KR102275158B1 - Steel box girder bridge - Google Patents

Abstract

The present invention relates to a steel box type girder bridge, which can be efficiently supported by withstanding the distribution of bending moments in a girder, and can be economically designed. The steel box type girder bridge comprises: a girder including abdomens laterally disposed at regular intervals, an upper flange arranged horizontally on the abdomens, and a lower flange arranged horizontally below the abdomens; a negative moment section in which upward tension occurs while the girder is disposed and a positive moment section in which downward tension on the girder occurs. The upper flange of the negative moment section is formed to have a closed section and has mortar filling grooves formed by being downwardly bent at regular intervals, and the upper surface of the upper flange has stud bolts installed therein. The lower flange of the negative moment section is formed to have an open section, an "H"-beam steel is disposed in the center of the upper surface of the lower flange located in a branch section where a bridge seat device is installed, and stud bolts are installed in the upper surface of the lower flange located in a section outside the bridge seat device. The upper flange of the positive moment section is formed to have an open section in which stud bolts are formed, the lower flange has a closed section, and ribs are provided on the upper surface of the closed section.

Description

Steel box girder bridge

The present invention relates to a steel box-type girder bridge that can be efficiently supported by resistance according to the distribution of the bending moment of the girder, and can reduce the amount of steel used by increasing rigidity and enable economical design.

In general, in a steel box girder bridge, the cross-sectional shape of the positive and negative moment sections consists of a closed section composed of two abdomens and upper and lower flanges.

Such a conventional steel box girder bridge considers only the convenience of manufacturing a steel box type girder bridge rather than improving economic efficiency by reducing unnecessary steel materials according to stress, and the amount of expensive steel material is severely wasted.

That is, the upper flange of the positive moment section is a section receiving compressive stress, and the bottom plate slab mainly responds to compressive stress rather than the steel upper flange. Since it only plays a role in maintaining the shape of the steel, a large amount of steel is wasted while using a large amount of steel, but it cannot play a proper role.

In addition, the upper flange of the negative moment section responds to the tensile stress, so there is structural efficiency, but the lower flange requires a large amount of steel because the steel has to respond to the compressive stress, which causes uneconomic factors.

KR 10-1779959 KR 10-1634307 KR 10-0682790 KR 10-0906400 KR 10-0995501 KR 10-0948358 KR 10-0615471

The present invention was devised to solve this problem, and the upper flange of the negative moment section in which the upper tension of the steel box girder occurs is formed as a closed cross-section, and a mortar filling groove is formed in the upper flange, so that the concrete mortar is closely synthesized. The lower flange of the negative moment section is formed as an open cross-section, and the “H” beam steel is disposed in the section where the seat unit is installed to increase rigidity, and the section outside the seat unit is formed at a certain height. It can be supported effectively by resisting according to the distribution of the bending moment of the girder, such as the concrete mortar layer used to cope with the compressive force. It is to provide a steel box type girder bridge that enables economical design while reducing

The present invention provides a girder comprising an abdomen disposed on the left and right at regular intervals, an upper flange horizontally disposed on the upper portion of the abdomen, and a lower flange horizontally disposed on the lower portion of the abdomen, and the upper portion in a state in which the girder is disposed It consists of a negative moment section in which tension is generated and a positive moment section in which the lower tension of the girder is generated, but the upper flange of the negative moment section is formed in a closed cross-section and is bent downward at regular intervals on the upper flange. The upper surface of the upper flange has a configuration in which stud bolts are installed, and the lower flange of the negative moment section is formed as an open cross-section and is made of "H" beam steel in the center of the upper surface of the lower flange located in the section where the pedestal device is installed. is disposed, a stud bolt is installed on the upper surface of the lower flange located in the section out of the seat arrangement, and the upper flange of the positive moment section is formed as an open cross-section in which the stud bolt is formed, and the lower flange is provided in a closed cross-section, It is characterized by a steel box type girder bridge with ribs on the upper surface of the closed section.

As another configuration embodiment showing the lower flange of the positive moment section, the lower flange of the positive moment section is configured as a closed cross-section, but a rib is provided on the upper surface of the closed cross-section of the lower flange, or the lower flange is horizontally bent upward or horizontally downward It is characterized in that the bent reinforcing end is provided.

The positive moment section of the girder is characterized in that compared to the negative moment section of the girder, the spaced distance of the abdomen on both sides is shortened and installed.

