KR100609304B1 - Precast Composition I-Beam with Concrete Panel and Corrugated Steel Web Girder - Google Patents

Abstract

The present invention relates to a precast concrete composite i-beam, in which a concrete panel is synthesized on upper and lower portions of a steel girder made of corrugated steel to increase the cross-section stiffness of the beam, and segment it into a unit length to improve workability.

Technical configuration of the present invention for this purpose, consisting of a steel girder and the upper and lower concrete panels are synthesized on the top and bottom of the steel girder, a plurality of through holes formed in the upper and lower portions of the steel girder in the longitudinal direction of the steel girder A connecting reinforcing bar is inserted and disposed in a direction orthogonal to the connecting reinforcing bar to be embedded in the upper and lower concrete panels; The web of the steel girder is composed of a corrugated steel sheet having a corrugated shape that is curved in the longitudinal direction to improve its buckling strength; The lower concrete panel is configured to introduce a prestressing force by placing tension members on both sides of the corrugated steel sheet and tensioning in a post tension manner; Synthetic i-beam consisting of the steel girder and the upper and lower concrete panels synthesized therewith is divided into a plurality of unit lengths for one span and manufactured in a precast manner, and then each segment of the synthetic i-beam is connected at a construction site. Adjacent corrugated steel sheets are assembled to each other at the portion to be assembled.

Corrugated Steel Sheet, I-Beam, Precast, Segmentation, Factory Fabrication, Constructability

Description

Precast Composition I-Beam with Concrete Panel and Corrugated Steel Web Girder

1 is a perspective view showing a concrete composite eye beam according to an embodiment of the present invention.

FIG. 2 is a schematic perspective view of a steel girder provided in the synthetic eye-beam shown in FIG. 1.

3A and 3B are schematic side views showing an integrated shape by connecting a synthetic eye beam according to the present invention divided into a plurality.

4A to 4B are schematic cross-sectional views taken along the lines A-A and B-B in FIG. 3B, respectively.

The present invention relates to a precast concrete composite eye-beam, and more particularly, to a precast concrete composite eye-beam which synthesizes a concrete panel on the upper and lower portions of a steel girder composed of corrugated steel to increase the cross-sectional rigidity of the beam. will be.

In addition, the present invention relates to a precast concrete composite i-beam that can be integrally formed by sintering and curing the concrete at the joints of the upper and lower concrete panels while simultaneously interconnecting adjacent corrugated steel sheets by segmenting the unit length. .

Generally, there are beam bridges and box-type bridges.

Box-shaped bridge consists of corrugated steel on four sides and slab concrete is poured on the upper and lower corrugated steel sheets, or both abdomens (web) are corrugated steel sheets, and the upper and lower parts are composed of slab concrete with embedded corrugated steel sheets. Produced by The former is disclosed in Korean Patent Laid-Open Publication No. 2003-37259, and the latter is disclosed in Japanese Laid-Open Patent Publication No. 14-030614.

In particular, in the latter case, after assembling the lower slab reinforcing bar, the corrugated steel plate is erected by bracing, and then the lower slab large concrete is poured, and then the upper slab reinforcing steel is assembled to pour the upper slab concrete. do.

Such box-type bridges are expensive to construct and only apply to special large bridges, such as the complicated construction procedures and methods and the need for bracing to be installed in the temporary assembly process.

On the other hand, unlike a box-shaped bridge, the beam bridge is not a box-shaped structure, but rather a structure in which a plurality of beams are placed side by side and slaked concrete is placed on top, and the concrete eye beam and steel eye beam are applied to the beam. .

Concrete i-beams were inherently impossible to be factory-manufactured and connected in the field by dividing them into units of a certain length. The reason for this is that when the large concrete beam is divided into a plurality, the joint connection of each unit cannot be completed, and the shear at the joint is a problem.

In addition, in the case of a steel eye-beam, it is possible to divide the production into a plurality of units in the factory and connect the joints using welding or bolts in the field. However, the steel eye beams are made of steel, as well as the upper and lower flanges, all of which are very expensive, and are particularly expensive for short span bridges since prestressing, a core technology of bridge technology, cannot be introduced.

