KR100679664B1 - Steel framed girder and slab structure for bridge and the construction method - Google Patents

Abstract

A steel framed girder bridge installation structure and a construction method is provided to favorably improving the structural efficiency of a member by using a lateral beam functioning a lateral beam and a structure member embedded in a slab. A steel framed girder bridge installation structure comprises a longitudinal beam(220) additional and longitudinally installed on an upper surface of a girder(100); and a lateral beam laterally formed between the upper surface of the girder, and connected with the lateral beam in a lattice shape. A frame structure(200) including the lateral beam and the longitudinal beam is embedded in a slab concrete formed on the upper surface of the girder. The girder is a steel beam and having the lateral beam which is also a steel beam on the upper surface. The slab concrete is communicated through a through-hole formed at a lower part of the longitudinal beam.

Description

Steel frame girder bridge installation structure and construction method {STEEL FRAMED GIRDER AND SLAB STRUCTURE FOR BRIDGE AND THE CONSTRUCTION METHOD}

1A and 1B show a plate girder bridge and a slab in which a steel beam is installed, in which a conventional crossbeam or bracing material is installed.

Figure 2a shows a mold in which the longitudinal beam of the present invention is installed,

2B and 2C show examples of the transverse beam of the present invention,

3A and 3B illustrate examples of a state in which the frame assembly of the present invention is installed in a mold.

4 is a sectional view showing a girder bridge installation structure according to the present invention.

<Description of Symbols for Main Parts of Drawings>

100: mold 210: transverse beam

220: longitudinal beam 200: frame assembly

300: slab concrete

The present invention relates to a steel frame girder bridge installation structure and its construction method. More specifically, the present invention relates to a girder bridge construction method for forming a slab on a bridge girder (mold).

In the case of a plate girder bridge in which a mold (GIRDER), which is manufactured in the form of a steel beam 10 having a conventional I-shaped cross section, is installed on a pier or alternately, and a slab concrete 20 is formed on the mold, the point of optimal design is as small as possible. While the molds could be installed, the focus was not to increase the height of the bridge.

Therefore, a method of using a steel beam made of high-quality rolled steel having excellent rigidity when manufacturing the steel beam 10 has been introduced several years ago, and has been used as a girder for long bridges.

Usually, the bridge girder as described above is installed a plurality of steel beams 10 in the longitudinal direction on the pier or the alternating upper surface as shown in Figure 1a, and then restrained in the transverse direction using a crossbeam or bracing material (30) By using steel dies, etc., the slab concrete 30 is placed on the steel beams 10 and cured to complete the bridge.

The steel beam 10 is a steel beam 10, which is a rolled steel product with a quality that can be used as a girder for bridges, but there is an advantage to simplify the work because it can be purchased as a ready-made product as it is, it is quite expensive There was a problem that the use is limited because of the problem.

In addition, the bracing material 30 has a problem that it is somewhat inefficient in terms of its effectiveness because the brazing material 30 functions only as a fall prevention and distortion prevention when installing the steel beam 10 and does not bear a load acting on the mold.

In addition, in Fig. 1b is introduced a precast slab 40 in which the section steel 41 is embedded in the transverse direction, which reduces the workability, such as installation of slab formwork for the construction of the slab, reinforcement for the slab, curing work, etc. In order to eliminate the type of work, the shape steel 41 is embedded in the slab concrete in advance, so that the shape steel 41 can replace the reinforcing bar of the slab concrete.

This precast slab 40 is to be connected to each other in the transverse direction directly to the upper surface of the piers 50 to be constructed.

However, the precast slab 40 has a problem that the shape steel 41 is installed only in the lateral direction, and thus acts as a one-way slab, so that the efficiency of dispersion and effective resistance to the working load may be somewhat inefficient. Therefore, there is a need to develop technology for the installation of economical and constructable girder bridges by structurally more effective installation structure.

An object of the present invention, in the construction of the plate girder bridge, to more effectively distribute and resist the load acting on the slab, while minimizing the increase in the BRIDGE DEPTH, can be economically constructed and excellent in construction It is to provide a steel frame girder bridge installation structure and its construction method.

