KR101883173B1 - Structure of Slab for Bridge - Google Patents

Abstract

The present invention relates to a deck structure of a bridge comprising an inner deck part and a cantilever deck part. The inner deck part is mounted in such a way that four sides of a deck plate are supported, and the cantilever deck part has a cantilever supporter for supporting the deck plate, wherein the cantilever supporter is located in the same line as an upper surface of a girder and is integrated with the cantilever deck plate, thereby enhancing structural stability. The deck structure of a bridge includes an inner deck part formed on an inner span between neighboring girders, a cantilever deck part protruding outwardly from the outermost girder, and slab concrete deposited on an upper portion of the deck parts. The cantilever deck part includes: a plurality of cantilever supporters, which are spaced apart from each other in a longitudinal direction of the girder, and each of which has a first flange put on an upper surface of the outermost girder, a second flange located to be opposite to the first flange and being narrower than the first flange, and a web for connecting the first flange and the second flange with each other, wherein one end is put on an upper surface of the girder to be fixed by a fixing part and the other end protrudes outwardly from the girder; and a cantilever deck plate of which both ends are put on upper portions of the first flanges of the neighboring cantilever supporters so that slab concrete is poured.

Description

{Structure of Slab for Bridge}

The present invention relates to a bottom structure of a bridge, which is configured to include an inner bottom portion and a cantilever bottom portion, wherein the inner bottom portion is provided so that the bottom plate is supported on four sides, and the cantilever bottom portion includes a cantilever pedestal supporting the bottom plate, The floor structure of a bridge which is located on the same line and integrated with the bottom plate when slab concrete is poured, thereby improving the structural stability.

Generally, bridge construction is accomplished by first completing a bridge substructure such as an alternating or pier, establishing a girder in the longitudinal direction (longitudinal direction) above the alternating and / or pierched bridges, After installation, a bridge slab form is installed on the installed bridge.

Next, the final slab of the bridge slab is completed by placing the reinforcing bars in the longitudinal and transverse directions inside the bridge slab formwork and casting the bridge slab concrete. The work for the bridge slabs and the bridge slab formwork, Of the bridge slabs and bridge slabs for the bridge slabs are required to pay attention to the safety management because they are accompanied by the complaints. It is inevitable that the construction of the bridge slab is deteriorated and the air (construction period) is delayed because of its very low cost.

In order to solve the problem of the above-mentioned on-site concrete, a precast deck is installed on the upper part of the girder, and the slab is installed by laying on the site.

Such a slab can be divided into an inner bottom portion formed between the inner side between the girder and the girder, and a cantilever bottom portion formed outwardly protruding from the outermost girder.

The inner bottom is installed in such a manner that both ends of the precast deck are supported by neighboring girders. In this way, the precast deck is supported at both ends so that the precast deck easily cracks and durability is lowered.

On the other hand, the bottom of the cantilever is constituted by connecting a precast permanent support to a side surface of a girder and installing a precast bottom plate to be supported by the precast permanent support, as disclosed in Japanese Patent No. 10-1101209.

However, when the precast permanent support is coupled to the side surface of the girder as described above, when the concrete is laid on the precast bottom plate, the concrete pushed and the permanent casting pedestal are not integrated, It is separated from the bridge due to the vibration generated in the bridge, resulting in a risk of safety accidents.

Registered Patent No. 10-1699888 Patent No. 10-1101209

According to an aspect of the present invention, there is provided a cantilever comprising: an inner bottom and a bottom of the cantilever; the bottom of the cantilever includes a bottom plate supported on four sides, And a bottom structure of the bridge which is located on the same line as the upper surface and is integrated with the cantilever bottom plate when the slab concrete is poured, thereby improving the structural stability.

According to an aspect of the present invention, there is provided a cantilever comprising: an inner bottom portion formed between an inner portion between adjacent girders; and a cantilever bottom portion protruding outward from the outermost girder, And a slab concrete laid on an upper portion of the floor portions, wherein the cantilever bottom portion includes a first flange that is mounted on an upper surface of the outermost girder, and a second flange that is positioned to face the first flange, A second flange formed to have a width narrower than a width of the flange and a web connecting the first flange and the second flange, wherein one end is placed on the upper surface of the girder and fixed through the fixing portion, A cantilever pedestal protruding outside the girder and having a plurality of spaced apart cantilevers along the longitudinal direction of the girder; And a cantilever bottom plate installed at both ends of the first flange of the neighboring cantilever pedestal so that the slab concrete can be laid.

The bottom of the cantilever may be longer than the cantilever pedestal so that a portion of the bottom of the cantilever is projected to the outside of the cantilever pedestal. At both ends of the cantilever, a wing is formed to be in close contact with the neighboring cantilever bottom.

