KR101190669B1 - Steel momposite girder module and construction method of steel momposite girder bridge using the same - Google Patents

Abstract

The present invention relates to a steel composite girder module and a method for constructing a steel composite girder bridge using the same.

The composite girder module according to an embodiment of the present invention includes a center girder of a reinforced concrete structure disposed at a central position of a bridge at right angles to a bridge and an end girder of reinforced concrete structures disposed at both end positions of the central girder. Including, the center girder is disposed in the center of the center girder and is provided with a support surface for supporting the bottom plate of the bridge at the top and bent to form both ends coupled to the first reinforcement concrete portion provided at the bottom of the center girder And a second steel material disposed on both sides of the first steel material and having a support surface at an upper portion thereof, and having one end bent so as to be synthesized at the first reinforcement concrete portion, wherein the end girder has a support surface at an upper portion thereof. It is provided and bent so that one end is coupled to the lower side of the second reinforcement concrete portion provided in the end girder and the other end is coupled to the second steel With the third steel material, the central girder, both ends of the bent first steel can be coupled to the first reinforcement concrete portion to form a reinforcement structure of the closed cross-sectional shape.

Composite girder, formwork, stranded wire, bottom plate, connecting member

Description

STEEL MOMPOSITE GIRDER MODULE AND CONSTRUCTION METHOD OF STEEL MOMPOSITE GIRDER BRIDGE USING THE SAME}

The present invention relates to a rigid composite girder module and a method of constructing a composite girder bridge using the same, which are integrally provided with a structure for placing a bottom plate, while resisting an applied load.

In general, the composite girder is a structure in which the steel and the concrete member are combined to form a girder of the bridge.

In such a structure of the composite girder, the steel is coupled to the upper portion of the concrete constituting the lower casing to form a steel composite girder, the structure that can reduce the mold height by the structure in which the upper flange area of the beam is embedded in the bottom plate concrete. Is known.

However, there is a disadvantage in that the cost of producing a steel of a structure such as an i-shaped steel is high.

In addition, in the case of the conventional rigid girder, after mounting on the lower structure of the bridge, the work of the formwork for placing the bottom plate must be made separately. In this case, materials such as formwork for placing the bottom plate is required separately, and additional costs are incurred due to the formwork.

Moreover, since the work of the formwork is performed in a high sky, not only the possibility of occurrence of safety accidents of the worker is high but also the work itself is not easy, so there is a disadvantage in that it is difficult to shorten the construction period.

The present invention is made by recognizing at least one of the needs or problems occurring in the composite girder provided in a conventional bridge.

One object of the present invention is to minimize the separate formwork for placing the bottom plate concrete installed on top of the composite girder.

Another object of the present invention is to allow the steel itself constituting the composite girders to be a structure that resists the working load while acting as a formwork for placing the bottom plate.

Another object of the present invention is to enable the omission of additional processes for placing the bottom plate concrete to shorten the site air.

The composite girder module and the method for constructing a composite girder bridge using the same according to an embodiment for realizing at least one of the above problems may include the following features.

The present invention is basically based on a structure in which the steel constituting the composite girder is configured to function as a formwork and remain as a structure that resists a working load.

The composite girder module according to one embodiment of the present invention includes a center girder of a reinforced concrete structure disposed at a central position in a right angle direction of a bridge's bridge, and an end girder of reinforced concrete structures disposed at both end positions of the center girder. ; Including, the central girder is disposed in the center of the central girder and provided with a support surface for supporting the bottom plate of the bridge at the top and bent to form both ends coupled to the first reinforcement concrete provided at the bottom of the central girder And a second steel material disposed on both sides of the first steel material and having a support surface at an upper portion thereof, and having one end bent so as to be synthesized at the first reinforcement concrete portion. And a third steel member having one end portion coupled to a lower side of the second reinforcement concrete portion provided at the end girder and the other end portion being bent so as to be coupled to the second steel member. Both ends of the first steel may be coupled to the first reinforcement concrete to form a reinforced cross-sectional reinforcement structure.

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On the other hand, the center girder, the reinforcing bar is disposed between the first steel and the second steel, the one end portion is embedded in the first reinforcement concrete portion provided in the lower portion of the center girder;

On the other hand, for introducing the prestress may include a strand wire provided inside the first reinforced concrete portion and the second reinforced concrete portion provided in the central girders and the end girders.

