KR102559951B1 - Steel composite rahmen structure and construction method thereof - Google Patents

Abstract

The steel composite ramen bridge structure of the present invention includes a pair of walls 100; A steel girder 200 mounted on the wall 100; A bottom plate 300 formed by pouring concrete (C) on the upper part of the steel girder 200; including, but the steel girder 200 is installed in plurality at intervals from each other along the front and rear directions, and one side and the bottom of the other side edge Protrusion 210 protruding downward; Extensions 220 protruding outward from one side and the other side, respectively; In order to reinforce the extension part 220, a reinforcing part 230 coupled to the upper part of the extension part 220; is provided.

Description

Steel composite ramen bridge structure and its construction method {STEEL COMPOSITE RAHMEN STRUCTURE AND CONSTRUCTION METHOD THEREOF}

The present invention relates to the field of construction, and specifically to a steel composite ramen bridge structure and its construction method.

Ramen bridges are widely used for small and medium-sized rivers of 20 to 40 m because of the effect of reducing maintenance costs because bridge devices are not used. In addition, even if the span length of the bridge is long, there is no expansion joint, so maintenance of the bridge does not occur, as well as improving the driving safety and comfort of users.

In the case of a ramen bridge, a large moment occurs at the right angle part of the upper part of the wall because the girder including the wall and the floor plate is combined in a rigid structure. Therefore, it is important to install the girder so that it has a hinge structure when mounting the girder so that the weight of the girder does not act as a negative moment on the right leg. The structure that does not add the moment of the girder's own weight to the wall is an important technology to reduce the height of the bridge and reduce the size of the wall.

The above-mentioned conventional technical configuration, name, and drawing number are used only for the description of the prior art.

Korean Patent Registration No. 10-1993298 'Steel composite ramen bridge using horizontal and rotational displacement allowance and its construction method' relates to a steel composite ramen bridge using horizontal and rotational displacement allowance and its construction method, which can absorb horizontal and rotational displacement of both ends of a steel composite girder during construction, enable rapid and stable construction, and effectively control cracks at right angles caused by common load. A height adjustment plate whose height is adjusted and fixedly installed along the bolt fixture drawn out from; And an end insertion device including; and a pull-out insertion plate including a vertical plate portion in which the T-shaped connecting steel member formed at both ends of the steel composite girder is lowered and supported on the upper surface of the height adjustment plate and has a horizontal rotation hole formed therebetween. It is a steel beam exposed at both ends of the concrete girder part, and is formed in a T-shaped cross section inserted into the pull-out resistance insert plate, and includes a T-shaped connecting steel member with a horizontal rotation hole formed in the abdomen, and is mounted on the abutment portion by the end insertion device. It includes a steel composite girder.

Korean Patent Registration No. 10-2005970 'Steel composite ramen bridge and its construction method' discloses a steel girder 100 including an upper flange 110 and a web 120, a casing concrete 200 coupled to the steel girder 100 in a structure surrounding the lower side of the web 120, and a prestress including a steel wire 300 embedded in the casing concrete 200. Steel Composite Girder (A); A pair of abutments (10) on which the steel composite girder (A) is mounted; A support device 20 installed on the upper surface of the abutment 10 to support the steel composite girder (A); including, but at both front and rear ends of the steel composite girder (A), the lower part is embedded in the abutment 10, and the upper part is coupled with the right angle reinforcement 11 protruding to the upper surface of the abutment 10; protruding members 30 protruding outward; are coupled. As shown in FIG. 5, the steel composite girder (A) of the present invention has a structure in which the steel girder 100 and the casing concrete 200 are combined, and the steel wire 300 is embedded in the casing concrete 200 and tensioned. As a prestressed steel composite girder, it has the advantage of minimizing the shape of the girder.

In addition, since protruding members 30 coupled to the right angle reinforcing bars 11 protruding to the upper surface of the abutment 10 are installed at both front and rear ends of the steel composite girder (A), the coupling between the steel composite girder (A) and the abutment 10 is excellent. The excellent bonding strength between the abutment 10 and the steel composite girder A prevents cracking of the right leg.

Korean Patent Registration No. 10-1936762 'Steel composite ramen bridge having tensile resistance performance by end jack-up and its construction method' relates to a steel composite ramen bridge and its construction method. A support block for placing a wedge member in the gap between the upper surface and the upper surface; A slab formed by pouring reinforced concrete to the outside of the supporting block and girder member; It relates to a Ramen bridge, characterized in that it is configured to include.