In addition, when the girder is a steel box type girder, a lug is provided on the upper part of the steel box girder, and the lug and the cantilever pedestal are welded through the fixing piece to fix the cantilever pedestal.

The inner bottom portion includes an inner pedestal body that is respectively mounted on a girder adjacent to the left and right sides, and a bottom plate support portion that protrudes from the front and rear sides of the inner pedestal body to allow the bottom plate to be mounted. A plurality of inner casings being spaced from each other along the longitudinal direction of the inner casings; And an inner bottom plate installed on the girder so that the left and right sides thereof are respectively mounted, and the front and back sides thereof are mounted on the bottom plate receiving portion and supported on four sides.

And a plurality of connecting stiffeners protruding from the front and rear side surfaces of the inner bottom plate to allow the inner bottom plate to be continuous.

In the method for constructing a bottom structure of a bridge formed on a bridge girder, there is provided a method of constructing a bottom structure of a bridge, comprising the steps of: mounting an inner pedestal on an inner ground between a girder and a girder; An inner bottom plate for mounting the inner bottom plate so that the front and rear sides are mounted on the bottom plate receiving portions formed on the front and rear sides of the inner pedestal so that the left and right sides are mounted on the girder, step; A second flange positioned to face the first flange and formed to have a width narrower than the width of the first flange and a second flange disposed opposite to the first flange so as to face the first flange, A plurality of cantilever pedestals installed on the girder so as to be spaced apart from each other along a longitudinal direction of the girders; A cantilever bottom plate mounting step for mounting both ends of the cantilever bottom plate to the first flanges of the neighboring cantilever mount; And a slab concrete casting step of placing reinforcing bars on the inner bottom plate and the upper part of the cantilever bottom plate and casting the slab concrete.

As described above, according to the present invention, when the slab concrete is installed by placing the cantilever pedestal on the same line as the upper surface of the girder, the cantilever bottom plate and the cantilever pedestal are integrally combined to prevent the cantilever pedestal from falling off There is an effect that stability is structurally improved.

In addition, since the inner bottom plate is supported so as to be supported by four inner bottom plates, the load applied to the inner bottom plate can be easily dispersed, thereby preventing the inner bottom plate from cracking.

In addition, when the cantilever pedestal is installed, if the girder is a steel box type girder, the cantilever pedestal and the steel box type girder are not directly welded, which is a very useful invention for preventing the steel box type girder from being damaged or damaged.

1 is an exploded perspective view showing a bridge floor structure according to the present invention,
FIG. 2 is a perspective view showing a bridge floor structure according to the present invention,
3 is an exemplary view showing an installation state of the inner pedestal according to the present invention,
FIG. 4 is a cross-sectional view showing a state in which an inner pedestal is installed in an inner bottom portion according to the present invention,
5 is a cross-sectional view showing a state in which an inner bottom portion according to the present invention is installed in a longitudinal direction of a bridge,
FIG. 6 is a cross-sectional view showing a bottom structure according to the present invention in a widthwise direction of a bridge,
FIG. 7 is an exemplary view showing an installation state when the floor structure is installed on the upper part of the steel box type girder according to the present invention;
8 is a perspective view showing a state in which a connecting stiffener is further formed on the inner bottom plate of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is an exploded perspective view of a bridge floor structure according to the present invention, FIG. 2 is an assembled perspective view of a bridge floor structure according to the present invention, FIG. 3 is an exemplary view showing an installed state of an inner bridge according to the present invention, FIG. 5 is a sectional view showing a state in which the inner bottom portion according to the present invention is installed in the longitudinal direction of the bridge, FIG. 6 is a sectional view of the inner bottom portion in the longitudinal direction of the bridge, Is a cross-sectional view of the bottom structure according to the present invention taken along the width direction of the bridge,

As shown in the figure, the bottom structure of a bridge of the present invention is formed by projecting in the width direction of a bridge at an inner bottom portion 100 and an outermost girder 10 formed between the inner side between the girder 10 and the girder 10 And a slab concrete 300 installed on the inner bottom 100 and the upper portion of the cantilever floor 200. The cantilever 200 includes a cantilever 200,

The cantilever bottom part 200 includes a cantilever pedestal 220 having one end fixed to the outermost girder 10 and a plurality of spaced apart from each other along the longitudinal direction of the girder 10, And a cantilever bottom plate 210 installed at both ends thereof.

The cantilever pedestal 220 is fixed to the upper surface of the girder 10 and includes a first flange 221 on which the cantilever bottom plate 210 is mounted and a second flange 221 spaced apart from the first flange 221, And a web 223 connecting the first flange 222 and the second flange 221. The second flange 222 is configured to have a width smaller than the width of the first flange 221 and the second flange 222. [

The width of the second flange 222 is narrower than the width of the first flange 221 so that the second flange 222 is inserted into the first flange 221 of the cantilever base plate 210, The first flange 221 can be easily mounted on the first flange 221 without being interfered by the first flange 222, thereby improving the workability of mounting the bottom plate while maintaining the structural rigidity of the cantilever support 220.