The present invention to achieve the above technical problem,

First, the present invention allows the frame assembly 200 of the lattice form as a steel beam on the upper surface of the mold 100, such a frame assembly (200, steel frame consisting of a longitudinal beam and a transverse beam) is slab concrete It is embedded in 300 to be synthesized with each other to be constructed.

To this end, the present invention to form the frame assembly 200,

A transverse beam 210, which is a rolled steel in the transverse direction, is installed on the upper surface of the mold 100, and the longitudinal beam 220 is transversely formed together with the transverse beam 210 to form a lattice-shaped frame assembly 200. To be installed between the directional beams 210,

The horizontal beams 210 and the longitudinal beams 220 are embedded in the slab concrete 300 as the frame assembly 200 of the grid shape to each other, eventually reducing the amount of rebar for slab construction and the thickness of the slab In addition to enabling the reduction of slab weight due to

The transverse beam 210 and the longitudinal beam 220 properly distributes the load acting on the slab in both the transverse and longitudinal directions, and finally transmits the load to the mold to enable effective load resistance. do.

Second, in the case of the transverse beam 210 using a steel beam of the I-shaped cross-section between the mold and the mold so that the abdomen further extends downwards without the lower flange portion, the extended abdominal side is the abdomen of the mold 100 By being coupled to the stiffeners installed in the conventional crossbeam can also play a role.

In addition, such a lateral beam 210 is to be manufactured in the factory in advance in a structure set between the mold and the mold in order to facilitate the construction so that the workability can be improved.

Third, in the case of the longitudinal beam 220 constituting the frame assembly 200 to be integral to the mold upper surface in the longitudinal direction, but using a steel beam such as rolled steel to increase the overall height of the mold 100 as a result The rigidity of the mold 100 is increased, and the longitudinal beam 220 installed in the mold 100 is embedded in the slab concrete 300 to act as a factor of increasing the bridge type as the overall height increases. Not to.

Fourth, in the case of the longitudinal beam 220 as described above by using a rolled steel products commonly sold to enable more economical bridge production, the longitudinal beam 220 and the transverse beam 210 is eventually slab By acting as a reinforcing member for reinforcement in concrete, the amount of reinforcing bars to be embedded in slab concrete can be reduced, and the amount of slab concrete can also be reduced, thereby reducing the weight of the slab that occupies a large part of the bridge load.

BRIEF DESCRIPTION OF DRAWINGS To describe the present invention more clearly and easily, the following describes the best embodiments of the present invention in detail with reference to the accompanying drawings, and embodiments according to the present invention may be modified in various other forms, and thus the scope of the present invention. Is not limited to the embodiment described below.

2A, 2B and 2C show examples of a mold and a transverse beam in which the longitudinal beam of the present invention is installed,

3A and 3B illustrate examples of a state in which the frame assembly of the present invention is installed in a mold;

4 is a sectional view showing a girder bridge installation structure according to the present invention.

First, the bridge substructure including the bridges and bridges for the bridge installation is first constructed in a predetermined position.

In the bridge substructure, the mold 100 of the present invention is first provided with a plurality in the longitudinal direction.

The mold 100 is described with reference to the steel plate girder of the I-shaped cross section for convenience as shown in FIG. 2A, but is not necessarily limited thereto.

At this time, the mold 100 may be formed of the upper, lower flange and the abdomen, but the horizontal reinforcement plate 130 may be further formed on the bottom of the lower flange, but in particular, the I-shaped cross section is used by using a rolled steel. This can reduce the labor and cost of manufacturing.

The mold 100 is spaced apart in the transverse direction according to the width of the bridge is installed in such a way that a plurality of molds are mounted on the upper surface of the lower bridge structure in the longitudinal direction, the abdomen a plurality of stiffeners 110 in the form of vertical and / or horizontal plates , Some kind of reinforcement) is installed spaced apart.