Republic of Korea Patent No. 10-1993298 Republic of Korea Patent No. 10-2005970 Republic of Korea Patent No. 10-1936762

In the present invention, after mounting the steel girder, an efficient ramen bridge structure can be obtained by mounting the steel girder in a hinge structure so that the weight of the steel girder does not cause a negative moment on the upper part of the wall to form a structural system that is advantageous to dead weight and dead load.

In order to solve the above problems, the steel composite ramen bridge structure of the present invention includes a pair of walls 100; A steel girder 200 mounted on the wall 100; A floor plate 300 formed by pouring concrete (C) on the upper part of the steel girder 200; but, the steel girder 200 has a plurality of installations spaced apart from each other along the front and rear directions, and one side and the other side A protrusion 210 protruding downward at the bottom of the edge; Extensions 220 protruding outward from one side and the other side, respectively; In order to reinforce the extension part 220, a reinforcing part 230 coupled to the upper part of the extension part 220; is provided.

It is preferable that a pair of fall prevention members 120 coupled to the extension part 220 by bolts are installed on the upper surface of the wall 100 .

Preferably, the extension part 220 has a structure in which the width gradually widens toward the outside.

It is preferable that the fall prevention member 120 is fitted to the outer edge of the extension part 220 and fixed by bolts.

End reinforcing members 240 are coupled to both lateral edges of the steel girder 200 inward from the edge end, and the end reinforcing members 240 are spaced apart from each other in the front and rear with respect to the abdomen of the steel girder 200, so that the lower surface is coupled to the upper surface of the lower flange of the steel girder 200, and the outer surface is coupled to one side and the other side of the steel girder 200. It is preferably coupled to the inside of the plate 250.

The protruding portion 210 is coupled to the lower surface of the end reinforcing plate 250 and protrudes downward, and the lower surface preferably has a round structure convex downward along the front-back direction.

On the outer side of the wall 100, it is preferable that the lower part is embedded in the wall 100 and the upper part is coupled with the wall reinforcement 400 protruding from the upper part of the wall 100.

The wall reinforcing bars 400 are installed in plurality along the front and rear directions at mutual intervals, and the outer wall reinforcing bars 410 installed on the outside of the wall 100; It is preferable to include; inner wall reinforcement 420 installed spaced apart from the outer wall reinforcement 410 to the inside.

After the steel girder 200 is installed, the outer wall reinforcement 410 is formed to extend upward, and then is bent inward to be placed at a position spaced upward from the upper part of the steel girder 200, and the inner wall reinforcement 420 is bent inward and extended to be reinforced at a position spaced downward from the upper flange of the steel girder 200.

The outer wall reinforcement 410 is reinforced in both the upper side of the steel girder 200 and the section between the steel girder 200, and the inner wall reinforcement 420 is a pair of steel girders installed along the front and rear direction.

The reinforcing part 230 is coupled to protrude outward from the end of the steel girder 200 along the abdomen of the steel girder 200, and the lower surface is coupled along the center of the upper surface of the extension part 220. It is preferable to have a structure.

An end frame 520 installed on the upper side of the end of a pair of steel girders 200 installed along the front and rear directions of the right angle portion of the bottom plate 300; an inner formwork 510 spaced apart from the inside of the end frame 520 and installed in a section between the pair of steel girders 200; In order to fix the inner formwork 510, one side is fixed to the end frame 520, and the other side is fixed to the inner formwork 510. A rod structure coupling rod 530; A support frame 540 installed in a structure in which a front end and a rear end are raised on the upper side of the lower flange of the pair of steel girders 200; It is preferable that the concrete is cast and formed by a formwork 500 including a lower formwork 550 mounted on the upper surface of the support frame 540.

A method for constructing a steel composite ramen bridge structure according to an embodiment of the present invention includes a wall construction step of constructing the pair of walls 100; A steel girder mounting step of mounting the steel girder 200 on the upper part of the wall 100 so that the fall prevention member 120 is fitted to the outer edge of the extension part 220; A wall reinforcement step of arranging the outer wall reinforcement 410 and the inner wall reinforcement 420; a formwork installation step of installing the end frame 520, the inner formwork 510, the coupling bar 530, the support frame 540, and the lower formwork 550; A floor plate forming step of forming the floor plate 300 by pouring the concrete (C); includes.