In the present invention, a mortar filling groove is formed in the upper flange of the negative moment section in which the upper tension is generated so that the concrete mortar is closely synthesized, and the lower flange of the negative moment section is the section where the pedestal device is installed. "The beam steel is arranged to increase the rigidity, and the section beyond the pedestal can be effectively supported by resisting according to the distribution of the bending moment of the girder, such as the concrete mortar layer can respond to the compressive force. Compared to the negative moment section of the girder branch, the positive moment section can be installed by shortening the spaced distance of the abdomen arranged on the left and right sides on the plane, thereby reducing the amount of steel required and providing a steel box girder bridge that can be designed economically has the effect of

1 is a front view schematically showing a positive moment section and a negative moment section of a steel box girder bridge according to the present invention.
2 is a cross-sectional view showing a positive moment section and a negative moment section of a steel box girder bridge according to the present invention;
Figure 3 is a cross-sectional view showing the configuration of the section of the fulcrum section in which the pedestal device is installed in the negative moment section of the steel box girder bridge according to the present invention.
4 is a cross-sectional view taken along line “A-A” of FIG. 3;
Figure 5 is a cross-sectional view showing the configuration of the section outside the pedestal device in the negative moment section of the steel box girder bridge according to the present invention.
6 is a cross-sectional view showing the positive moment section of the steel box girder bridge according to the present invention.
7 to 9 are cross-sectional views of another configuration embodiment showing the positive moment section of the steel box type girder bridge according to the present invention.
10 is a plan view showing a positive moment section and a negative moment section of a steel box girder bridge according to the present invention;
11 is a bottom view showing a positive moment section and a negative moment section of a steel box girder bridge according to the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail. In the description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

The steel box girder bridge according to the present invention includes an abdomen (10) disposed on the left and right at regular intervals, an upper flange (20) horizontally disposed on the upper portion of the abdomen (10), and the abdomen (10). The slab 80 is constructed by pouring concrete on the upper part of the steel box-shaped girder G composed of the lower flange 30 connected horizontally between the lower left and right sides.

That is, in the state where the girder G is disposed as shown in FIGS. 1 and 2 , the point part of the girder G is the negative moment section B in which the upper tension is generated, and the central part of the girder G generates the lower tension. It consists of a positive moment section (A).

In the present invention, the upper flange 20 of the negative moment section (B) is formed with a closed cross-section 40, and the mortar filling groove 60 formed by bending downward at regular intervals on the upper flange 20 is formed, and the upper The upper surface of the flange 20 has a configuration in which stud bolts 62 are installed.

In addition, the lower flange 30 of the negative moment section (B) is formed with an open cross-section (50), and the upper surface central portion of the lower flange (30) located in the fulcrum section (P) where the pedestal device is installed is “H” The beam steel 64 is disposed, and stud bolts 62 are installed on the upper surface of the lower flange 30 located in the section S outside the seat arrangement.

And, the upper flange 20 of the positive moment section (A) is formed with an open cross-section 50 in which the stud bolt 62 is formed, and the lower flange 30 is provided with an open cross-section 50 to the girder (G). While supporting efficiently by resisting according to the distribution of the acting bending moment, the installation interval of the abdomen 10 on both sides of the positive moment section (A) is to have a margin against stress.

The negative moment section (B) of the girder (G) has a narrow mortar filling groove (60) that is opened upward by bending the upper flange (20) downward at regular intervals while the upper flange (20) has a closed cross section (40). ) is formed in the longitudinal direction of the girder and poured on the upper flange 20 so that the concrete mortar constituting the slab 80 can be closely synthesized by the mortar filling groove 60, and the lower flange 30 is It is formed with an open cross-section 50 and a truss-shaped horizontal bracing 72 is attached to cope with the torsion.

That is, as shown in FIGS. 3 and 4, the "H" beam steel 64 is disposed on the upper surface of the lower flange 30 located in the fulcrum section P where the seat device of the negative moment section B is installed, so that the rigidity Concrete mortar formed by pouring concrete mortar to a certain height by installing stud bolts 62 on the upper surface of the lower flange 30 located in the section S outside the pedestal as shown in FIG. The layer 80 is adapted to counteract the compressive force.

The positive moment section (A) of the girder (G) has an open cross-section (50) in which the upper flange (20) is open, and the lower flange (30) is provided in an open cross-section (50), as shown in FIGS. 6 to 9 . However, the lower flange 30 is composed of a double plate (30a) to increase the rigidity.

