KR102197011B1 - Steel-concrete composite rahman bridge - Google Patents

Abstract

The present invention relates to a steel girder-support assembly structure comprises: a steel girder (300); and support members (200) respectively engaged with a front edge and a rear edge of the steel girder (300). The support members (200) includes: a support plate (210); and a pair of standing plates (230) engaged with an upper surface of the support plate (210) in a vertical direction with a standing structure. The pair of standing plates (230) are engaged to be apart from each other in a sideway direction. On a front edge and a rear edge of an upper flange (310) and a lower flange (330) of the steel girder (300), a pair of upper penetrating holes (311) and a pair of lower penetrating holes (331) are respectively formed to penetrate the standing plate (230) of the support members (200). The steel girder (300) is inserted into and engaged with the pair of support members (200) installed by being apart from each other in a forward/backward direction towards a lower side. According to the present invention, the steel girder-support assembly structure is a structure manufactured for a steel composite Rahman bridge, and is able to minimize a negative moment generated on a corner unit of the Rahman bridge.

Description

Steel girder-support assembly structure and fabrication. Steel composite ramen bridge using this {STEEL-CONCRETE COMPOSITE RAHMAN BRIDGE}

The present invention relates to the field of construction, and in detail, a steel girder-support assembly structure and fabrication. It relates to a steel composite ramen bridge using this.

A ramen bridge is a bridge structure in which a girder and a wall are joined in a steel structure, and a large positive moment occurs in the right leg, and the size of the wall and the foundation is large.

Because of this structure, a girder with a high shape that can resist large moments, a wall with a large thickness, and a wide foundation are required. Also, for the construction of a wide foundation, the amount of excavation increases and the construction period is lengthened.

To solve this problem, development is being made to make the connection of the wall and the girder into a hinged connection, but most of the developed technologies are limited to the connection between the upper part of the wall and the girder, so the development of a technology that can reduce the size of the wall and the foundation is difficult. It is an urgent situation.

Korean Patent Registration No. 10-0742206'Steel composite ramen bridge having long length and low height by moment redistribution and its construction method' has a composite structure using a steel girder and concrete, and it is based on the bending moment by its own weight and the working load. By having a structure capable of redistributing the bending moment, the present invention relates to a new structured steel-composite ramen bridge suitable for use in long span and low profile bridges, and its construction method. In the present invention, it is composed of a concrete vertical wall 10 on both sides, and a span portion installed between the vertical wall 10; The central portion 20 of the span is composed of a steel girder 21 and a bottom plate 40 installed thereon; The concrete vertical wall 10 and the branch part 30 are integrally connected to each other in a rigid connection form, a steel-concrete composite girder in which the steel girder 21 is embedded in the concrete and a floor plate installed thereon ( As a construction method of a steel composite ramen bridge consisting of 40), the concrete vertical wall 10 on both sides is provided so that a girder fixing device 11 capable of fixing the steel girder 21 is integrally provided at the upper end of the vertical wall 10 Installing; Simply mounting the steel girders 21 constituting the central portion 20 on the upper portions of the concrete vertical walls 10 on both sides; A step of integrally combining the both ends of the steel girder 21 with the vertical wall 10 to strengthen the steel girder 21; And a steel-concrete composite girder having a structure in which a steel girder 21 is buried in the concrete by pouring concrete outside the both ends of the steel girder 21 at the position of the branch part 30, integrally with the vertical wall 10. A method of constructing a steel composite ramen bridge comprising the step of constructing to form a branch part 30 and forming a bottom plate 40 on the upper part of the steel girder 21 and the branch part 30, and thereby Constructed steel composite ramen bridge is provided.

Korean Patent Registration No. 10-1993298'Steel composite ramen bridge using horizontal and rotational displacement tolerance and its construction method' is a quick and stable construction while being able to absorb the horizontal and rotational displacement of both ends of the steel composite girder that occurs during the construction process. This is a steel composite ramen bridge using horizontal and rotational displacement allowance and its construction method that can effectively control the right leg crack due to common load. The steel composite ramen bridge using horizontal and rotational displacement allowance is the upper surface of the abutment. A height adjustment plate that is fixedly installed by adjusting the height along the bolt fasteners drawn out from; And a pull-down insertion plate including a vertical plate portion in which a T-shaped connection steel member formed at both ends of the steel composite girder is downwardly inserted and supported on the upper surface of the height adjustment plate and formed with a horizontal rotation hole. ; As a steel beam exposed to both ends of the concrete girder, it is formed in a T-shaped cross section that is inserted into the pull-out resistance insertion plate, and a horizontal rotation hole is mounted on the alternating part by an end insertion device including a T-shaped connecting steel formed in the abdomen. It includes a steel composite girder.