Accordingly, the present invention is proposed to provide a new concept of synthetic eye-beam that can solve this conventional problem as an eye-beam.

An object of the present invention is to increase the cross-sectional rigidity by synthesizing the concrete panel on the upper and lower parts of the steel girders consisting of corrugated steel sheet, and to produce a plant by segmenting it into a plurality of unit lengths, the construction cost is easy and the construction cost is low, It is to provide a precast concrete composite eye beam which can shorten the process and facilitate quality control.

It is another object of the present invention to provide precast concrete composite eye-beams suitable for the construction of medium to large bridges with longer spans by introducing prestressing to further strengthen each unit length connection.

Other objects, features and advantages of the invention will be more clearly understood from the embodiments set forth below.

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Technical configuration of the present invention is composed of a steel girder and the upper and lower concrete panels synthesized at the upper and lower ends of the steel girder, the plurality of through holes formed in the upper and lower portions of the steel girder perpendicular to the longitudinal direction of the steel girder A coupling bar is inserted and disposed in a direction so that the connecting bar is embedded in the upper and lower concrete panels; The web of the steel girder is composed of a corrugated steel sheet having a corrugated shape that is curved in the longitudinal direction to improve its buckling strength; The lower concrete panel is configured to introduce a prestressing force by placing tension members on both sides of the corrugated steel sheet and tensioning in a post tension manner; Synthetic i-beam consisting of the steel girder and the upper and lower concrete panels synthesized therewith is divided into a plurality of unit lengths for one span and manufactured in a precast manner, and then each segment of the synthetic i-beam is connected at a construction site. Adjacent corrugated steel sheets are assembled to each other at the portion to be assembled.
Preferably, the concrete can be cured by further pouring concrete to the connecting portion of the adjacent upper and lower concrete panels, and more preferably, the concrete poured to the connecting portion of the upper and lower concrete panels can be poured to cover the corrugated steel plate to be interconnected.

Hereinafter, specific embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view illustrating a concrete synthetic eye beam according to an embodiment of the present invention, and FIG. 2 is a schematic perspective view of a steel girder provided in the synthetic eye beam shown in FIG. 1.

As shown in Figures 1 and 2, the synthetic eye-beam 1 of the present invention is a steel girder 10, concrete panels 30, 40 are integrally coupled to the upper and lower portions of the steel girder 10 It consists of. According to the present invention, the steel girder 10 is made of a corrugated steel sheet 20 which is corrugated in a constant wave shape in the longitudinal direction (length direction) of the composite eye beam.

As shown in FIG. 2, in this embodiment, the corrugated steel sheet 20 is illustrated as having a trapezoidal shape having a predetermined angle, but the shape of the corrugated sheet formed on the corrugated steel sheet 20 is necessarily. It is not limited to a trapezoid, for example, may have a waveform shape consisting of a trigonometric curve such as a sine wave or cosine wave, and may have various waveform shapes.

The upper and lower concrete panels 30 and 40 are synthesized on the upper and lower portions of the corrugated steel sheet 20 in the steel girder 10.

For example, referring to FIG. 2, a plurality of through-holes 21 in the lengthwise direction are provided at portions close to the upper and lower portions of the steel girder 10, that is, the portions at which the upper and lower concrete panels 30 and 40 are synthesized. Is formed.

The through-holes 21 are disposed to penetrate the coupling reinforcing bars 22 having a predetermined length in the transverse direction of the steel girder 10.

As such, when the upper and lower portions of the steel girder 10 are embedded in the upper and lower concrete panels 30 and 40, respectively, since the reinforcing bars 22 are integrally embedded in the upper and lower concrete panels 30 and 40, respectively. The steel girders 10 and concrete panels 30 and 40 are firmly combined and synthesized.

The configuration in which the coupling reinforcing bar 22 is fitted to the through hole 21 is merely an example, and any structure may be embedded in the concrete panels 30 and 40 to improve the bonding force.