The upper portion of the second flange 222 may further include a shear connection member 224 so as to improve the efficiency with which the slab concrete 300 is combined.

1 to 5, when the girder 10 is a PC girder 11, the cantilever pedestal 220 can be fixed to the PC girder 11 through an anchor bolt, And the anchor bolts are fixed to the PC girder 11 through the through-holes 221.

7, when the girder 10 is a steel box girder 12, the lug 400 and the cantilever pedestal 220, which are installed to lift the steel box girder 120, So that the cantilever pedestal 220 can be fixed.

That is, one end of the fixing piece 500 is welded to the lug 400 and the other side end of the fixing piece 500 is welded to the cantilever support 220, thereby moving the cantilever support 220 to the upper portion of the steel box- The cantilever pedestal 220 is welded and fixed to the steel box girder 12 without welding the cantilever pedestal 220 directly to the steel box girder 12. [ So that it can be fixed.

Since the cantilever pedestal 220 is not directly welded to the steel box girder 12, it is prevented that the steel box girder 12 is thermally damaged by the heat generated during the welding, thereby preventing the coating from being peeled off or the strength being lowered .

The cantilever bottom plate 210 includes a bottom plate body 211 combined with the slab concrete 300 while being mounted on the upper portion of the first flange 221 and serving as a mold when the slab concrete 300 is installed, And a shear connector 212 formed on the upper portion of the slab concrete 211 to facilitate the synthesis with the slab concrete 300.

The cantilever bottom plate 210 is vertically formed at one end of the bottom plate body 211 and further includes a vertical portion 213 for preventing the slab concrete 300 from flowing down when the slab concrete 300 is poured Can be configured.

The shear connector 212 may be formed of a truss structure and may be formed in various shapes for compositing with other concrete.

Meanwhile, the cantilever base 220 may be shorter than the cantilever base 210 in a range of a length that prevents the cantilever base 210 from being conducted.

By forming the cantilever pedestal 220 shorter than the cantilever bottom plate 210, the length of the cantilever pedestal 220 made of a steel material can be reduced to reduce the material cost and the area protruding outside the girder can be reduced, The process of the present invention can be performed more easily.

At this time, the cantilever bottom plate 210 further includes a wing 214 protruding in the width direction of the cantilever bottom plate 210 in a range not supported by the cantilever pedestal 220.

The wing portion 214 is further formed on the cantilever bottom plate 210 so that the portion of the cantilever base 220 that is not supported by the cantilever base 220 is in close contact with the neighboring cantilever bottom plate 210 via the wing portion 214, It is possible to prevent the slab concrete from leaking to the lower portion of the cantilever bottom plate 210.

When the slab concrete 300 is installed by placing the cantilever pedestal 220 so as to be positioned on the same line as the upper surface of the girder 10, the cantilever bottom plate 200 and the cantilever bottom plate 200, The cantilever pedestal 220 is integrated with the slab concrete 300 so that the cantilever pedestal 220 is prevented from falling off and the structural stability is improved.

The inner bottom portion 100 includes an inner pedestal 120 having a left and a right side mounted on girders 10 adjacent to each other and spaced from each other along the longitudinal direction of the girder 10, The left and right side surfaces are respectively mounted on the inner bottom plate 10 and the front and rear side surfaces are mounted on the inner bottom plate 120 to support the four sides of the inner bottom plate 110.

The inner pedestal 120 protrudes from the front and rear sides of the inner pedestal body 121 so as to protrude from the inner bottom plate 110 And a bottom plate receiving portion 122 for allowing the bottom plate receiving portion 122 to be mounted.

The upper surface of the bottom plate receiving portion 122 is formed so as to be in line with the upper surface of the girder 10 so that the inner bottom plate 110 is supported on four sides when the inner bottom plate 110 is mounted .

In addition, a shear connection member 123 may be further provided on the upper surface of the inner pedestal body 121 so that the slab concrete 300 can be easily combined with the slab concrete 300.

The left and right side surfaces of the inner bottom plate 110 are fixed to the upper surface of the girder 10 and the front and rear surfaces of the inner bottom plate 110 are fixed to the bottom plate receiving portion 122 to serve as a mold when the slab concrete 300 is laid, A bottom plate body 111 to be combined with the concrete 300 and a shear connection member 112 formed on the bottom plate body 111 to facilitate the synthesis of the slab concrete 300, do.

Since the inner bottom plate 110 having such a structure is installed so as to support four sides, the load applied to the inner bottom plate 110 is easily dispersed to prevent cracking of the inner bottom plate 110, So that stable construction can be achieved.

