KR200384998Y1 - Encased composite H girder bridge - Google Patents

Abstract

The present invention relates to an embedded composite H-beam steel girder bridge that can reduce the amount of concrete while properly exerting its function as a bridge. In the embedded composite H-beam steel girder bridge in which the girder is embedded in the bottom plate, The girder is connected to each other by a horizontal bar and an arched deck plate, the horizontal bar is installed in the transverse direction through the web of the girder embedded in the bottom plate, both ends of the deck plate is formed with a coupling guide, the coupling The guide slides longitudinally along the lower flange end of the mutually adjacent girders.

Description

Encased composite H girder bridge

The present invention relates to a buried synthetic H-beam girder bridge, and more particularly, to a buried synthetic H-beam girder bridge constructed using an arched deck plate.

In general, bridges are elevated structures made to cross rivers, lakes, straits, bays, canals, lowlands or other traffic routes or structures, as shown in FIG. ) And the substructure 20.

The superstructure 10 refers to a structure above the alternating 22 or pier 24 and is generally comprised of a girder 12, a slab 14. Determining the type of bridge depends on the shape of the main member, which is usually the member that receives the most force. The case where the main member is a girder 12 is called a girder bridge, the case of an arch is called an arch bridge, the case of a truss is called a truss bridge, and the case supported by a cable is called a cable bridge (cable bridge, suspension bridge). The slab 14 refers to a bottom plate that allows a vehicle or the like to travel on the top.

The undercarriage 20 refers to alternating 22 and pier 24 which serve to safely transfer the load acting on the superstructure 10 to the ground. Shift 22 means the bearing of the starting point of the bridge, the bridge 24 means the intermediate bearing other than the starting point. The ground condition under the pier 24 determines the type of foundation, pile foundations, wells foundations, etc. directly. The foundation slab 26 is located under the pier 24.

H-beam girder bridges, which are generally used in such bridges, have a high mold height (that is, a height from the bottom of the girder 12 to the top of the bottom plate 14) because the bottom plate 14 is installed on the girder 12. .

Accordingly, various ways to lower the height of the H-beam girder bridges were sought. As one of the methods, the embedded synthetic H-beam girder bridges as shown in FIG. 2 were proposed. That is, as shown in Figure 2 by embedding the girder 30 in the bottom plate 40 of the concrete material it is possible to lower the mold height and increase the synthesis efficiency between the girder 30 and the bottom plate 40 than the structure of FIG. It became possible.

However, the buried synthetic H-beam girder bridge of FIG. 2 has the advantages described above, but the amount of concrete forming the bottom plate 40 may increase as the girder 30 is embedded in the bottom plate 40. There is no economic burden.

The present invention has been proposed to solve the above-described problems, and an object of the present invention is to provide a buried synthetic H-shaped steel girder bridge that can properly function as a bridge while reducing the amount of concrete.

In order to achieve the above object, the embedded synthetic H-beam girder bridge according to the preferred embodiment of the present invention, in the embedded synthetic H-beam girder bridge, the girder is embedded in the bottom plate,

The girder embedded in the bottom plate is connected by a horizontal bar and an arched deck plate, the horizontal bar is installed in the transverse direction through the web of the girder embedded in the bottom plate, the coupling guides at both ends of the deck plate Is formed, the coupling guide is characterized in that it is slidingly coupled in the longitudinal direction along the lower flange end of the girder adjacent to each other.

Preferably, the upper surface curvature of the deck plate is formed with protrusions having an uneven or embossed shape, the coupling guide of the deck plate and the lower flange of the girders are mutually bound by a high-tensile bolt and nut.

Hereinafter, with reference to the accompanying drawings will be described with respect to the embedded composite H-beam girder bridge according to an embodiment of the present invention.

Figure 3 is a perspective view for explaining the configuration of the embedded composite H-beam girder bridge according to an embodiment of the present invention, Figure 4 is a cross-sectional view for explaining the configuration of the embedded composite H-beam girder bridge according to an embodiment of the present invention. .