On the other hand, optionally, on the upper concrete panel 30, a shear connecting member 31 made of reinforcing bar or the like of a protruding shape for the future firm connection with the concrete slab is provided. Shear connector 31 is embedded in the concrete slab to achieve a solid shear connection between the synthetic eye-beam and the concrete slab through a mechanical action.

On the other hand, preferably, the lower concrete panel 40 is provided with a tension member separate from the reinforcing bar, thereby introducing the prestress to the synthetic eye-beam. Specifically, after embedding the sheath tube 41 in the lower concrete panel 40, the tension member 42 is disposed therein, the unit length of the steel girders 10 connected to the segment and integrally installed, then the tension member By tensioning and fixing the 42, a tension force is applied to the lower concrete panel 40 to further strengthen the connection of the synthetic eye beams of each unit length, and at the same time, to introduce a prestress force to the entire synthetic eye beam in the connected state. It further increases the strength of the synthetic eye beam. In other words, the connection of the synthetic eye beam according to the present invention is primarily assembled after connecting the corrugated steel sheets 20 adjacent to each other at the portion where the respective segments of the synthetic eye beam is connected, and secondly the lower concrete of each segment The tension member 42 disposed on the panel 40 is tension-fixed in a post-tension manner to complete the connection of the synthetic eye-beam segment by further increasing the connection coupling force of each segment.

The upper and lower concrete panels 30 and 40 of the present invention are manufactured in a precast manner to be synthesized with the steel girders 10 of unit length in advance in a factory, and transported to a site to be integrated by connecting a desired number of steel girders. have.

As described above, in the present invention, the web of the steel girder 10 synthesized with the upper and lower concrete panels 30 and 40 is manufactured as a curved corrugated steel sheet 20. Since the steel girder 10 made of the corrugated steel sheet 20 has a large cross-sectional coefficient according to the cross-sectional shape of the corrugated steel sheet 20, the steel girder 10 has a high buckling strength in the vertical direction, that is, in the mold height direction. Have.

When the steel girder 10 is configured to have a web made of a simple flat plate as in the prior art, the web of the steel girder 10 acts as a pillar. Therefore, when a vertical load of a predetermined degree or more is applied, buckling occurs in the web itself, which causes a large deformation in the steel girder 10.

However, in the present invention, since the web of the steel girder 10 is made of the corrugated steel sheet 20 to improve its cross-sectional rigidity, the web of the steel girder 10 has a strong buckling strength even if the web behaves like a columnar structure. Therefore, in the present invention, even if the mold height is high, it is possible to prevent the buckling from occurring in the web.

In particular, since the web of the steel girder 10 is not embedded in a separate concrete in the present invention, its own weight can be reduced as compared with a general concrete girder (prestressed concrete I beam), and thus it is very advantageous for the extension of the bridge. .

In addition, since the tension member 42 may be disposed on the lower concrete panel 40, the tension force may be introduced, thereby further increasing the strength of the synthetic eye beam.

3A and 3B are schematic side views showing an integrated shape by connecting a synthetic eye beam according to the present invention divided into a plurality.

For example, it is practically impossible to manufacture a synthetic eye-beam having a long section of about 50m in one piece and transport it to the field. However, in the present invention, one beam is divided into segments of several unit lengths, each manufactured at a factory, and then easily transported to the site to be easily connected to construct one synthetic eye beam having a long span. You can do it.

3A and 3B show an example in which one synthetic i-beam is manufactured by combining three unit length segments, and FIGS. 4A to 4B are schematic views cut along AA and BB in FIG. 3B, respectively. A cross section is shown.

As shown in the figure, first, one synthetic eye-beam is divided into segments of several unit lengths and manufactured at the factory as concrete synthetic eye-beams having corrugated steel webs.

After transporting the concrete synthetic eye beam segment of each unit length thus manufactured to the site, the webs of the adjacent steel girders 10 are connected by a method such as bolts and welding to form one synthetic eye beam, Preferably, the upper and lower concrete panel connections of adjacent steel girders 10 pour concrete to produce a complete composite eye-beam.

At this time, preferably, the concrete that is poured into the connecting portion of the upper and lower concrete panels may be poured to cover the corrugated steel sheet to be interconnected.