The longitudinal beam 220 of the present invention is pre-installed on the upper surface of the mold 100, that is, the upper flange upper surface.

The longitudinal beam 220 may use a rolled steel having a width slightly smaller than the width of the upper flange of the mold 100, and may be structurally integrated with the mold 100 by welding or the like. Allow them to act in one piece.

At this time, the through-hole 221 is formed in the abdomen of the longitudinal beam 220, so that the slab concrete 300 can be communicated.

The mold 100 in which the longitudinal beam 220 is integrated on the upper surface of the mold 100 increases the mold 100 height by adding the height of the longitudinal beam 220 to the original mold height as a whole.

By increasing the height, the rigidity (particularly the bending rigidity) of the mold 100 is greatly increased, and the cross-beams 210 to be described later are connected to each other to form the frame assembly 200 having a lattice shape.

In addition, the longitudinal beam 220 is installed on the upper surface of the mold in a divided state so that the horizontal beam 210, which will be described later on the upper surface of the mold 100 to be cross-connected.

Since the mold 100 in which the longitudinal beam 220 is integrated has a fear of conduction in a state in which the longitudinal beam 220 is mounted, a conventional cross beam or bracing material is usually installed between the mold and the mold abdomen as shown in FIG. 1A.

However, such cross beams or bracing materials have not only a very low workability, but also have a structure that does not share the load, so the efficiency of the installation cost is inevitably deteriorated.

In the present invention, while acting as a normal cross beam, the load acting on the slab can also be structurally dispersed in the mold, while being embedded in the slab to function as an internal reinforcement of the slab concrete 300, the transverse beam 220 of the present invention Will be installed.

The transverse beam 220 is simply connected to the longitudinal beam 210 in a lattice form with the longitudinal beam 210 in the transverse direction between the mold and the mold upper surface using a rolled steel having the same I-shaped cross section as the longitudinal beam 210. Can be installed.

Accordingly, the longitudinal beam 220 and the transverse beam 210 are installed on the upper surface of the mold as the frame assembly 200 having a lattice shape, and the overall size thereof will be determined according to the width of the slab.

The frame assembly 200 is formed to be formed on the mold upper surface, but is installed to be embedded in the slab concrete 300 as shown in FIG.

As a result, when the slab is referred to as a reference, the longitudinal beam 220 and the transverse beam 210 are embedded in a lattice form to function as a structural member capable of resisting the load acting on the slab. By embedding in the reinforcement can be replaced conventionally reinforcement can be omitted a significant amount of reinforcing reinforcement work complex.

In addition, the slab has the advantage of being able to reduce the thickness of the slab that takes up most of the slab's own weight. do.

As a result, the slab according to the present invention is formed to a thin thickness can reduce the slab load can effectively reduce the cross-sectional size of the mold to support the slab,

Since the longitudinal beam 220 is also installed in the slab is buried in a way that the height of the bridge does not become large, it is possible to be free to limit the bridge height,

Not only can a large amount of rebar reinforcement work for a complex slab can be omitted, but also a more efficient mold cross-section design can be achieved by distributing the working load by the frame assembly 200, and ultimately, the number of mold installations can be reduced.

The use of high-quality rolled steel can reduce the number of molds and allow the construction of longer bridges.

Particularly, in the case of the transverse beam 210, as shown in FIGS. 2B and 2C, the reinforcement member 214 including the L-shaped steel is further installed on the upper abdomen, thereby replacing the transverse reinforcement shortened by the installation of the transverse beam 210. You can do it.

The frame assembly 200 composed of the longitudinal beam 220 and the transverse beam 210 may be manufactured at the factory first and installed on the mold upper surface by welding.

Preferably, in consideration of construction convenience, etc., first, the mold 100 in which the longitudinal beam 220 is installed is installed in the bridge lower structure,

The longitudinal beam 220 is installed so as to form a separation space by cutting the longitudinal beam 220 so that the horizontal beam 210 can be cross-installed, the horizontal beam 210 in the separation space and the mold To be installed in the transverse direction on the upper surface of the mold.