In the embedded synthetic H-shaped steel girder bridge according to an embodiment of the present invention, a plurality of girders 50 are embedded in the bottom plate 60 of the concrete material in parallel to each other, the girder 50 mutually to maintain the reinforcement spacing In addition to the sake is connected by the horizontal bar (90) and the arc-shaped deck plate 70 for performing the role of the cross beam.

Here, the horizontal rod 90 is installed in the horizontal direction through the web of the girder 50 embedded in the bottom plate 60. Although not shown in the figure, the through holes are formed in the web of the girder 50. The horizontal rod 90 may be made of a tension member or the like.

In addition, both ends of the deck plate 70 are formed with a coupling guide of a declination shape, the coupling guide is slidingly coupled in the longitudinal direction along the lower flange end of the adjacent girder 50.

In particular, the upper curvature of the deck plate 70 is formed with a protrusion 80 of irregularities or embossed shape in order to improve the coupling with the bottom plate (60).

On the other hand, the coupling guide of the deck plate 70 and the lower flange of the girder 50 is mutually bound by the high tension bolt 92 and the nut 94. The high tension bolt 92 and the nut 94 may not be used.

The material of the deck plate 70 may be corrugated steel sheet or transparent FRP as well as steel.

Subsequently, in order to construct the embedded composite H-beam steel girder bridge according to the embodiment of the present invention configured as described above, first, an arc-shaped deck plate 70 having a declination-shaped coupling guide is formed at both ends thereof, but the deck plate ( On the curvature portion located on the upper surface of 70), protrusions 80 having an uneven or embossed shape are formed.

Thereafter, the girders 50 to be embedded in the concrete floor plate 60 are positioned parallel to each other at regular intervals, and the lower flanges of adjacent girders 50 among the positioned girders 50 are placed on the deck plate. Combine with each other using (70). That is, the coupling guide of the deck plate 70 is fitted to the lower flange of the mutually adjacent girders 50 in a sliding manner. Then, the high tension bolts 92 and the nuts 94 are used to more firmly engage the coupling guide portion and the lower flange. The use of the high tension bolts 92 and nuts 94 is optional. In this way, the arcuate deck plate 70 serves as a formwork.

Then, the girders 50 are tightly bound by installing the horizontal bar 90 through the webs of the girders 50.

Of course, the horizontal bar 90 may be installed first, and then the deck plate 70 may be coupled.

Subsequently, when the concrete is placed on it to form a bottom plate 60 of a predetermined thickness to create a buried synthetic H-beam girder bridge of the present invention.

As described in detail above, according to the present invention, by using the arched deck plate, it is possible to reduce the amount of concrete required for the bottom plate, and to reduce the weight of the bottom plate, and by the arched deck plate Will be excellent.

On the other hand, the present invention is not limited to the above-described embodiment and can be carried out by modifying and modifying within the scope not departing from the gist of the present invention, the technical idea that such modifications and modifications are also applied to the following utility model registration claims It must be seen as belonging.

1 is a view for explaining the structure of a general bridge,

2 is a view for explaining a conventional embedded synthetic H-beam girder bridge,

Figure 3 is a perspective view of the main part for explaining the configuration of the embedded synthetic H-beam girder bridge according to an embodiment of the present invention,

4 is a cross-sectional view for explaining the configuration of the embedded synthetic H-beam girder bridge according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

50: girder 60: bottom plate

70: deck plate 80: protrusion

90: horizontal bar 92: high tension bolt

94: nuts

Claims (3)

In the embedded synthetic H-beam girder bridge, in which the girder is embedded in the bottom plate, The girder embedded in the bottom plate is connected by a horizontal bar and an arched deck plate, the horizontal bar is installed in the transverse direction through the web of the girder embedded in the bottom plate, the coupling guides at both ends of the deck plate Is formed, the coupling guide is embedded synthetic H-beam girder bridge, characterized in that the sliding sliding in the longitudinal direction along the lower flange end of the adjacent girder. The method of claim 1, The buried synthetic H-shaped steel girder bridge, characterized in that the protrusion of the irregularities or embossed shape is formed on the upper curvature of the deck plate. The method according to claim 1 or 2, And the coupling guide of the deck plate and the lower flange of the girders are mutually bound by a high tension bolt and a nut.