More preferably, the side end portion of the corrugated steel sheet 20 of the steel girder 10 constitutes the protrusion 20a so as to protrude more than the upper and lower concrete panels 30 and 40 between the adjacent corrugated steel sheets 20. The coupling can be facilitated. For example, as illustrated in FIG. 3A, a bolt hole is drilled in the protruding portion 20a of the adjacent corrugated steel sheet 20, and the connection steel sheet 70 is padded to connect.

However, even if the protrusion 20a is not formed, the corrugated steel sheets 20 may be coupled to each other by a method of bolting or welding by applying a reinforcing plate or the like.

In addition, a separate connecting sheath tube 43 is installed at the connection between the lower concrete panels 40 of the adjacent steel girder 10 so that the sheath tube is completely communicated over the entire span of the synthetic eye beam, and penetrates through the entire span. A tension member is placed in the connected sheath pipe, and the concrete is poured into the connecting portion, and then the tension material is tensioned and settled so that prestress is introduced into the lower concrete panel over the entire section of the synthetic eye beam. In FIG. 3A, the portion where the tension member 41 is fixed at the synthetic eye-beam ends on both sides is illustrated in a simplified manner by arrows.

Thus, each steel girder is connected to the ground, the concrete composite i-beam made integrally on the alternating or pier, and then cast the upper slab concrete curing to complete the bridge according to the present invention.

Although the above has been described with reference to preferred embodiments of the present invention, various changes and modifications can be made at the level of those skilled in the art, and such changes and modifications will fall within the scope of the present invention without departing from the spirit of the present invention.

As described above, according to the present invention, after the synthetic eye-beams are divided into unit length segments and manufactured according to a consistent process in a precast method at the factory, the synthetic eye-beams of each unit length in the field are corrugated steel sheet and upper portion. And by using the lower concrete panels, it is possible to shorten the process, to facilitate quality control and to produce even more economical synthetic eye beams.

In addition, since the web of the steel girder is made of a corrugated steel sheet to improve its cross-sectional rigidity, it has a strong buckling strength, and accordingly has the advantage that the mold height of the synthetic eye beam can be significantly increased compared to the conventional.

In addition, it is structurally distinguished from corrugated steel for box-type bridges in which a large slab of lower slab is to be poured and bracing is installed, and construction cost can be further improved to reduce construction costs.

In addition, in the present invention, since it is not necessary to cast concrete on the web abdomen, the weight reduction effect is exerted, and thus, it is very advantageous for the extension of the bridge.

In particular, in the present invention, since the tension material is disposed on the lower concrete panel, the prestressing force is introduced into the synthetic eye beam, thereby increasing the strength of the synthetic eye beam.

Claims (6)

It consists of a steel girder and upper and lower concrete panels are synthesized on the top and bottom of the steel girder, a plurality of through-holes formed in the upper and lower portions of the steel girder, the coupling reinforcement is inserted in a direction perpendicular to the longitudinal direction of the steel girder Disposed so that the reinforcing bars are embedded in the upper and lower concrete panels; The web of the steel girder is composed of a corrugated steel sheet having a corrugated shape that is curved in the longitudinal direction to improve its buckling strength; The lower concrete panel is configured to introduce a prestressing force by placing tension members on both sides of the corrugated steel sheet and tensioning in a post tension manner; Synthetic i-beam consisting of the steel girder and the upper and lower concrete panels synthesized therewith is divided into a plurality of unit lengths for one span and manufactured in a precast manner, and then each segment of the synthetic i-beam is connected at a construction site. Precast concrete composite eye beam having a corrugated steel web, characterized in that the adjacent corrugated steel sheet is assembled and connected at the portion. delete delete The precast concrete composite eye-beam having a corrugated steel web according to claim 1, wherein the concrete is further casted to cure the connection portions of the adjacent upper and lower concrete panels. The precast concrete composite i-beam with corrugated steel web according to claim 4, wherein the concrete cast on the connecting portion of the upper and lower concrete panels is cast so as to cover the interconnected corrugated steel sheet portions. delete

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