Steel composite girder bridge construction method using a composite girder module according to another embodiment of the present invention, is provided with a support surface for supporting the bottom plate of the bridge on the upper portion and both ends are coupled to the first reinforced concrete portion provided at the lower portion A first girder bent; and a second girder disposed on both sides of the first steel and having a support surface at an upper end thereof and bent to be synthesized at one end thereof in the first reinforcement concrete portion. And a third steel material having a support surface at an upper portion thereof and a bent portion formed at one end thereof to be coupled to a lower side of the second reinforcement concrete portion; and manufacturing an end girder including the central girder and the end girder to the bridge lower structure. A bottom plate formwork forming step of forming a bottom plate formwork by mounting the other end portion of the second steel material and the other end portion of the third steel material; And placing concrete in the bottom plate formwork formed by the first steel and the second steel and the third steel of the end girder to form a bottom plate, wherein the central girder is formed of the bent first steel. Both ends may be coupled to the first reinforcement concrete to form a reinforcement structure having a closed cross section.

In this case, the manufacturing step of the central girder, the reinforcing bar is disposed between the first steel and the second steel, the one end portion is embedded in the first reinforced concrete portion provided in the lower portion of the central girder; have.

On the other hand, in the manufacturing step of the center girder and the end girder, it is possible to further arrange the strand provided in the first reinforced concrete portion and the second reinforced concrete portion provided in the central girder and the end girder for the introduction of prestress. .

On the other hand, the bottom plate formwork forming step, it is possible to combine the other end of the second steel and the other end of the third steel using a connecting member.

As described above, according to the present invention, a separate formwork can be minimized for placing the bottom plate concrete installed on the upper portion of the composite girder.

In addition, according to the present invention, the steel itself constituting the composite girder can be maintained as a structure that resists the working load while acting as a formwork for placing the bottom plate concrete.

In addition, according to the present invention, it is possible to omit the additional process for placing the bottom plate concrete to shorten the site air.

In order to help the understanding of the features of the present invention as described above, it will be described in more detail with respect to the composite girder module and the method of constructing a composite girder bridge using the same according to an embodiment of the present invention.

Hereinafter, exemplary embodiments will be described based on embodiments best suited for understanding the technical characteristics of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, It is to be understood that the present invention may be implemented as illustrated embodiments.

Accordingly, the present invention may be modified in various ways within the technical scope of the present invention through the embodiments described below, and such modified embodiments fall within the technical scope of the present invention.

And, in order to help the understanding of the embodiments described below, in the reference numerals described in the accompanying drawings, among the components that will have the same function in each embodiment, the related components are denoted by the same or extension numbers.
In addition, hereinafter, for convenience of description, the first reinforcement concrete portion 111 is referred to as concrete 111 and the second reinforcement concrete portion 121 is referred to as concrete 121. In addition, hereinafter, for convenience of description, 'first steel 114a is made of steel 114a', 'second steel 114b is made of steel 114b', and 'third steel 124 is made of steel ( 124) 'will be described.

Embodiments related to the present invention are basically based on that the steel constituting the composite girder is configured to be able to survive as a structure to resist working loads while functioning as a formwork.

As shown in Figure 1 and 2, the composite girder module (110, 120) according to an embodiment of the present invention is a central girder 110 and the central girder 110 mounted on the lower structure (not shown) of the bridge It may be configured to include an end girder 120 disposed on both sides with respect to.

In this case, the concrete 111 of the central girder 110 is composed of a structure in which the concrete 111, in which the reinforcing bars 112 are installed, is mounted on the lower structure of the actual bridge. In addition, steels 114a and 114b may be synthesized on top of the concrete 111 to replace the formwork for placing the bottom plate concrete.

That is, the structure consisting of the reinforcing steel 112 and the concrete 111, such as RC structure is mounted on the lower structure of the bridge, the steel (114a, 114b) is one end embedded in the concrete 111, the bottom plate ( While forming a part of the 140 may be made of a structure that substantially supports the bottom plate 140.

In this case, the steels 114a and 114b constituting the center girder 110 may be formed in a structure in which one end is embedded in the concrete 111 which is a structure mounted on the lower structure. In addition, the steel material 114a disposed in the center portion may be formed of a closed cross-sectional structure, and the steel material 114b of the side may be formed of an open cross-sectional structure and disposed at both sides of the steel 114a of the closed cross-sectional structure.