As a result, the longitudinal beam 210 and the transverse beam 210 are cross-connected with each other, and the method of connecting both beams may include bolts or bolts on an upper surface of the longitudinal beam and the transverse beam. The method may be used.

In this case, the shape of the transverse beam 210 may be deformed so that the mold may be more stably installed between the molds in the transverse direction, while ensuring a sufficient role as a conventional cross beam.

In other words, the horizontal upper portion is to be embedded in the slab concrete, and the lower portion is to serve as a conventional crossbeam.

Specifically, as shown in FIGS. 2B and 3A, instead of the lower flange of the transverse beam 210, the abdomen 211 extends further downward between the mold 100 and the mold 100, but the lower part of the abdomen has a horizontal plate 212. The side of the abdomen can be coupled to each other by using a bolt and a nut (coupling tool) as a padding plate to the stiffener 110 pre-installed on the abdomen of the mold 100.

At this time, the transverse beam 210 has an abdomen 211 extending from the mold 100 to the mold 100 with a lower portion formed by a horizontal plate 212, and both sides are formed in a T-shaped cross section in advance. The produced one can be used.

When manufactured in such a shape, the transverse beam 210 may have the upper flange and the abdomen embedded in the slab concrete, and the extended abdomen may extend below the slab concrete bottom to be exposed to the outside.

Furthermore, if there are five molds installed as shown in FIG. 3A, it is preferable to separately install one transverse beam 210 having an extended abdomen installed at the outermost side.

In the case of the middle three molds, the installation of the transverse beam 210 extending one by one may be inferior in construction.

Accordingly, as shown in FIG. 2C, the three center molds are fabricated by setting two transverse beams 210 extending from the two abdomen (this is a state in which two transverse beams are continuously connected to each other). The construction of the lateralized beam 210 can be performed at a time, thereby improving workability.

Whether or not to use only the set horizontal beam 210 may be determined in consideration of the number of mold installation and site conditions.

In addition, the transverse beam 210 is a number to facilitate fastening by the upper flange portion of the mold and the mechanical bolts, nuts to be fixed in the transverse direction to the upper surface of the mold 100, which is a steel beam of I-shaped cross section The plate 213 can be installed in a number of transverse beams.

Looking at the basis of Figures 3a and 3b,

In the case of FIG. 3A, in the state in which the molds 100 in which the longitudinal beams 220 are installed are five consecutively spaced apart in the lateral direction, the two outermost molds 100 have one lateral beam 220 as shown in FIG. 2B. It can be seen that the intermediate mold is provided with a set horizontal beam 220 as shown in Figure 2c,

As a result, it can be seen that the longitudinal beam 220 and the transverse beam 210 are installed in the form of a frame assembly 200 on the mold upper surface in a lattice form.

3B is the same as FIG. 3A, but shows that the mold 100 is segmented so that the two molds can be segmented and joined to each other by bolts and nuts.

As described above, when the transverse beam 210 is installed between the longitudinal beams 220, the slab formwork for forming the slab concrete 300 is installed,

When the concrete is poured into the slab formwork, and the longitudinal beam and the transverse beam is embedded in the slab, the final slab can be completed as shown in FIG.

The slab concrete 300 is eventually composited with the longitudinal beam 220 and the transverse beam 210, which are steel materials. In order to enhance the synthesizing effect, an additional stud 120 is placed in the space of the longitudinal beam as shown in FIG. The mold 100 may be further installed on the upper surface of the mold 100, and the through-hole formed in the abdomen of the longitudinal beam may enable the composite of the slab concrete and the frame assembly 200 and the mold 100 to be more effective.

In this case, when the bridge is to be installed in a continuous bridge method, a means for reinforcing the point portion is required under the influence of the bending parent in the point portion. In the present invention, as shown in FIGS. 3A and 3B, the transverse beam 210 is provided. ) In the mold, it is possible to reduce the installation distance in the site portion so that a plurality of lateral beams 210 are concentrated in the site portion.

For example, in the case of intensively installing the lateral beams 210 on both sides based on the point part, more effective point reinforcement may be possible.