Republic of Korea Patent Registration No. 10-1936762'steel composite ramen bridge having improved tensile resistance performance by end jack-up and its construction method' relates to a steel composite ramen bridge and its construction method, and more specifically, one side is the shift A wedge member is inserted in the gap between the upper surface of the alternating belt, which is embedded in and the other side penetrates the end of the girder member and is tensioned upward, and is fixed to the girder member and mounted on the upper surface of the alternation. A supporting block to be posted; A slab formed by pouring reinforced concrete outside the support block and the girder member; It relates to a ramen bridge, characterized in that configured to include.

Korean Patent Registration No. 10-0742206 Korean Patent Registration No. 10-1993298 Korean Patent Registration No. 10-1936762

The present invention reduces the size of the base part of the ramen bridge, reduces the momentum of the right leg by forming a hinged structure between the wall and the girder, and shortens the construction period to produce an economical steel girder-support assembly structure and fabrication. We present a steel composite ramen bridge using this.

In order to solve the above problems, the steel girder of the present invention-the supporting assembly structure includes a steel girder (300); Including; but the support member 200 coupled to the front and rear edges of the steel girder 300, respectively, wherein the support member 200 is a support plate 210, the support plate 210 in a standing structure along the vertical direction In addition to including a coupled pair of standing plates 230, the pair of standing plates 230 are coupled to be spaced apart from each other along the lateral direction, and the upper flange 310 and the lower portion of the steel girder 300 A pair of upper through holes 311 and a pair of lower through holes 331 are formed at the front and rear edges of the flange 330 so that the standing plate 230 of the support member 200 penetrates, respectively, The steel girder 300 is fitted in a downward direction to a pair of the support members 200 spaced apart from each other along the line.

Based on the lateral direction, a flange support part 220 protrudes from the outside of the pair of standing plates 230 to the upper side of the support plate 210 to support the lower surface of the lower flange 330 of the steel girder 300 It is desirable that it is done.

It is preferable that the upper surface of the flange support part 220 has a round structure that is convex upward in the front-rear direction.

A girder support part 340 protruding downward is coupled to the front and rear edges of the lower flange 330 of the steel girder 300, and the girder support part 340 is at the front and the rear of the lower flange 330, respectively. It is preferably coupled to a section between the formed pair of lower through-holes 331, and a lower surface coupled to the upper surface of the support plate 210.

It is preferable that the lower surface of the girder support part 340 has a round structure convex in the lower direction based on the front and rear directions.

In order to drive the hinge of the steel girder 300 and the support member 200, the steel rod 500 is provided to pass through the pair of standing plates 230 and the abdomen 320 of the steel girder 300 in common. It is preferably combined.

A method of manufacturing a steel girder-bearing assembly structure according to an embodiment of the present invention comprises: a standing plate coupling step of coupling a pair of the standing plates 230 to an upper surface of the supporting plate 210; A flange support part coupling step of coupling the flange support part 220 to the outside of the pair of standing plates 230 so that the side surfaces of the standing plate 230 and the flange support part 220 are in surface contact; Steel girder manufacturing step of manufacturing a steel girder 300; A through-hole forming step of forming the upper through-hole 311 and the lower through-hole 331 so that the standing plate 230 passes through the steel girder 300; The girder support so that the upper surface of the flange support part 220 is in contact with the lower surface of the lower flange 330 of the steel girder 300, so that the lower surface of the girder support part 340 contacts the upper surface of the support plate 210 Girder support unit coupling step of coupling the unit 340; A steel bar hole for forming a steel bar hole in the standing plate 230 and the abdomen 320 so that the steel bar 500 passes through the abdomen 320 of the standing plate 230 and the steel girder 300 in common It includes; forming step.

Steel girder according to an embodiment of the present invention-a steel composite ramen bridge using a supporting assembly structure is spaced from each other in the front and rear, a plurality of piles 10 are installed in a lateral direction; A concrete block 100 coupled in common to an upper portion of the plurality of piles 10 installed in the lateral direction; The support member 200 installed on the upper surface of the block 100; The steel girder 300 fitted to the pair of support members 200 spaced apart from each other based on the front-rear direction; A connection slab 20 coupled to the front and rear outer sides of the steel girder 300; And a bottom plate 30 on which concrete (C) is poured and installed on the top of the steel girder 300 and the connection slab 20.

