KR100622452B1 - Multi-H section steel girder compounded part - Google Patents

Abstract

The present invention relates to a partially synthesized multi-H-beam girder to increase the workability and reduce the number of supports, in the plurality of H-beam girders disposed in parallel between the piers or between the piers and the alternator, the plurality of H The section girders are grouped into a predetermined number of units, and in each of the group units, both longitudinal ends of the H-beam girders of the pairs are embedded in a composite body portion of a predetermined shape, and the composite body portion is formed between the composite body portions adjacent to the outer surface. The coupling portion is formed to couple to each other.

H-beam girder, partial composite, bridge, workability, composite body, precast, concrete

Description

Multi-H section steel girder compounded part

1 is a view showing the configuration of a partially synthesized multi H-beam girder according to an embodiment of the present invention,

2 is a sectional view of the main part of FIG. 1;

3 is a view illustrating a state in which the configuration of FIG. 1 is installed in a bridge;

4 is a modification of FIG. 2.

* Explanation of symbols for main parts of the drawings

10: H-beam girder 12, 40: synthetic body

14: coupling portion 16: steel wire through hole

18: steel wire 20: bearing

22: upper reinforcement plate 24: lower reinforcement plate

30: piers

The present invention relates to a partially synthesized multi H-beam girder, and more particularly, to a structure in which a plurality of H-beam girders installed on a pier are partially synthesized.

The steel sheet was first used in some limited high-rise structures, long span roofs, factories and plants, and gradually increased the industrial facilities and the introduction of steel frames into high-rise structures.

At present, steel structures are spreading to residential and mid-rise buildings. In the civil engineering field, due to its excellent structural performance, low price, and reusability, it is mainly applied to temporary construction including subway construction, temporary bridges for disaster recovery, and bridge construction for main construction. The development and dissemination of prototypes and composite structures that maximize the advantages of steel are being actively carried out.

Types of section steel include H-beam, a-beam, c-beam, I-beam, and T-beam, and mainly H-beam is widely used as girders in bridges. H-beam bridges have excellent saving effect and have high rigidity and are widely applied in 20-25m section.

However, when dealing with problems such as socializing and increasing part of the bridge depending on the site conditions, there is a problem that the number of supports increases and the construction is difficult as the number of H-beam girders increases.

The present invention has been proposed to solve the above-mentioned conventional problems, and an object thereof is to provide a partially synthesized multi H-beam girder capable of increasing workability and reducing the number of bearings.

Partially synthesized multi H-beam girders according to a preferred embodiment of the present invention, in order to achieve the above object, in a plurality of H-beam girders disposed in parallel between the bridge or between the bridge and the alternating,

The plurality of H-girder girders are formed in a predetermined number of units, the lengthwise ends of the H-shaped steel girders of the corresponding pair in each of the pairs are embedded in the composite body of a predetermined shape and synthesized, the composite body portion is adjacent to the outer surface Characterized in that the coupling portion is formed to couple between the composite body portion.

Preferably, a steel wire through hole is formed at both ends of the H-shaped steel girders of the predetermined number unit for each group embedded in the synthetic body part and the synthetic body part, and the steel wire is a predetermined number unit for each group through the steel wire through hole. It is installed orthogonal to the H-beam girder of each group to connect the composite body parts.

The predetermined number is two or three.

On the other hand, the coupling portion is formed on both outer surfaces of the composite body portion, the coupling portion formed on one side of the composite body portion is configured in a yaw shape, the coupling portion formed on the other side of the composite body portion is iron (凸) shape The composite body portion is composed of concrete or FRP.

The upper flanges formed at both ends of the longitudinal H-girder girders embedded in the composite body portion are coupled to each other by an upper reinforcement plate, and the longitudinal direction of the respective H-girder girders embedded in the composite body portion. Lower flanges formed at both ends are mutually joined by lower reinforcement plates.

Hereinafter, with reference to the accompanying drawings, a partially synthesized multi-H-beam girders according to an embodiment of the present invention will be described.

1 is a view showing the configuration of a partially synthesized multi-H-beam girder according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the main portion of Figure 1, Figure 3 is a view showing a state in which the configuration of Figure 1 is installed on the bridge .