In the present invention, an efficient ramen bridge structure can be taken because the weight of the girder does not cause a moment on the right leg portion when the steel girder is installed due to the protrusion of the round structure coupled to the lower surface of the girder.

1 is a representative drawing of Korean Patent Registration No. 10-1993298
Figure 2 is a representative drawing of Korean Patent Registration No. 10-2005970
Figure 3 is a representative drawing of Korean Patent Registration No. 10-1936762
Figure 4 is a view showing that the wall reinforcement is coupled to the upper surface of the wall according to an embodiment of the present invention
Figure 5 is a perspective view showing that the steel girder is mounted on the upper surface of the wall according to an embodiment of the present invention
Figure 6 is a side view showing that the steel girder according to an embodiment of the present invention is mounted on the upper surface of the wall and fixed by a fall prevention member
Figure 7 is a perspective view showing that the inner wall reinforcement according to an embodiment of the present invention is placed
8 is a view showing the reinforcement of the outer wall according to an embodiment of the present invention
9 is a view showing that the inner wall reinforcement and the outer wall reinforcement are coupled and the formwork is coupled according to an embodiment of the present invention.
Figure 10 is a perspective view showing that the concrete of the right angle portion is poured by the formwork according to an embodiment of the present invention
Figure 11 is a perspective view showing that the casting of the floor plate according to an embodiment of the present invention is completed
12 is a perspective view of a steel composite ramen bridge in which deck placement is completed according to an embodiment of the present invention
13 is a perspective view of a steel girder according to an embodiment of the present invention
Figure 14 is a bottom perspective view showing that the protrusions of the round structure are coupled according to an embodiment of the present invention
15 is a detailed side view of the end side of a steel girder showing that an extension part, a protrusion part, a reinforcement part, and an end reinforcement part are combined according to an embodiment of the present invention.
16 is a perspective view of a combined formwork in which an inner formwork, an end frame, a coupling rod, a support frame, and a lower formwork are combined according to an embodiment of the present invention.
17 is a lower perspective view of a formwork in which an inner formwork, an end frame, a coupling bar, a support frame, and a lower formwork are combined according to an embodiment of the present invention.
Figure 18 is a combined perspective view showing that the inner formwork, end frame, and coupling rods are coupled according to an embodiment of the present invention
Figure 19 is a combined perspective view showing that the inner formwork, end frame, coupling rod, support frame, and lower formwork are coupled according to an embodiment of the present invention
20 is a perspective view showing that a support frame and a lower formwork are coupled according to an embodiment of the present invention
21 is a view showing that a support frame and a lower formwork are coupled according to an embodiment of the present invention
22 is a view showing that formwork is installed and concrete is poured according to an embodiment of the present invention
23 is a perspective view showing that the extension part is formed in an enlarged structure along an outward direction according to an embodiment of the present invention.
24 is a bottom perspective view showing that the extension part is formed in an enlarged structure along an outward direction according to an embodiment of the present invention.
25 is a perspective view showing a plurality of steel girders mounted according to an embodiment of the present invention
Figure 26 is a perspective view showing that the extension of the expansion structure according to an embodiment of the present invention is fixedly installed by the fall prevention member
Figure 27 is a cross-sectional view showing that the lower surface of the reinforcing part according to an embodiment of the present invention is formed in a round structure along the front-back direction.

An embodiment of the steel composite ramen bridge structure and its construction method according to the present invention will be described in detail with reference to the accompanying drawings.

In addition, terms such as first and second used below are only identification symbols for distinguishing the same or corresponding components, and the same or corresponding components are not limited by the terms first and second.

In addition, in the contact relationship between each component, coupling does not mean only the case where each component is in direct physical contact, but another configuration is interposed between each component, and the component is in contact with the other configuration.

Hereinafter, a steel composite ramen bridge structure and a construction method thereof according to an embodiment of the present invention will be described in detail with reference to the accompanying tables and drawings.

The steel composite ramen bridge structure of the present invention includes a pair of walls 100; A steel girder 200 mounted on the wall 100; A bottom plate 300 formed by pouring concrete (C) on the upper part of the steel girder 200; including, but the steel girder 200 is installed in plurality at intervals from each other along the front and rear directions, and one side and the bottom of the other side edge Protrusion 210 protruding downward; Extensions 220 protruding outward from one side and the other side, respectively; In order to reinforce the extension part 220, a reinforcing part 230 coupled to the upper part of the extension part 220; is provided.