The connection slab 20 and the steel girder 300 are mutually coupled by a connection slab coupling member 700, and the connection slab coupling member 700 has an inner region of the abdomen 320 and the standing plate 230 ) Is fitted to the steel bar 500 so as to be located in the interstitial region, and the outer region is embedded in the connection slab 20 with a structure through which the connection slab reinforcement 20-S embedded in the connection slab 20 penetrates It is desirable to be.

A method of constructing a steel-composite ramen bridge according to an embodiment of the present invention includes a foundation installation step of installing the support member 200 on the pile 10, the concrete block 100, and the concrete block 100 ; A steel girder installation step of fitting and coupling the steel girder 300 to the standing plate 230 of the support member 200; A coupling part installation step of installing the steel rod 500 and the connection slab coupling member 700; A slab reinforcement coupling step of fitting and coupling the connection slab reinforcement (20-S) to the connection slab coupling member 700; A connecting slab forming step of pouring concrete to form the connecting slab 20; Includes; a floor plate installation step of pouring the concrete (C) to install the floor plate 30.

The concrete (C) poured for installation of the floor plate 30 is poured so that the front and rear edge regions of the steel girder 300, the connection slab coupling member 700, and the inner region of the connection slab 20 are buried. It is desirable to be.

In the present invention, since the steel girder is hinged to the supporting member, the negative moment generated in the right leg can be reduced. In the structure of the ramen bridge, there is an advantage of implementing a slim ramen bridge because the connecting slab is first joined to the girder before the concrete is placed on the floor plate, and the concrete is then placed to form the floor plate.

1 is a representative drawing of Korean Patent Registration No. 10-0742206
2 is a representative drawing of Korean Patent Registration No. 10-1993298
3 is a representative drawing of Korean Patent Registration No. 10-1936762
4 is a side view showing that a steel girder, a support member, and a connection slab are coupled to each other according to an embodiment of the present invention.
Figure 5 is a view showing that the connection slab reinforcement is fitted to the coupling member according to an embodiment of the present invention
6 is a perspective view of a coupling member according to an embodiment of the present invention
Figure 7 is a view showing that the connection slab reinforcement is fitted to a coupling member according to another embodiment of the present invention
8 is a perspective view of a coupling member according to another embodiment of the present invention
9 is a perspective view showing that a steel girder is coupled to a support member according to an embodiment of the present invention
10 is a view showing that the height adjustment plate 600 is installed in the area between the girder support part and the support plate 210 according to an embodiment of the present invention
11 is a view showing that the support member according to an embodiment of the present invention is installed in a lateral direction
12 is a front view of a support member according to an embodiment of the present invention
13 is a perspective view of a support member according to an embodiment of the present invention
14 is a view showing that a girder support part according to an embodiment of the present invention is coupled to a lower surface of a steel girder
15 is a perspective view showing that an upper through hole 311 and a lower through hole 331 are formed according to an embodiment of the present invention
16 is a view showing that a connection slab is combined according to an embodiment of the present invention
17 is a process chart of installing a file according to an embodiment of the present invention
18 is a process diagram of installing a support member according to an embodiment of the present invention
19 is a process diagram of installing a steel girder according to an embodiment of the present invention
20 is a process diagram of installing a connection slab according to an embodiment of the present invention
21 is a process diagram of pouring a floor plate according to an embodiment of the present invention

Steel girder according to the present invention-supporting assembly structure and fabrication. An embodiment of a steel composite ramen bridge using this will be described in detail with reference to the accompanying drawings, and in the description with reference to the accompanying drawings, the same or corresponding constituent elements are given the same reference numbers, and duplicate descriptions thereof are omitted. I will do it.

In addition, terms such as first and second used hereinafter are merely identification symbols for distinguishing the same or corresponding elements, and the same or corresponding elements are limited by terms such as first and second. no.

In addition, the term “couple” does not mean only a case in which each component is in direct physical contact with each other in the contact relationship between each component, but a different component is interposed between each component, and the component is It should be used as a concept that encompasses each contact.

Hereinafter, with reference to the accompanying drawings, steel girder-support assembly structure and fabrication. The steel composite ramen bridge using this will be described in detail.

