KR101310009B1 - Integral girder including combination unit - Google Patents

Abstract

The present invention forms a girder body, a top plate, a cross beam and a coupling member integrally on a girder mounted on a pier on a ground or in a nearby factory, and is easily and quickly coupled to a pair of adjacent girders positioned to face each other. It relates to a girder body, the upper plate, the cross beam and the coupling member is formed integrally.
The integrated girder including the coupling member of the present invention has a girder body formed to extend in one direction, an upper plate formed on an upper portion of the girder body, and a cross beam protruding from both side portions of the girder body and contacting the bottom surface of the upper plate. In the girder,
One end is embedded in the cross beam, the other end is formed with a coupling member exposed to the end of the cross beam, the coupling member is a plate-shaped coupling plate, the other side of the coupling plate to improve the embedding strength of the coupling plate A reinforcing plate formed at an end in a direction perpendicular to the coupling plate to be embedded in the cross beam, and forming a groove to expose the coupling plate in at least one of the front or rear side of the cross beam end, thereby including an integral coupling member. The coupling plates located on opposite sides of the girder are mutually coupled with each other by welding or fastening members, but an insertion protrusion is formed at one end of the upper plate to facilitate mutual coupling and release between integrally arranged integral girders. The other end of the upper plate is characterized in that the insertion groove is formed.

Description

Integrated girder including combination member {Integral girder including combination unit}

The present invention relates to a girder mounted on a pier, and more specifically, to a girder body, a top plate, a cross beam and a coupling member integrally formed so that a pair of adjacent girders and a welding or fastening member are positioned to face each other. It relates to an integrated girder including a coupling member to be coupled.

In general, when constructing a girder bridge, after mounting the girder on the pier, assembling the formwork on the top of the mounted girder to form concrete on the site to form a bridge deck.

However, the girder having the top plate formed thereon has a problem that the area of the top plate is wider than that of the girder, thereby increasing the risk of falling of the girder, and the deformation of the girder occurs due to the load transmitted from the top plate of the large area.

In order to solve this problem, a separate cross beam was formed on the side of the girder to be mutually coupled with the girders disposed adjacent to each other to divide the load transmitted from the upper plate formed on the girder to the girder and prevent the girder from falling.

However, the construction method of assembling the formwork on the upper part of the girder mounted on the pier and placing the concrete in the site takes a long time until the concrete placed in the formwork is cured, and there is a problem of delay in the construction period due to the weather and weather.

In addition, there is a problem of industrial accidents, such as a worker's fall accident because the worker has to work on the expensive structure for a long time.

In order to solve this problem, in recent years, the production of the bridge deck formed on the girder mounted on the pier and the cross beam formed on the side of the girder has been carried out by the prestressed concrete (PSC) method or reinforced concrete method in the ground or factory near the site, not on the pier. By manufacturing the girder, the top plate and the cross beams integrally and placing them on the pier, it was possible to shorten the construction period by omitting the formwork for manufacturing the top plate on the conventional girder and the curing time of the concrete poured in the field.

However, the conventional girder, the girder formed of the upper plate and the cross beams integrally formed to expose the loop reinforcing bars at the ends of the upper plate and the cross beams. The integral girder exposing the loop reinforcing bar at the end of the cross beam connects the upper plate of the integral girder disposed adjacent to the cross beam and the loop reinforcing bar exposed to the end of the cross beam, and then casts concrete or filler so that the loop reinforcing is embedded. To connect adjacently arranged integral girders. There is a problem that the construction period is delayed because the poured concrete or filler takes time to cure.

In addition, in the step of manufacturing the girder, the top plate and the cross beams integrally, the one-piece girder formed by embedding the steel sheath pipe in the transverse direction is mounted on the piers to be mutually coupled with the integral girder disposed adjacent to the steel wire inside the buried sheath pipe. The girder and the girder are combined to each other by inserting them.

However, in the method of mutually coupling with the integral girder arranged adjacently by inserting the steel wire into the integral girder forming the sheath pipe, a separate hauler for pulling the steel wire in the high air is required, and the integrated girder positioned on both sides joined to each other. There is a problem in that the construction is complicated, such as the need for a separate fixing means to fix the steel wire, the increase in the time and risk of the worker working on the expensive structure.

In addition, the girder coupled to each other by a steel wire inserted into the sheath tube formed in the integral girder has a difficult problem in maintenance after construction difficult to separate.

Therefore, an object of the present invention is to solve such a conventional problem, an integral girder in which the girder formed integrally with the upper plate, the girder main body and the cross beams which are manufactured on the ground and mounted on the pier to shorten the construction period is disposed adjacently. And to provide an integrated girder including an improved coupling member that can be easily and quickly interconnected with each other.