On the other hand, each of the steel (114a, 114b) may be provided with a support surface on which the bottom plate 140 can be mounted. In addition, the reinforcing bars 115 may be further disposed between the steels 114a positioned at the center and the steels 114b disposed at both sides, thereby improving durability.

In more detail, as described below, the steels 114a and 114b exist together with the concrete 141 while serving as formwork for placing the concrete 141 to form the bottom plate 140. It may be made of a structure. In this case, the reinforcing bar 115 may be further placed between the steels 114a and 114b to increase durability.

On the other hand, the end girder 120 is made of a structure in which the concrete 121, which is reinforced with reinforcing bars 123, is mounted on the lower structure of the bridge substantially like the center girder 110, and made of steel 124 One end of the) may be coupled in a state of being embedded in the concrete 121. In this case, the steel 124 of the end girder 120 may be made of an open cross-sectional structure, a support surface on which the bottom plate 140 may be mounted.

As shown in FIG. 2, the end girder 120 has an upper region of one side of the concrete 121 that serves as formwork when the concrete 141 is formed for the formation of the bottom plate 140. It may be configured in a shape extending in the same upper direction as). In addition, between the region extending in the upper direction of the concrete 121 and the steel 124, reinforcing bars (not shown), such as the center girder 110 may be further reinforced.

The center girder 110 and the end girder 120, which may be configured in this way, are mounted on the lower structure of the bridge, and the ends of the respective side steels 114b and 124 of the open cross-section structure are connected to each other to form the center girder 110. Each steel 114a, 114b, 124 of the end girder 120 and the end girder 120 may serve as a structure for placing the bottom plate 140. And, each of the steel (114a, 114b, 124) is still present after the concrete 141 to form the bottom plate 140 to support a portion of the bottom plate 140 and the bottom plate 140 ( A part of 110 and 120 may be configured.

On the other hand, the concrete 111 of the central girder 110 and the concrete 121 of the end girder 120 may be further provided with strands 113, 123 for the introduction of prestress. In this case, since the structure to which the strands 113 and 123 are applied is possible by a generally known configuration for introducing prestress into a general RC structure, a detailed description thereof will be omitted.

Referring to the process of constructing the composite girder bridge 100 using the above-described composite girder module (110,120), the center girder 110 and the end as described on the basis of Figures 1 and 2 on the upper structure After the girder 120 is manufactured to establish a lower structure (not shown) of the initial bridge, the center girder 110 and the end girder 120 are mounted on the upper portion of the lower structure.

In this case, the manufacturing process of the center girder 110 and the end girder 120 may be made as described for the structure. Therefore, detailed description thereof will be omitted.

After the center girder 110 and the end girder 120 is mounted on the lower structure, the ends of the steels 114b and 124 having the open cross-sectional structure are coupled to each other. For example, as shown in FIG. 3, the open end of the steel 114b of the center girder 110 and the open end of the steel 124 of the end girder 120 are coupled using the connection member 130. Alternatively, the open ends of the respective steels 114b and 124 may be directly coupled to each other.

On the other hand, when the width of the bottom plate 140 is large, a plurality of central girders 110 may be mounted on the bridge lower structure. In this case, coupling may be made between the open ends of each side steel 114b between the center girders 110.

In this case, in order to minimize the prevention of leakage when placing the concrete 141 constituting the bottom plate 140 may be combined by a welding method or a fastening method using a bolt or the like.

Forming for concrete placing for forming the bottom plate 140 by the steel (114a, 114b, 124) of the center girder 110 and the end girder 120 may be formed.

On the other hand, the reinforcing bars 142 for constituting the bottom plate 140 may be placed in the concrete casting form for forming the bottom plate 140 formed by each of the steel (114a, 114b, 124). In this case, the reinforcing bar 142 for forming the bottom plate 140 is structurally stable so that the reinforcement is made in a state connected with the reinforcing bar 115 disposed between each of the steel (114a, 114b, 124) It can also be increased.

Each of the steels 114a, 114b, and 124 configured as described above is poured concrete 141 to form the bottom plate 140 to form the bottom plate 140. In this case, the concrete 141 may be poured into a space between the steels 114a, 114b, and 124 to form a structure for supporting the bottom plate 140 together with the steels 114a, 114b, and 124.