The steel girder of the present invention-the supporting assembly structure includes a steel girder 300; Including, but the support member 200 coupled to the front and rear edges of the steel girder 300, respectively, as long as the support member 200 is coupled in a standing structure along the vertical direction from the upper surface of the support plate 210, the support plate 210 In addition to including a pair of standing plates 230, a pair of standing plates 230 are coupled to be spaced apart from each other along the lateral direction, and the upper flange 310 and the lower flange 330 of the steel girder 300 A pair of upper through-holes 311 and a pair of lower through-holes 331 are formed at the front and rear edges so that the standing plate 230 of the support member 200 penetrates, respectively, as long as they are spaced apart from each other along the front and rear directions. The steel girder 300 is fitted to the pair of support members 200 in the downward direction. The steel girder-support assembly structure of the present invention is a structure manufactured for a steel-composite ramen bridge, and it is possible to minimize the negative moment generated in the right leg of the ramen bridge.

Based on the lateral direction, it is preferable that the flange support part 220 is protruded to the upper side of the support plate 210 to support the lower flange 330 of the steel girder 300 outside the pair of standing plates 230 .

It is preferable that the upper surface of the flange support part 220 has a round structure that is convex upward in the front-rear direction.

At the front and rear edges of the lower flange 330 of the steel girder 300, a girder support part 340 protruding downward is coupled, and the girder support part 340 is a pair of each formed at the front and rear of the lower flange 330 It is preferably coupled to the section between the lower through hole 331, the lower surface is coupled to contact the upper surface of the support plate 210.

Based on the front-rear direction, it is preferable that the lower surface of the girder support part 340 has a round structure convex in the lower direction.

In order to drive the hinge of the steel girder 300 and the support member 200, it is preferable that the steel bar 500 is combined to pass through the abdomen 320 of the pair of standing plates 230 and the steel girder 300 in common. Do.

A method of manufacturing a steel girder-support assembly structure according to an embodiment of the present invention includes a standing plate coupling step of coupling a pair of standing plates 230 to an upper surface of the support plate 210; A flange support coupling step of coupling the flange support 220 to the outside of the pair of standing plates 230 so that the side surfaces of the standing plate 230 and the flange support 220 are in surface contact; Steel girder manufacturing step of manufacturing a steel girder 300; A through hole forming step of forming an upper through hole 311 and a lower through hole 331 so that the standing plate 230 passes through the steel girder 300; While the upper surface of the flange support part 220 is in contact with the lower surface of the lower flange 330 of the steel girder 300, the girder support part 340 is coupled so that the lower surface of the girder support part 340 is in contact with the upper surface of the support plate 210 The girder support part coupling step; Includes; a steel bar hole forming step of forming a steel bar hole in the standing plate 230 and the abdomen 320 so that the steel bar 500 is commonly penetrated through the abdomen 320 of the standing plate 230 and the steel girder 300. .

Steel girder according to an embodiment of the present invention-a steel composite ramen bridge using a supporting assembly structure is spaced from each other in the front and rear, a plurality of piles 10 are installed in a lateral direction; A concrete block 100 that is commonly coupled to the upper portion of the plurality of piles 10 installed in the lateral direction; A support member 200 installed on the upper surface of the block 100; A steel girder 300 fitted into a pair of support members 200 spaced apart from each other based on the front and rear directions; A connection slab 20 coupled to the front and rear outer sides of the steel girder 300; It includes; a steel girder 300 and a floor plate 30 on which concrete (C) is poured and installed on the upper part of the connection slab 20.

The connection slab 20 and the steel girder 300 are mutually coupled by the connection slab coupling member 700, but the connection slab coupling member 700 has an inner region between the abdomen 320 and the standing plate 230. It is fitted to the steel bar 500 so as to be positioned, and the outer region is preferably embedded in the connection slab 20 in a structure through which the connection slab reinforcement 20-S embedded in the connection slab 20 penetrates.

The foundation is formed of a plurality of piles 10 and concrete blocks 100. At this time, the concrete block 100 may be formed by casting in place or a precast block, and the pile 10 may be applied to both a steel pipe pile and a PHC pile. In the present invention, the size of the foundation can be reduced because the foundation part formed of the existing wall concrete and the foundation concrete is composed of the pile 10 and the concrete block 100 formed only on the pile 10. In addition, it has the advantage of shortening the construction period for the foundation work.

In addition, the steel girder 300 may be a pre-flex steel composite girder or a steel composite girder, and because the steel girder or the pre-flex steel composite girder is combined with the concrete block 100 to have a hinged structure, It can reduce the negative moment that occurs.