At this time, as shown in FIG. 27, the protruding portion 210 is coupled to the lower surface of the end reinforcing plate 250 and protrudes downward, and the lower surface preferably has a round structure convex downward along the front-back direction.

This is because the steel girder 200 is mounted in a hinge structure after the steel girder 200 is installed, so the weight of the steel girder 200 does not cause a negative moment at the right corner of the wall. In particular, since it is formed in a round structure along the front-rear direction, there is a feature of having a hinge structure in the lateral direction and a hinge structure in the front-rear direction.

After mounting the steel girder 200, it is preferable to install a pair of fall prevention members 120 bolted to the extension part 220 on the upper surface of the wall 100 to prevent the fall of the steel girder 200.

The fall prevention member 120 is installed in the structure shown in FIG. 26, the lower part is embedded in the wall 200, the upper part is exposed to the upper surface of the wall 200, and the exposed part has a structure that is fitted into the extension part 220.

At this time, in order to maximize the efficiency of fall prevention, as shown in FIG. 26, the extension portion 220 has a structure in which the width gradually widens toward the outside, and the fall prevention member 120 is fitted to the outer edge of the extension portion 220. It is preferable to be fixed by a bolt.

In addition, in order to secure the rigidity of both end edges of the steel girder 200, it is preferable that the reinforcing part 230 and the end reinforcing member 240 are combined as shown in FIG.

Specifically, the end reinforcing members 240 are coupled to both side edges of the steel girder 200 inward from the edge end, but the end reinforcing members 240 are spaced apart from each other in the front and rear with respect to the abdomen of the steel girder 200, so that the lower surface is coupled to the upper surface of the lower flange of the steel girder 200, and the outer surface is coupled to one side and the other side of the steel girder 200 End reinforcement plate ( 250) is preferably coupled to the inside.

Outside of the wall 100, it is preferable that the lower part is embedded in the wall 100 and the upper part is coupled with the wall reinforcing bar 400 protruding to the upper part of the wall 100. The wall reinforcement 400 is reinforced as shown in FIGS. 6, 7, and 8. Specifically, a plurality of wall reinforcements 400 are installed along the front-back direction at intervals from each other, and installed outside the wall 100. External wall reinforcement 410); It is preferable to include; inner wall reinforcement 420 installed spaced apart from the outer wall reinforcement 410 inwardly.

At this time, after the steel girder 200 is installed, the outer wall reinforcement 410 is formed to extend upward, and then is bent inward to be placed at a position spaced upward from the upper part of the steel girder 200, and the inner wall reinforcement 420 is bent inward and extended to be reinforced at a position spaced apart from the upper flange of the steel girder 200.

The wall reinforcement 400 is reinforced between the steel girder 200 and the bottom plate concrete to improve the stiffness of the right leg.

As shown in FIG. 8, the outer wall reinforcement 410 is reinforced in both the upper side of the steel girder 200 and the interval between the steel girder 200, and the inner wall reinforcement 420 is installed along the front and rear direction as shown in FIG.

It is preferable that the reinforcing part 230 is coupled so as to protrude outward from the end of the steel girder 200 along the abdomen of the steel girder 200, and has a structure in which the lower surface is coupled along the central part of the upper surface of the extension part 220.

The right angle portion of the bottom plate 300 includes an end frame 520 installed above the end of a pair of steel girders 200 installed along the front and rear directions; An inner formwork 510 spaced apart from the inside of the end frame 520 and installed in a section between the pair of steel girders 200; In order to fix the inner formwork 510, one side is fixed to the end frame 520, the other side is fixed to the inner formwork 510, the rod structure of the coupling rod 530; A support frame 540 installed in a structure in which a front end and a rear end are raised on the upper side of the lower flange of the pair of steel girders 200; It is preferable that concrete is poured and formed by the formwork 500 including; a lower formwork 550 mounted on the upper surface of the support frame 540.

In this case, since it is possible to pour concrete at the right corner without installing a shoring, it is possible to improve the construction speed and simplify the process by excluding the shoring construction from the construction process.

A method for constructing a steel composite ramen bridge structure according to an embodiment of the present invention includes a wall construction step of constructing a pair of walls 100; A steel girder mounting step of mounting the steel girder 200 on the upper part of the wall 100 so that the fall prevention member 120 is fitted to the outer edge of the extension part 220; A wall reinforcement step of arranging the outer wall reinforcement 410 and the inner wall reinforcement 420; A formwork installation step of installing the end frame 520, the inner formwork 510, the coupling rod 530, the support frame 540, and the lower formwork 550; It includes; floor plate forming step of forming the floor plate 300 by pouring concrete (C).