According to the girder bridge installation structure and the installation method of the present invention, it is possible to improve the rigidity of the mold while eliminating the increase factor of the bridge height, and to reduce the number of installation of the mold by the effective distribution and resistance of the load acting on the slab This makes it very economical bridge construction possible.

In addition, by manufacturing the frame assembly using the rolled steel products that can be purchased commercially, the manufacturing process is simplified and economical construction is possible, and most of the factory products are used, so quality and maintenance are very easy.

In particular, while the lateral beam plays the role of a structural member embedded in the slab while serving as a conventional cross beam at the same time, it is possible to greatly increase the structural efficiency of the member, which enables a very effective bridge construction.

An embodiment of the present invention described above and illustrated in the drawings should not be construed as limiting the technical spirit of the present invention. Those skilled in the art of the present invention can change and change the technical idea of the present invention in various forms. Therefore, such improvements and modifications fall within the protection scope of the present invention as long as it will be apparent to those skilled in the art.

Claims (11)

A longitudinal beam further integrated in the longitudinal direction on the upper surface of the mold (girder); And a transverse beam formed between the upper surface of the mold in a transverse direction, the transverse beam being connected to the longitudinal beam and in a lattice form, the frame assembly being embedded in a slab concrete formed on the upper surface of the mold. Steel frame girder bridge installation structure. The steel frame girder bridge mounting structure according to claim 1, wherein the mold is a steel beam and a longitudinal beam, which is also a steel beam, is further integrated on the upper surface. 3. The steel frame girder bridge mounting structure according to claim 2, wherein through-holes are formed in the abdomen of the longitudinal beam so that the slab concrete is in communication. According to claim 1, wherein the transverse beam is to be installed in the longitudinal direction spaced apart between the mold and the mold upper surface, wherein at least two transverse beams are installed on both sides of the branch portion for reinforcement of the branch portion Steel frame girder bridge installation structure characterized in that to be installed. 2. The lateral beam of claim 1, wherein the lateral beam uses a steel beam, wherein the abdomen of the transverse beam located between the mold and the mold extends further below the slab concrete bottom so that the side of the extended abdomen is formed in the abdomen of the mold. Steel frame girder bridge installation structure, characterized in that to be fixed to the stiffener by a coupler including a bolt and a nut. 6. The transverse beam according to claim 5, wherein in the transverse beam extending from the abdomen, the transverse beams installed between the molds are arranged between each of the molds and the molds, or at least two of which are integrally manufactured and set to be installed on the molds. Steel frame girder bridge installation structure, characterized in that can be installed by the direction beam. 6. The steel frame according to claim 5, wherein in the transverse beam in which the abdomen is extended, a reinforcement including an L-shaped steel is further attached to the transverse beam abdomen, and the reinforcement is embedded in the slab concrete. Girder bridge installation structure. 8. The steel frame girder bridge mounting structure according to any one of claims 1 to 7, wherein the longitudinal beam and the transverse beam use a roll beam as a rolled steel. Longitudinal beams made of steel beams on the upper surface of the bridge undercarriage are integrated on the upper surface and are formed transversely between the longitudinal beams and the upper surface of the molds with the molds also made of steel beams. However, the longitudinal beam is installed in the form of a grid connected to the horizontal beam made of steel beams; by installing the frame assembly in the form of a grid on the mold upper surface, Steel frame girder bridge construction method characterized in that to form a slab concrete to the frame assembly is completed bridge 10. The bolt and nut of claim 9 wherein the transverse beam allows the abdomen of the transverse beam located between the mold and the mold to extend further below the slab concrete bottom so that the side of the extended abdomen forms in the abdomen of the mold. Steel frame girder bridge construction method characterized in that to be fixed by a coupler comprising a. The transverse beam of claim 9 or 10, wherein the transverse beams provided between the molds are provided between the molds and the molds, or at least two are integrally manufactured and installed on the molds. Steel frame girders bridge construction method characterized in that the installation can be installed with a transverse beam set.

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