Partially synthesized multi H-beam girder according to an embodiment of the present invention, a plurality of H-beam girders 10 arranged in parallel between the bridge 30 or between the bridge 30 and the alternating (for example, two Or 3) unit and partially synthesized.

That is, both ends of the longitudinal direction of the H-shaped steel girders 10 of the corresponding pairs in each of the pairs are embedded in the composite body portion 12 of the concrete or FRP material of a predetermined shape (for example, a cube or a cube) and synthesized. The engaging portion 14 is formed in the portion 12. The coupling portion 14 is to mutually join the adjacent composite body portion 12.

The length of the composite body portion 12 is relatively shorter than the length of the H-shaped steel girder 10, the length of the composite body portion 12 is embedded in each of the longitudinal both ends of the set of H-shaped steel girders 10 The overall length is also shorter than the length of the H-beam girder 10.

Here, the steel wire passage hole 16 is formed at both ends in the longitudinal direction of the H-shaped steel girders 10 of the predetermined number unit for each group embedded in the composite body portion 12 and the composite body portion 12, the steel wire The steel wire 18 is installed orthogonally to the H-shaped steel girders 10 of the predetermined number unit of each group through the through-hole 16 to firmly connect the composite body portion 12 of each group.

And, the coupling portion 14 is formed on both outer surfaces of the composite body portion 12, the coupling portion formed on one side of the composite body portion 12 in a yaw shape in a longitudinal direction to the corresponding one side It is configured, the coupling portion formed on the other side of the composite body portion 12 is formed in the longitudinal direction on the other side in the shape of iron (凸).

In FIG. 3, each grouping composite body part 12 is illustrated as being installed at one side of each group H-beam girder 10, but is substantially provided at the other side of each group-shaped H-beam girder 10. Of course.

4 is a modification of FIG. 2, which is a structure for further strengthening the binding of the H-beam girder 10 embedded in the composite body portion 40.

That is, upper flanges formed at both ends in the longitudinal direction of each group H-shaped steel girder 10 embedded in the composite body portion 40 are mutually coupled by an upper reinforcing plate 22, and the composite body portion 40 is formed. Lower flanges formed at both longitudinal ends of the respective group H-girder girders 10 embedded in the lower reinforcing plates 24 are coupled to each other. In FIG. 4, the upper reinforcing plate 22 and the lower reinforcing plate 24 are joined to the upper and lower flanges in contact with the upper reinforcing plate 22 and the lower reinforcing plate 24 by welding.

1 to 3 described above, the number of H-shaped steel girders 10 embedded in the composite body parts 12 and 40 is three, but the number may be added or subtracted as necessary.

In the partially synthesized multi H-beam girder according to the embodiment of the present invention configured as described above, since two or three H-beam girders are synthesized by the composite body portion 12, one composite body portion as shown in FIG. One support 20 (stool device) is required for (12). That is, in the prior art, one support (stool device) had to be provided at the lower sides of both H-beam girders in the longitudinal direction. Only 20 may be present.

In addition, when the partially synthesized multi-H-beam girders according to the above-described embodiments of the present invention are installed in the bridge as shown in FIG. Therefore, in order to reinforce the part, angled angles (not shown) may be provided in the composite body portions 12 at both ends in a transverse shape.
A plurality of composite body parts coupled to each other by the coupling part are each provided with angled angles in a transverse shape at the corners of both sides of the outer surface.
That is, angled angles (not shown) are provided at the corners of the upper left portion of the composite body portion 12 at the left end and at the corners of the upper right portion of the composite body portion 12 at the right end. Then, the shear connector is provided on the inner surface of the angled angle to strengthen the binding with the composite body portion 12 coupled to the angle.

The partially synthesized multi H-beam girder of the present invention described above may be manufactured in advance in a factory, or may be manufactured in the field.

That is, in the case of manufacturing in advance in the factory, after placing two or three or more H-beam girders 10 in parallel, both sides of the two or three or more H-beam girders 10 arranged in parallel are concreted. Precast synthesis. The precast concreted portion forms the composite body portions 12, 40. Then, the steel wire passing hole 16 is formed in advance on both sides of the two or three or more H-shaped steel girders 10 before the synthesis. In addition, the steel wire passing holes 16 are also formed in the composite body parts 12 and 40.