8, the inner bottom plate 110 is protruded from the front and rear sides of the bottom plate body 111 to be continuous with another inner bottom plate 110 adjacent to the longitudinal direction of the bridge A plurality of connection stiffeners 113 may be further included.

At this time, slopes 114 are formed on the front and rear sides of the bottom plate body 111 so that the slab concrete 300 can be easily inserted between the adjacent bottom plate bodies 111, So that the inner bottom plate 110 can be made more solidly continuous.

As the connecting stiffener 113 is further installed, the coupling strength of the inner bottom plates 110 is further improved and the inner bottom plates 110 are more firmly connected and continuous.

A plurality of inner pedestals 120 (not shown) are disposed between the girder 10 and the girder 10 so as to be spaced from each other along the longitudinal direction of the girder 10, The front and rear sides of the girder 10 are fixed to the bottom plate receiving portion 122 formed on the front and rear sides of the inner bottom 120, A step of installing an inner bottom plate 110 so that the inner bottom plate 110 is installed so as to support the four sides of the outermost girder 10, and a step of fixing one side end to the upper surface of the outermost girder 10, A cantilever base for installing a plurality of cantilever pedestals 220 so as to be spaced apart from each other and a cantilever floor for mounting both ends of a cantilever bottom plate 210 to a first flange 221 of a neighboring cantilever pedestal 220; A plate installing step, Reinforcement for reinforced on the upper side of the bottom plate 110 and the cantilever floor plate 210 and is configured to include the concrete slab, the method comprising pouring the concrete slab (300).

The step of mounting the inner pedestal is a step of mounting a plurality of the inner pedestal 120 along the longitudinal direction of the girder 10 by mounting the left and right ends of the inner pedestal 120 on the neighboring girders 10.

The inner bottom plate 110 is installed so that four sides are supported by the girder 10 and the inner bottom 120 adjacent to each other so that the inner bottom plate 110 is supported by the inner bottom plate 120 The load is more easily dispersed, thereby preventing the inner bottom plate 120 from being cracked or broken, thereby greatly improving the structural stability.

On the other hand, when the girder is a PC girder, the anchor bolt may be installed and fixed to the girder through the first flange of the cantilever pedestal.

When the girder 10 is a steel box girder 12, the lug 400 and the cantilever pedestal 220 installed for lifting the steel box girder 12 are welded through the fixing piece 500, It is possible to fix the pedestal 220 to the steel box type girder 12 and prevent the cantilever pedestal 220 from being welded directly to the steel box type girder 12 so that the rigidity of the steel box type girder 12 is lowered, .

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

(10): Girder (11): PC girder
(12): Steel box girder (100): Inner bottom
(110): inner bottom plate (111): bottom plate body
(112): shear connector (113): connection stiffener
(114): an inclined surface (120): an inner pedestal
(121): Inner pedestal body (122): Floor plate pedestal
(123): shear connector (200): cantilever bottom
(210): cantilever bottom plate (211): bottom plate body
(212): shear connector (213): vertical section
(214): wing portion (220): cantilever support
(221): first flange (222): second flange
(223): web (224): shear connector
(300): Slab Concrete (400): Rug
(500)

Claims (6)

A bottom of the cantilever protruding outward from the outermost girder, and slab concrete laid on the top of the bottoms, the bottom structure comprising:
Wherein the cantilever bottom portion includes a first flange that is seated on an upper surface of the outermost girder, a second flange that is positioned to face the first flange and is formed to have a width narrower than the width of the first flange, And a plurality of cantilever brackets which are arranged on the upper surface of the girder and fixed to each other through the fixing portion and whose other ends are projected to the outside of the girder and are spaced apart from each other along the longitudinal direction of the girder, And a cantilever bottom plate installed on both sides of the first flange of the adjacent cantilever pedestal so that both ends thereof are laid so that the slab concrete can be laid. In the case where the girder is a steel box type girder, One end of the fastening piece is welded to the lug installed for lifting, and the other end of the fastening piece is fastened to the cantilever support The girder can be fixed to the steel box type girder without welding the cantilever pedestal directly to the steel box type girder so as to prevent heat damage to the steel box type girder,
The inner bottom portion includes an inner pedestal body that is respectively mounted on a girder adjacent to the left and right sides thereof and a bottom plate support portion that protrudes from the front and rear sides of the inner pedestal body so that the inner bottom plate can be mounted. And the front and rear sides of which are mounted on the bottom plate receiving portion and are supported on four sides so as to be supported by the inner bottom plate Respectively,
Further comprising a plurality of connecting stiffeners projecting from the front and rear side surfaces of the inner bottom plate so that the inner bottom plate can be continuous.



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