In addition, it is to provide an integrated girder including a coupling member that improves the safety of the operator by reducing the time for the worker to work on the high-cost structure by simplifying the work.

The present invention also provides an integrated girder including an improved coupling member capable of quick replacement and repair of a broken girder in the breakage and maintenance of the girder coupled to the girder mounted adjacent to the pier.

The object is, in accordance with the present invention, the girder body formed in one direction elongated, the upper plate formed on the upper portion of the girder body, the horizontal beam is in contact with the bottom portion of the upper plate is formed integrally with the cross beam protruding from both side portions of the girder body In the girder,

One end is embedded in the cross beam, the other end is formed with a coupling member exposed to the end of the cross beam, the coupling member is a plate-shaped coupling plate, the other side of the coupling plate to improve the embedding strength of the coupling plate A reinforcing plate formed at an end in a direction perpendicular to the coupling plate to be embedded in the cross beam, and forming a groove to expose the coupling plate in at least one of the front or rear side of the cross beam end, thereby including an integral coupling member. The coupling plates located on opposite sides of the girder are mutually coupled with each other by welding or fastening members, but an insertion protrusion is formed at one end of the upper plate to facilitate mutual coupling and release between integrally arranged integral girders. The other end of the upper plate is formed by an integrated girder including a coupling member, characterized in that an insertion groove is formed. It is achieved.

Here, at least one connection member for interconnecting the reinforcement plate formed to the left and right of the girder body is preferably further included.

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The apparatus may further include a reinforcing member covering the coupling plates on both sides coupled to the integrated girders including adjacent coupling members, and at least both sides of the reinforcing members may be welded to the coupling plate.

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In addition, the reinforcing member to cover the coupling plate of the two sides coupled to the integral girder including the adjacent coupling member; further comprising, the reinforcing member is preferably coupled to the coupling member penetrating through the coupling plate.

In addition, the end of the cross beam is formed on the inner side than the end of the upper plate, the coupling plate is formed extending outward than the end of the upper plate fastening member in the state in which the coupling plate located on the opposite sides of the adjacent girders cross-butted It is preferable to penetrate through.

In addition, the end of the cross beam is formed on the inner side than the end of the top plate, the coupling plate is formed to extend outward than the end of the top plate and the coupling plate located on the opposite sides of the integral girder including the adjacent coupling member is cross-facing It is preferable to join by welding in the extended state.

According to the present invention, in the fastening of the girder main body, the integral girder including the coupling member disposed adjacently including the coupling member on the girder formed integrally with the top plate and cross beams, the construction period is shortened by mutually fast coupling In providing an integrated girder including a coupling member.

In addition, according to the present invention, in the coupling with the integral girder including the coupling member disposed adjacent to provide an integrated girder including a coupling member for reducing the working time of the worker working on the expensive structure to increase the safety of the operator.

In addition, the present invention provides an integrated girder including a coupling member capable of quick replacement of a broken girder and a smooth maintenance after the coupling with an integrated girder including an adjacently disposed coupling member, and the broken girder.

1 is a perspective view of an integrated girder including a coupling member of the present invention;
2 is a front view of an integrated girder including a coupling member of the present invention;
Figure 3 is a cross-sectional view cut in the aa 'direction of the integral girder including the coupling member of the present invention,
4 is a front view of the integral girder including the coupling member of the present invention coupled to each other by welding integral girder including the coupling member disposed adjacent,
5 is a cross-sectional view of the main portion of the reinforcing member covering the fastening plate of FIG. 4 by welding;
6 is a cross-sectional view of a main part of the reinforcing member covering the fastening plate of FIG. 4 through the fastening member;
7 is a perspective view of a second embodiment of an integrated girder including a coupling member of the present invention;
8 is a cross-sectional view taken in the bb 'direction of the girder of the second embodiment of the integrated girder including the coupling member of the present invention;
8 is a front view of a second embodiment of an integrated girder including a coupling member of the present invention;
Figure 9 is a cross-sectional view cut in the bb 'direction of the integral girder including the coupling member of the present invention,
Figure 10 is a front view of the integral girder including the coupling member of the present invention mutually coupled to the integral girder and the fastening member including a coupling member disposed adjacent to each other.
11 is a front view of the girder of the present invention in which the girder is welded together with an integrated girder including a coupling member disposed adjacent to each other.

Prior to the description, in various embodiments, components having the same configuration will be representatively described in the first embodiment using the same reference numerals, and in other embodiments, different configurations from the first embodiment will be described. Shall be.

Hereinafter, the integrated girder 100 including the coupling member 40 according to the first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of an integrated girder 100 including the coupling member 40 of the present invention, and FIG. 2 is a front view of the integrated girder 100 including the coupling member 40 of the present invention. 3 is a cross-sectional view of the integrated girder 100 including the coupling member 40 of the present invention cut in the a-a 'direction.