And, Figures 7 to 9 is another configuration embodiment showing the lower flange 30 of the positive moment section (A), the lower flange 30 of the positive moment section (A) is composed of a closed section 40, but 7, a plurality of longitudinal ribs 66 are arranged in the longitudinal direction of the girder G on the upper surface of the closed cross-section 40 of the lower flange 30 to correspond to the lower tension.

In addition, FIGS. 8 and 9 show the lower flange 30 of the positive moment section A as a closed cross-section 40, but the lower flange 30 is horizontally bent upward or horizontally downward. 68) to cope with the lower tension and increase the rigidity.

This invention corresponds to a point portion corresponding to the negative moment section (B) in which the upper tension of the girder (G) is generated, and the positive moment section (A) in which the lower tension of the girder (G) is generated, as shown in FIG. According to the distribution of the bending moment in the central part, it is possible to resist and efficiently support it, and these girders are interconnected by the cross beams (70).

And, the positive moment section (A) of the central part of the girder (G) is provided so that the installation interval of the both sides of the abdomen (10) has a margin compared to the stress, which is the positive moment section (A) of the central part of the girder (G) is the girder (G) ) Compared to the negative moment section (B) of the point part, it is possible to install by shortening the spaced interval of the abdomen (10) disposed on the left and right sides on the plane.

That is, the abdominal installation interval (D2) of the positive moment section (A) shown in FIG. 6 can be shortened compared to the abdominal installation interval (D1) of the negative moment section (B) shown in FIG. 3, thereby reducing the amount of steel required be able to do

In addition, as shown in FIG. 10 , at the point where the abdomens 10 on the left and right sides of the positive moment section (A) are connected to the left and right abdomens 10 of the negative moment section (B), the positive moment section (A) and By making the width of the abdomen 10 of each of the negative moment sections (B) the same, abrupt changes in the cross section during connection of each moment section are alleviated and stress concentration is not caused in these parts.

As such, in the steel box girder bridge according to the present invention, the point portion corresponding to the negative moment section (B) in which the upper tension of the girder (G) occurs, and the positive moment section (A) in which the lower tension of the girder (G) is generated. It is provided so that it can be efficiently supported by resisting according to the distribution of the bending moment in the corresponding central part.

In addition, since the positive moment section (A) of the central part of the girder (G) has a configuration in which the installation intervals of both sides of the abdomen have a margin against the stress, the positive moment section (A) of the central part of the girder (G) is the negative moment section of the girder (G) point Compared to (B), it is possible to shorten the spaced interval of the abdomen 10 disposed on the left and right sides on the plane, so that it is possible to design economically while reducing the amount of steel required.

Although the present invention has been described above with reference to the above embodiments, it goes without saying that various modifications are possible within the scope of the technical spirit of the present invention.

A: Positive moment section B: Negative moment section
C : Concrete mortar layer D1, D2 : Abdominal installation interval
G : Girder P : Section at the point where the pedestal device is installed
S: Section out of the seat belt 10: Abdomen
20: upper flange 30: lower flange
30a: double plate 40: closed cross section 50: open cross section 60: mortar filling groove 62: stud bolt 64: "H" beam steel 66: rib 68: reinforcing end 70: cross beam 72: bracing 80: slab

Claims (4)

Abdomen 10 disposed on the left and right at regular intervals, an upper flange 20 horizontally disposed on the upper part of the abdomen 10, and a lower flange 30 horizontally disposed on the lower part of the abdomen 10 It consists of a girder (G) made of, a negative moment section (B) in which upper tension is generated in a state in which the girder (G) is disposed, and a positive moment section (A) in which the lower tension of the girder (G) is generated.
The upper flange 20 of the negative moment section (B) is formed of a closed cross-section 40, and the mortar filling groove 60 formed by bending downward at regular intervals on the upper flange 20 is formed, and the upper flange 20 ) the upper surface of the stud bolt 62 is installed and,
The lower flange 30 of the negative moment section (B) is formed of an open cross-section (50) and is made of “H” beam steel in the center of the upper surface of the lower flange 30 located in the section P of the point where the pedestal device is installed. (64) is arranged, and the stud bolt 62 is installed on the upper surface of the lower flange 30 located in the section (S) out of the seat arrangement,
The upper flange 20 of the positive moment section (A) is formed of an open cross-section (50) formed with a stud bolt (62), and the lower flange (30) is a steel phase, characterized in that it is provided with an open cross-section (50) shaped girder bridge.
delete delete The method of claim 1,
The positive moment section (A) of the girder (G) is a steel box type girder bridge, characterized in that compared to the negative moment section (B) of the girder (G), the spaced distance between the abdomens (10) on both sides is shortened and installed.

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