C : Concrete 100 : Wall
120: fall prevention member 200: steel girder
210: protrusion 220: extension
230: reinforcement part 240: end reinforcement member
250: end reinforcement plate 300: bottom plate
400: wall reinforcement 410: outer wall reinforcement
420: inner wall reinforcement 500: formwork
510: inner formwork 520: end frame
530: coupling bar 540: support frame
550: lower formwork

Claims (13)

A pair of walls (100);
A steel girder 200 mounted on the wall 100;
A bottom plate 300 formed by pouring concrete (C) on the upper part of the steel girder 200; including,
A plurality of steel girders 200 are installed at mutual intervals along the front and rear directions,
Protrusions 210 protruding downward from one side and the other edge bottom;
Extensions 220 protruding outward from one side and the other side, respectively;
A reinforcement part 230 coupled to the upper part of the extension part 220 to reinforce the extension part 220;
A pair of fall prevention members 120 coupled with bolts to the extension part 220 are installed on the upper surface of the wall 100,
The extension part 220 has a structure in which the width gradually widens toward the outside, and
The fall prevention member 120 is fitted to the outer edge of the extension part 220 and fixed by a bolt,
End reinforcing members 240 are coupled to both side edges of the steel girder 200 from the edge end to the inside,
The end reinforcing member 240 is
It is spaced apart in the front and rear with respect to the abdomen of the steel girder 200, the lower surface is coupled to the upper surface of the lower flange of the steel girder 200, and the outer surface is one side and the other side of the steel girder 200. It is coupled to the inner side of the end reinforcing plate 250 coupled to,
The protrusion 210 is
It is coupled to the lower surface of the end reinforcing plate 250 and protrudes downward, and the lower surface has a round structure convex downward along the front-back direction,
On the outside of the wall 100, the lower part is embedded in the wall 100, and the upper part is coupled with the wall reinforcement 400 protruding to the upper part of the wall 100,
The wall reinforcing bars 400 are installed in plurality along the front and rear directions at mutual intervals, and the outer wall reinforcing bars 410 installed on the outside of the wall 100;
Including; inner wall reinforcement 420 installed spaced apart from the outer wall reinforcement 410 inwardly,
The outer wall reinforcement 410 is formed extending upward after the installation of the steel girder 200 and then bent inward to reinforce it at a position spaced upward from the upper part of the steel girder 200,
The inner wall reinforcement 420 is bent and extended inward to be reinforced at a position spaced below the upper flange of the steel girder 200,
The outer wall reinforcement 410 is reinforced in both the upper side of the steel girder 200 and the section between the steel girder 200,
The inner wall reinforcement 420 is reinforced only in the section between the pair of steel girders 200 installed along the front and rear directions,
The reinforcing part 230 is coupled to protrude outward from the end of the steel girder 200 along the abdomen of the steel girder 200,
In addition to the structure in which the lower surface is coupled along the central portion of the upper surface of the extension part 220,
The right corner of the bottom plate 300
An end frame 520 installed above the end of a pair of steel girders 200 installed along the front and rear directions;
an inner formwork 510 spaced apart from the inside of the end frame 520 and installed in a section between the pair of steel girders 200;
In order to fix the inner formwork 510, one side is fixed to the end frame 520, and the other side is fixed to the inner formwork 510. A rod structure coupling rod 530;
A support frame 540 installed in a structure in which a front end and a rear end are raised on the upper side of the lower flange of the pair of steel girders 200;
A steel composite ramen bridge structure, characterized in that the concrete is poured and formed by the formwork 500 including a lower formwork 550 mounted on the upper surface of the support frame 540.
delete delete delete delete delete delete delete delete delete delete delete As a method for constructing a steel composite ramen bridge structure of claim 1,
A wall construction step of constructing the pair of walls 100;
A steel girder mounting step of mounting the steel girder 200 on the upper part of the wall 100 so that the fall prevention member 120 is fitted to the outer edge of the extension part 220;
A wall reinforcement step of arranging the outer wall reinforcement 410 and the inner wall reinforcement 420;
a formwork installation step of installing the end frame 520, the inner formwork 510, the coupling bar 530, the support frame 540, and the lower formwork 550;
A ramen bridge structure construction method comprising a; floor plate forming step of forming the floor plate 300 by pouring the concrete (C).

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