As shown in the drawings, the integral girder 100 including the present invention coupling member 40 is to be mutually coupled with an integral girder including a coupling member disposed adjacent to and mounted on a pier in constructing a girder bridge. Body 10, top plate 20, cross beam 30 and the coupling member 40 is configured to include.

The girder body 10 is formed long in one direction by giving a compressive stress in advance in order to offset the tensile stress generated in the concrete by reinforced concrete or prestressed concrete (PSC) method in the ground near the plant or bridge construction site. The lower portion of the girder body 10 is made into a state of compressive stress of an appropriate size to distribute the load transmitted from the upper plate 20 to be described later in the piers.

The top plate 20 is formed on the girder body 10 to perform a bridge bottom plate function. An insertion groove 24 is formed at one end of the upper plate 20. The other end of the upper plate 20 is formed with an insertion protrusion 22 which can be inserted into the insertion groove 24 formed at one end of the upper plate 20 of the girder adjacent to the upper plate of the girder ( Level is the same as in 20).

The cross beam 30 is to prevent overturning due to the top plate 20 formed on the top of the girder body 10 and to distribute the load transmitted from the top plate 20 to the girder body 10, the top plate ( It is in contact with the bottom surface portion 20 of the girder body 10 is formed in the direction perpendicular to the longitudinal direction of the girder body 10. The cross beam 30 includes a coupling member 40, and the groove 32 is formed in at least one of the front and the rear of the end of the cross beam 30 so that the coupling member 40 is exposed.

The coupling member 40 includes a coupling plate 42, a reinforcement plate 44, and a connection member 46. As shown in FIG. 3, the coupling plate 42 is formed in a plate shape of a steel material, one end of which is embedded in the cross beam 30, and the other end of the coupling plate 42 is exposed to an end of the cross beam 30.

The reinforcing plate 44 is a plate of steel material, the coupling plate 42 embedded in the cross beam 30 is embedded in the direction parallel to the cross beam 30, the coupling plate for the cross beam 30 ( In order to increase the embedding strength of 42, one side end of the cross beam 30 is formed in a direction perpendicular to the coupling plate 42 is embedded in the cross beam (30).

The connecting member 46 is connected to the reinforcing plate 44 formed to the left and right of the girder body 10 by the steel wire of the steel material to the strength that the coupling member 40 receives from the outside, that is, the external force At least one is formed to increase.

Hereinafter, mutual coupling of the integrated girder 100 including the pair of coupling members 40 disposed adjacent to the integrated girder 100 including the coupling member 40 of the first embodiment will be described.

4 is a front view of the integral girder 100 including the coupling member 40 of the present invention and the integral girder 100 including the coupling member 40 adjacent to each other by welding (w). 4 is a cross-sectional view showing main parts welded (w) to the reinforcing member 50 covering the mutually coupled coupling plate 42 of FIG. 4, and FIG. 6 illustrates a fastening member 50 to cover the reinforcing member 50 of FIG. b) A cross section of the recessed part which is penetrated through b).

As shown in FIG. 4, an insertion groove formed at one end of the upper plate 20 of the integrated girder 100 including a coupling member 40 disposed adjacent to the insertion protrusion 22 formed at the other end of the upper plate 20. The upper plate 20 and the upper plate 20 are horizontally inserted into the upper portion 24.

At this time, one side end is embedded in the cross beam 30, the other end is formed to be exposed to the end of the cross beam 30, the coupling plate 42 is a cross beam of the integrated girder 100 including the adjacent coupling member 40. The coupling plate 42 formed in the 30 is located on the surface facing each other.

Here, the pair of coupling plates 42 abutting against each other by the grooves 32 formed at the front or rear of the cross beam 30 end is exposed to the outside, a pair of the coupling plates abutting against each other ( 42 is coupled to each other by welding (w).

In addition, as shown in FIG. 5, the integral girder 100 including the coupling member 40 of the present invention is mutually coupled by the integral girder 100 and the welding w including the coupling member 40 disposed adjacent thereto. The coupling plate 42 of the integrated girder 100 including the pair of coupling members 40 is covered with a reinforcing member 50, and at least both sides of the reinforcing member 50 are welded to the coupling plate 42 ( w) is coupled to increase the mutual coupling force for the structure of the integral girder 100 including a pair of coupling members 40.

In addition, as shown in FIG. 6, the integral girder 100 including the coupling member 40 of the present invention is mutually coupled by the integral girder 100 and the welding w including the coupling member 40 disposed adjacent thereto. The coupling plate 42 of the pair of girders covered with a reinforcing member 50, the reinforcing member 50 is coupled by a fastening member (b) passing through the coupling plate 42 is a pair of coupling members ( To increase the mutual coupling force to the structure of the integral girder 100, including 40).