As shown in FIG. 9, an upper through hole 311 and a lower through hole 331 are formed in the upper and lower flanges of the steel girder 300, respectively, and a standing plate in the upper through hole 311 and the lower through hole 331 It has a structure in which (230) is fitted. This implements the hinge coupling of the steel girder 300 and the concrete block 100, and improves the binding force to form a stable right leg.

As shown in FIG. 13, the flange support part 220 is coupled to the upper surface of the support plate 210 in a structure in which the inner surface contacts the outer surface of the standing plate 230.

The upper surface formed in a round structure prevents damage to the lower flange when the steel girder 300 is bent downward, as well as allows the end of the steel girder 300 to rotate freely. When the steel girder 300 is fitted to the supporting member 200, the structure is brought into contact with the upper surface of the flange support 220 on the lower flange of the steel girder 300.

As shown in FIGS. 10 and 14, the girder support part 340 is formed to protrude downwardly from the lower surface of the lower flange, and is formed as if the abdomen of the steel girder 300 is extended.

The bottom surface of the girder support part 340 is formed in a convex round structure in the downward direction so that the end of the steel girder 300 rotates freely after the steel girder 300 and the support member 200 are coupled to maintain the hinge structure. It is to do.

That is, when the lower surface of the girder support part 340 and the upper surface of the flange support part 220 are formed in a round structure, after the steel girder 300 and the support member 200 compete in a hinge structure, a minor moment generated in the right leg In order to reduce the, it is to free the rotational displacement of the steel girder 300.

Through this structure, the steel girder 300 and the support member 200 in the girder support part 340 and the flange support part 220 are in contact with each other and are supported.

The height adjustment plate 600 is installed in the area between the girder support part 340 and the support plate 210 as shown in FIG. 10, and the girder support part due to manufacturing errors of the steel girder 300 or construction errors of the support member 200 The spaces generated in the 340 and the base plate 210 are filled to have a structure in which they contact each other.

The steel bar 500 is installed in a structure as shown in FIGS. 9 and 10, and implements a hinge structure of the steel girder 300 and the support member 200, and controls the displacement of the steel girder 300 in the front and rear directions.

As shown in FIG. 16, the connection slab 20 is coupled to the steel girder 300 by a coupling member 700. Since the coupling member 700 coupled to the steel rod 500 is a structure fitted to the steel rod, the load of the connection slab 20 does not cause a bending stress on the steel girder 300.

Therefore, the connection slab 20 is coupled to the steel girder 300 in a hinge structure until the bottom plate is formed and integrated with the steel girder 300.

A method for constructing a steel-composite ramen bridge according to an embodiment of the present invention includes a foundation installation step of installing a support member 200 on an upper portion of the pile 10, the concrete block 100, and the concrete block 100; Steel girder installation step of fitting and coupling the steel girder 300 to the standing plate 230 of the support member 200; A coupling part installation step of installing the steel rod 500 and the connection slab coupling member 700; The slab reinforcement coupling step of fitting the connection slab reinforcement (20-S) to the connection slab coupling member 700; Connection slab forming step of pouring concrete to form the connection slab 20; It includes; a floor plate installation step of pouring concrete (C) for installation of the floor plate 30.

It is preferable that the concrete (C) poured for installation of the floor plate 30 is poured so that the front and rear edge regions of the steel girder 300, the connection slab coupling member 700, and the inner region of the connection slab 20 are buried.

As shown in FIG. 19, after the steel girder installation step, the floor plate concrete is not immediately poured, but the connection slab 20 is first coupled to the steel girder 300. Through this, the steel girder 300, the connection slab 20, and the support member 200 all maintain the bonded state of the hinge structure until the concrete (C) poured to form the bottom plate 30 is cured.

Through this, as well as dispersing the moment of the right leg of the ramen bridge, it is possible to minimize the transfer of the bending load to the concrete block 100 and the pile 10.