And, in the case of manufacturing in the field, after the pre-fabrication of the composite body portion 12, 40 in the pre-cast frame, the composite body portion 12 or 40 on both sides of the H-beam girder 10 in the field, respectively Insert to fill. When the composite body parts 12 and 40 are prefabricated with a protruding precast mold, the composite body parts 12 and 40 may have a predetermined shape in which two or three sides of the H-beam girder 10 may be inserted. Inserts should be formed. The production of the protruding precast mold may be made of concrete or FRP plate with a combination of thin plates, and the joints may also be reinforced.

In addition, the upper bottom plate of the multi H-beam girder 10 can use a precast panel, and can also be constructed using a deck between girders.

As a method of constructing an H-beam steel bridge using the partially synthesized multi-H-beam girder according to the embodiment of the present invention described above, first, two or three or more H-beam girder 10 as a pair of H-shaped steel for each group Both sides of the girder 10 are precast concrete. The precast concrete treated portion forms the composite body portion 12. Steel wire passage holes 16 are formed at both sides of the composite body portion 12 and each group of H-shaped steel girders 10, and coupling portions 14 are formed at both outer surfaces of the composite body portion 12. have. Here, not two or three or more H-beam girders 10 are precast concrete as a whole, but only precast concrete is processed on both sides, thereby saving concrete.

Thereafter, the pre-fabricated partially synthesized multi-H-beam girders are transported to the construction site and mounted between the bridge piers 30 or between the bridge piers 30 and the alternators by the crane or the like. Combine them together. After that, the composite body portions 12 are strongly bound to each other using the steel wire 18.

As described in detail above, according to the present invention, it is possible to easily apply a girder having an increased cross-sectional secondary moment.

In addition, the construction of the sidewalk bridge as well as the road bridge can be mounted as a crane as it is.

In addition, the fall prevention and construction of the beam is increased, the workability is excellent by manufacturing the factory, there is an effect that can reduce the number of supports supporting the H-beam girder.

In addition, the haunch construction is prefabricated, and no deformation of the beam is required for the slab end reinforcement.

On the other hand, the present invention is not limited only to the above-described embodiment, but can be modified and modified within the scope not departing from the gist of the present invention, the technical idea to which such modifications and variations are also applied to the claims Must see

Claims (8)

For many H-beam girders arranged in parallel between piers or between piers and alternators, The plurality of H-girder girders are formed in a predetermined number of units, the lengthwise ends of the H-shaped steel girders of the corresponding pair in each of the pairs are embedded in the composite body of a predetermined shape and synthesized, the composite body portion is adjacent to the outer surface Partially synthesized multi H-beam girder, characterized in that the coupling portion is formed to mutually bond between the composite body portion. The method of claim 1, Steel wire passing holes are formed at both ends of the H-shaped steel girders of the predetermined number unit for each group embedded in the synthetic body part and the synthetic body part, and the steel wire is H-shaped steel of the predetermined number unit for each group through the steel wire passing holes. Partially synthesized multi-H-beam girder, characterized in that orthogonal to the girder and connected to each of the groups of the composite body. The method according to claim 1 or 2, And wherein said predetermined number is two or three. The method according to claim 1 or 2, The coupling portion is formed on both outer surfaces of the composite body portion, the coupling portion formed on one side of the composite body portion is formed in a yaw shape, the coupling portion formed on the other side of the composite body portion is formed of an iron shape Partially synthesized multi H-beam girder. The method according to claim 1 or 2, Partially synthesized multi H-beam girder, characterized in that the composite body portion is composed of concrete or FRP. The method according to claim 1 or 2, Upper flanges formed at both longitudinal ends of the respective group H-beam girders embedded in the composite body portion are mutually coupled by an upper reinforcing plate, and both longitudinal ends of the respective group-shaped H-beam girders embedded in the composite body portion. The lower flange formed on the partially synthesized multi H-beam girder, characterized in that the mutually coupled by the lower reinforcement plate. The method according to claim 1 or 2, Partially synthesized multi H-beam girder, characterized in that each of the plurality of composite body portion coupled to the coupling portion is installed in the corner portion of both sides of the outer angle in the shape of a translator. A bridge comprising the partially synthesized multi H-beam girder according to claim 1 or 2.

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