Next, the integrated girder 100 'including the coupling member 40 according to the second embodiment of the present invention will be described.

7 is a perspective view of a second embodiment of the integrated girder 100 'including the coupling member 40' of the present invention, and FIG. 8 is a second of the integrated girder 100 'including the coupling member 40'. A front view of an embodiment, the attached figure 9 is a sectional view bb 'of the second embodiment of the integrated girder 100' including a coupling member 40 '.

As shown in FIG. 8, the second embodiment of the integrated girder 100 ′ including the coupling member 40 ′ according to the present invention has an upper plate formed on an upper portion of the girder body 10, as shown in FIG. 8. 20) the girder in contact with the bottom surface of the top plate 20 and to distribute the load transmitted to the girder body 10 of the top plate 20 due to the overturning due to the girder A cross beam 30 'is formed inwardly from an end portion of the upper plate 20 in a direction perpendicular to the longitudinal direction of the main body 10, and includes a coupling member 40'.

The coupling member 40 'is composed of a coupling plate 42', a reinforcement plate 44 and a connection member 46.

The coupling plate 42 'is a plate of steel material, one side of which is embedded in the cross beam 30', and the other side of the coupling plate 42 'is exposed to an end of the cross beam 30'. The coupling plate 42 ′ is formed to extend outward from an end of the upper plate 20. The coupling plate 42 ′ is opposed to the one-piece girder 100 ′ including the coupling member 40 ′ disposed adjacent to and face each other.

Here, since the reinforcing plate 44 and the connecting member 46 is the same as the configuration listed in the first embodiment and repeated, the description thereof is omitted.

As shown in FIG. 10, the integrated girder 100 ′ including a pair of adjacent coupling members 40 ′ fastens the coupling member 42 ′ having the opposite surfaces abutting against each other. ) Are penetrated and joined together.

In addition, as shown in FIG. 11, the integrated girder 100 ′ including a pair of adjacent coupling members 40 ′ welds a coupling plate 42 ′ having cross-butted surfaces facing each other. by w).

The scope of the present invention is not limited to the above-described embodiments but may be implemented in various forms of embodiments within the scope of the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described in the present invention to various extents which can be modified.

100, 100 ': girder 10: girder body
20: top plate 22: insertion protrusion
24: insertion groove 30, 30 ': cross beam
32: groove 40,40 ': coupling member
42,42 ': Bonding plate 44: Reinforcing plate
46: connecting member 50: reinforcing member

Claims (9)

In the girder body is formed in one direction, the upper plate formed on the upper portion of the girder body, the girder is in contact with the bottom surface of the upper plate and integrally formed cross beams protruding from both side portions of the girder body,
One end is embedded in the cross beam, the other end is formed with a coupling member exposed to the end of the cross beam, the coupling member is a plate-shaped coupling plate, the other side of the coupling plate to improve the embedding strength of the coupling plate A reinforcing plate formed at an end in a direction perpendicular to the coupling plate to be embedded in the cross beam, and forming a groove to expose the coupling plate in at least one of the front or rear side of the cross beam end, thereby including an integral coupling member. The coupling plates located on opposite sides of the girder are mutually coupled with each other by welding or fastening members, but an insertion protrusion is formed at one end of the upper plate to facilitate mutual coupling and release between integrally arranged integral girders. The other side end of the upper plate integral girder including a coupling member characterized in that the insertion groove is formed.
delete The method of claim 1,
At least one connecting member for interconnecting the reinforcing plate formed to the left and right of the girder body; integral girder comprising a coupling member further comprising.
delete delete The method according to claim 1 or 3,
And a reinforcing member covering the coupling plates on both sides coupled to the integral girders including adjacent coupling members, wherein at least both sides of the reinforcing members are welded to the coupling plate.
The method according to claim 1 or 3,
And a reinforcing member covering the coupling plate on both sides coupled to the adjacent girder, wherein the reinforcing member is coupled to the coupling member through the coupling plate.
The method according to claim 1 or 3,
Ends of the cross beams are formed on the inner side than the end of the upper plate, the coupling plate is formed to extend outward than the end of the upper plate and the coupling plates located on opposite sides of the integral girder including adjacent coupling members are cross-butted Integral girder including a coupling member characterized in that the fastening member is coupled through.
The method according to claim 1 or 3,
Ends of the cross beams are formed on the inner side than the end of the upper plate, the coupling plate is formed to extend outward than the end of the upper plate and the coupling plates located on opposite sides of the integral girder including adjacent coupling members are cross-butted Integral girder including a coupling member, characterized in that coupled by welding.

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