Meanwhile, the strands 113 and 123 provided in the concrete 111 and 121 of the center girder 110 and the end girder 120 may allow prestress to be introduced before the concrete 141 is formed to form the bottom plate 140. .

By the configuration of the steel (114a, 114b, 124) as described above, the production of formwork, etc. for forming the bottom plate 140 is not required separately can shorten the air, the steel of the steel that serves as the formwork ( It can be seen that 114a, 114b, 124 itself can be present as a structure that supports the girder and the bottom plate and the bottom plate.

The composite girder module and the method of constructing a composite girder bridge using the same according to the present invention are not limited to the above-described embodiments, but all or some of the embodiments may be selectively combined for various modifications. It may be.

1 is a cross-sectional view schematically showing the structure of a central girder constituting a composite girder module according to an embodiment of the present invention.

2 is a cross-sectional view schematically showing the structure of the end girders constituting the composite girder module according to an embodiment of the present invention.

3 is a cross-sectional view schematically showing the configuration of a composite girder bridge constructed using a composite girder module according to an embodiment of the present invention.

* Description of the main parts of the drawings *

100 ... Composite girder bridge 110 ... Center girder

111 ... 1st reinforced concrete section 115 ... reinforcing bars
121 ... 2nd reinforced concrete section 112,122,142

113,123 ... strand 114a ... first steel
114b ... Second Steel 124 ... Third Steel

130 ... connecting member 140 ... bottom plate

Claims (7)

A center girder of a reinforced concrete structure disposed at a center position in a direction perpendicular to the bridge axial direction of the bridge; And End girders of reinforced concrete structures disposed at both end positions of the central girders; , ≪ / RTI & The central girder may include: a first steel material disposed at a center of the central girder and having a support surface supporting a bottom plate of a bridge at an upper portion thereof and bent to couple both ends to a first reinforcement concrete portion provided at a lower portion of the central girder; And a second steel material disposed on both sides of the first steel material and having a support surface thereon, and having one end bent to be synthesized in the first reinforcement concrete portion. The end girders are provided with a supporting surface on the upper portion of the second reinforcement concrete portion provided in the end girder, one end is coupled to the other end is bent and formed so that the other end is coupled to the second steel; The central girder is a composite girder module, wherein both ends of the bent first steel are coupled to the first reinforcement concrete to form a reinforced cross-sectional reinforcement structure. The method of claim 1, wherein the central girder And a reinforcing bar disposed between the first steel and the second steel, and having one end embedded in a first reinforcing concrete part provided at a lower portion of the center girder. The method of claim 1, And a stranded wire provided inside the first reinforced concrete part and the second reinforced concrete part provided in the center girder and the end girder to introduce prestress. A first steel material having a support surface supporting a bottom plate of a bridge at an upper portion thereof and bent to couple to a first reinforcement concrete portion provided at both ends thereof; and a support surface disposed on both sides of the first steel material and supported on an upper portion thereof. Manufacturing a central girder having a second steel material having one end bent to be synthesized in the first reinforced concrete part; Producing an end girder having a third steel material having a support surface in the upper portion and bent to be coupled to one end to the lower side of the second reinforcement concrete portion; A bottom plate form forming step of mounting the center girder and the end girder on a bridge undercarriage, and forming a bottom plate formwork by combining the other end of the second steel and the other end of the third steel; And And placing concrete on the bottom plate formwork formed by the first and second steels of the central girder and the third steel of the end girder to form a bottom plate. The central girder, the composite girder bridge construction method using a composite girder module that is coupled to both ends of the bent first steel to form a reinforced cross-sectional reinforcement structure of the first reinforced concrete portion. According to claim 4, wherein the manufacturing step of the central girders The steel composite is disposed between the first steel and the second steel, the reinforcing reinforcing bar is embedded in the first reinforcement concrete portion provided at one end of the lower portion of the central girder; Girder bridge construction method According to claim 4, wherein the manufacturing step of the center girders and end girders A method of constructing a rigid girder bridge using a rigid girder module further comprising disposing a strand provided in the first reinforced concrete part and the second reinforced concrete part provided in the center girder and the end girder to introduce prestress. . The method of claim 4, wherein the bottom plate formwork forming step A method of constructing a steel composite girder bridge using a steel composite girder module characterized in that the other end of the second steel and the other end of the third steel are coupled using a connecting member.

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