge I-beam or H-beam bridge in two stages on the bridge, and is installed horizontally on the bridge and a plurality of A pedestal comprising an I-beam or H-beam with fastening holes formed therein; A plurality of girders, each of which is installed horizontally on an upper side of the pedestal, the opposing ends of which are in contact with each other, each of which forms a parental section, comprising a plurality of I-beams or H-beams having a plurality of fastening holes; And a coupling member for coupling a contact portion between the pedestal and the plurality of girders and a contact portion between the plurality of girders.

Bridge, simple bridge, girder, pedestal, bolt

Description

Superstructure double joint structure of bridge

1 is a view showing a superstructure two-stage joint structure of a bridge according to an embodiment of the present invention,

2 is an exploded perspective view of the main part of FIG.

3 is a perspective view showing the shape of the pedestal shown in FIG.

* Explanation of symbols for main parts of the drawings

10: pier 12: girder

14: shear connector 16, 17: end reinforcement

18: binding plate 18a: top binding plate

18b: bottom binding plate 20: bolt

22: nut 24: base

The present invention relates to a two-stage joint structure of the upper structure of the bridge, and more particularly, to a two-stage joint structure of the upper structure of the bridge to connect the girder of the simple bridge I (H) section steel bridge to the second stage to continue the girder. It is about.

Bridges are largely divided into superstructures and substructures. Superstructures refer to structures on top of bridges or bridges, and substructures refer to bridges and bridges that safely transfer loads acting on the superstructure to the ground.

The superstructure is generally composed of girders, slabs. Determining the type of bridge depends on the shape of the main member, which is usually the member that receives the most force. Girder bridges are called main bridges, arches are called arch bridges, trusses are called truss bridges, and cable bridges (cable bridges, suspension bridges) are supported. The slab refers to a bottom plate that allows a vehicle or the like to travel on the top.

The alternation of the substructure means the bearing of the starting point of the bridge, and the pier of the substructure means the intermediate bearing other than the starting point.

As the types of bridges constructed in this way, they are classified into simple bridges, continuous bridges, and Gerber bridges.

Bridges and bridges are sometimes referred to as spans or spans, and bridges in which the template of each span is separated are called simple bridges. The advantages of the simple school are easy calculation and easy construction. Disadvantage is that it can not pull long because of the large deflection. Therefore, simple bridges are mainly applied to small bridges.

The present invention has been proposed in view of the above-described conventional situation, and provides a two-stage joint structure of the upper structure of a bridge to increase the bending rigidity of the girder by installing a simple bridge I-beam or H-beam bridge in two stages on a pier. There is a purpose.

In order to achieve the above object, the upper structure two-stage joint structure of the bridge according to a preferred embodiment of the present invention is formed of an I-beam beam or an H-beam beam horizontally installed on the pier and a plurality of fastening holes are formed on the upper side. Pedestal; A plurality of girders, each of which is installed horizontally on an upper side of the pedestal, the opposing ends of which are in contact with each other, each of which forms a parental section, comprising a plurality of I-beams or H-beams having a plurality of fastening holes; And a coupling member for coupling a contact portion between the pedestal and the plurality of girders and a contact portion between the plurality of girders.

The coupling member may include: a binding plate that is padded up and down on an upper surface portion of a contact portion between the girders and has a plurality of fastening holes formed therein; And a fastening member fastened through a fastening hole of the binding plate and an upper fastening part of both end surfaces of the girder, and a fastening member fastened through the fastening hole of both ends of the bottom surface of the girder and the fastening hole of the pedestal.

The first end stiffener in the form of a deflector is fastened to the contact part surface by bolts to cover the contact part surface of the girder in contact with the opposing contact. It is interpolated to be in the same line as the first end reinforcement.

Hereinafter, with reference to the accompanying drawings will be described with respect to the upper structure two-stage joint structure of the bridge according to an embodiment of the present invention.

1 is a view showing a two-stage structure of the upper structure of the bridge according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the main part of Figure 1, Figure 3 is a perspective view showing the shape of the pedestal shown in Figure 1 to be.

As shown in the figure, the upper structure two-stage joint structure of the bridge according to the present invention is a simple bridge having a girder 12 of I-beam or H-beam beams horizontally installed separately from each other on the bridge 10. This structure is applied to I (H) section steel bridge.

In the upper structure two-stage joint structure of the bridge according to the present invention, a pedestal 24 made of I-beam or H-beam beam is horizontally installed on the pedestal device of the bridge 10, and on the upper side of the pedestal 24. A plurality of girders 12 are installed horizontally with each other but the opposite ends are in contact with each other. In addition, a coupling member for coupling each other is installed at a contact portion between the pedestal 24 and the plurality of girders 12 and a contact portion between the plurality of girders 12.