C: concrete 10: pile
20: connection slab 20-S: connection slab reinforcement
30: floor plate 100: concrete block
200: support member 210: support plate
220: flange support 230: standing plate
240: shear connector 300: steel girder
310: upper flange 311: upper through hole
320: abdomen 330: lower flange
331: lower through hole 340: girder support
500: steel bar 600: plate
700: connection slab coupling member

Claims (11)

Steel girder 300;
Including; support members 200 respectively coupled to the front and rear edges of the steel girder 300
The support member 200 is
Base plate 210,
In addition to including a pair of standing plates 230 coupled in a standing structure along the vertical direction on the upper surface of the base plate 210,
The pair of standing plates 230 are coupled to be spaced apart from each other along the lateral direction,
At the front and rear edges of the upper flange 310 and the lower flange 330 of the steel girder 300, a pair of upper through holes 311 and a pair so that the standing plate 230 of the support member 200 penetrates The lower through-holes 331 of are respectively formed,
The steel girder 300 is fitted in a downward direction to a pair of support members 200 spaced apart from each other along the front and rear directions,
Based on the lateral direction, a flange support part 220 protrudes from the outside of the pair of standing plates 230 to the upper side of the support plate 210 to support the lower surface of the lower flange 330 of the steel girder 300 And
The upper surface of the flange support 220 is a round structure convex upward in the front-rear direction,
A girder support part 340 protruding downward is coupled to the front and rear edges of the lower flange 330 of the steel girder 300, and the girder support part 340 is at the front and the rear of the lower flange 330, respectively. It is coupled to the section between the formed pair of lower through-holes 331, the lower surface is coupled to contact the upper surface of the base plate 210,
Based on the front-rear direction, the lower surface of the girder support part 340 has a convex round structure in the lower direction,
In order to drive the hinge of the steel girder 300 and the support member 200, a steel rod 500 is provided to pass through the pair of standing plates 230 and the abdomen 320 of the steel girder 300 in common. Are combined,
A standing plate coupling step of coupling a pair of the standing plates 230 to the upper surface of the base plate 210;
A flange support part coupling step of coupling the flange support part 220 to the outside of the pair of standing plates 230 so that the side surfaces of the standing plate 230 and the flange support part 220 are in surface contact;
Steel girder manufacturing step of manufacturing a steel girder 300;
A through hole forming step of forming the upper through hole 311 and the lower through hole 331 through the steel girder 300 so that the standing plate 230 passes through;
The girder support so that the upper surface of the flange support part 220 is in contact with the lower surface of the lower flange 330 of the steel girder 300, so that the lower surface of the girder support part 340 contacts the upper surface of the support plate 210 Girder support unit coupling step of coupling the unit 340;
A steel bar hole for forming a steel bar hole in the standing plate 230 and the abdomen 320 so that the steel bar 500 passes through the abdomen 320 of the standing plate 230 and the steel girder 300 in common As a steel composite ramen bridge using a steel girder-bearing assembly structure assembled in a configuration comprising a forming step,
A plurality of piles 10 spaced apart from each other in the front and rear directions and installed in a lateral direction;
A concrete block 100 coupled in common to an upper portion of the plurality of piles 10 installed in the lateral direction;
The support member 200 installed on the upper surface of the block 100;
The steel girder 300 fitted to the pair of support members 200 spaced apart from each other based on the front-rear direction;
A connection slab 20 coupled to the front and rear outer sides of the steel girder 300;
Including; a floor plate 30 on which concrete (C) is poured and installed on the upper part of the steel girder 300 and the connection slab 20,
The connection slab 20 and the steel girder 300 are coupled to each other by a connection slab coupling member 700,
The connection slab coupling member 700 is
It is fitted to the steel bar 500 so that the inner region is located in the region between the abdomen 320 and the standing plate 230,
A steel-composite ramen bridge, characterized in that the outer region is buried in the connecting slab 20 in a structure through which the connecting slab reinforcement 20-S buried in the connecting slab 20 penetrates.
delete delete delete delete delete delete delete delete As the method of constructing a steel composite ramen bridge according to claim 1,
A foundation part installation step of installing the support member 200 on the pile 10, the concrete block 100, and the concrete block 100;
A steel girder installation step of fitting and coupling the steel girder 300 to the standing plate 230 of the support member 200;
A coupling part installation step of installing the steel rod 500 and the connection slab coupling member 700;
A slab reinforcement coupling step of fitting and coupling the connection slab reinforcement (20-S) to the connection slab coupling member 700;
A connecting slab forming step of pouring concrete to form the connecting slab 20;
A method of constructing a steel-composite ramen bridge comprising: a floor plate installation step of pouring the concrete (C) for installation of the floor plate 30.
The method of claim 10,
The concrete (C) poured for installation of the floor plate 30 is poured so that the front and rear edge regions of the steel girder 300, the connection slab coupling member 700, and the inner region of the connection slab 20 are buried. Steel composite ramen bridge construction method characterized in that the.

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