Here, a plurality of fastening holes 24b are formed on the upper surface of the pedestal 24. And, the pedestal 24 preferably has a length as long as the parent section of the lower surface of the girder 12.

In addition, a plurality of fastening holes 12d are formed in the protruding portions of one side end portion 12b and the lower portion 12c of each girder 12, and a plurality of fastening holes 12a are also formed inside each side end portion. Is formed. When the girders 12 are in contact with each other horizontally, a first end stiffener 17 having a zigzag shape is fastened by a bolt 20 to the contact surface, and the inner end of the first end stiffener 17 may be fastened. A plurality of fastening holes 17a are also formed on the side surfaces.

The coupling member includes: a binding plate (18) consisting of an upper surface binding plate (18a) and a lower surface binding plate (18b), which are padded up and down in an upper surface portion among the contact portions between the girders (12) and formed with a plurality of fastening holes; And fastening through the fastening hole of the binding plate 18 and the fastening hole 12d of the upper surface of both end portions of the girder 12 (ie, 12b) and the lower surface of the both end portions of the girder 12 (ie, 12c). ) And a fastening member (bolt 20, nut 22) fastened through the fastening hole 12d of the crankshaft and the fastening hole 24b of the pedestal 24.

On the other hand, the inner end portion of the pedestal 24, the second end reinforcing material 16 in the form of a deviator is interpolated, it is interpolated so as to be located in the same line with the first end reinforcing material (17).

Next, the installation process of the upper structure two-stage joint structure of the bridge according to an embodiment of the present invention.

First, after the pedestal 24 is installed on the pedestal device of the piers 10, the two girders 12 are horizontally placed on the pedestal 24.

Subsequently, the contact portion between the girder 12 and the pedestal 24 is fastened by using the bolt 20 and the nut 22, and the second end reinforcement 16 is attached to the inner central portion of the pedestal 24. Interpolate. That is, when fastening between the girder 12 and the pedestal 24, the fastening hole 12d formed in the lower portion 12c protruding portion of the girder 12 and the fastening hole 24b formed in the upper side of the pedestal 24 are provided. The bolt 20 and the nut 22 are fastened together.

Subsequently, the upper and lower binding plates 18b and the lower binding plate 18b are padded on the upper and lower surfaces of the girder 12 in contact with the end faces of the girders 12, respectively. Fasten the upper part between the girder 12 by the bolt and nut through. Then, the first end reinforcing material 17 is fastened by the bolt 20 to the contact surface between the girder 12 in contact with each other.

The upper structure double joint structure of the bridge according to the embodiment of the present invention may be installed by the above-described process, or may be installed through other processes as necessary. For example, the girder 12 and the pedestal 24 may be previously installed on the piers 16 after the coupling members and the first and second end stiffeners 17 and 16 are joined in the ground.

On the other hand, the present invention is not limited only to the above-described embodiments and can be carried out by modifications and variations within the scope not departing from the gist of the present invention, and the technical spirit to which such modifications and variations are applied also belongs to the following claims. Must see

As described in detail above, according to the present invention, the bridge can be applied to a continuous bridge of 25 to 40m by providing a simple bridge I-beam or H-beam bridge in two stages at the pier.

In addition, by fastening the parent moment section of the bridge consisting of two stages with bolts, it is possible to minimize the fatigue (fatigue) problem due to welding in the moment section, it is possible to cheaper and faster construction than the existing method.

In addition, according to the present invention, the bending stiffness of the girder cross section is increased by more than two times compared to the existing composite type.

Claims (5)

delete delete delete delete A pedestal made of an I-beam or an H-beam, which is horizontally installed on the pier and has a plurality of fastening holes formed on an upper side thereof; A plurality of girders, each of which is installed horizontally on an upper side of the pedestal, the opposing ends of which are in contact with each other, each of which forms a parental section, comprising a plurality of I-beams or H-beams having a plurality of fastening holes; And In the upper structure two-stage joint structure of the bridge having a coupling member for coupling the contact portion between the pedestal and the plurality of girders and the contact portion between the plurality of girders, The coupling member may include: a binding plate that is padded up and down on an upper surface portion of a contact portion between the girders and has a plurality of fastening holes formed therein; And a fastening member comprising a fastening hole of the binding plate and a fastening hole of the upper end of both ends of the girder, and a bolt and a nut fastened through the fastening hole of both end and lower ends of the girder and the fastening hole of the pedestal. The first end stiffener in the form of a deflector is fastened to the contact surface by bolts to cover the contact surface of the girder in contact with the opposite contact, and the second end stiffener in the form of a deviator is inserted into the central part of the pedestal. The upper structure two-stage joint structure of the bridge, characterized in that interpolated so as to be located in the same line with the first end stiffener.

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