KR101797969B1 - Slab girder bridge with arch deck and the construction method therefor - Google Patents

Abstract

The present invention relates to a slab girder bridge constructed by an arch deck structurally integrating an arch deck with a slab girder by connecting the slab flange of the slab girder and the inner transverse reinforcement of the arch deck at the site and a construction method thereof. The arch deck is a structural member having an arching effect that is restrained in a hinged state at a step support portion of a slab girder, and is installed in a half deck form instead of a formwork, so that it is not displaced when the slab concrete is laid, So that it can be used.

Description

TECHNICAL FIELD [0001] The present invention relates to a slab girder bridge made of an arch deck,

The present invention relates to a slab girder bridge made of an arch deck and a construction method thereof. More particularly, the present invention relates to a slab girder bridge made of an arch deck structured by connecting the slab flange of the slab girder and the inner transverse reinforcement of the arch deck in situ and structurally integrating the arch deck with the slab girder.

FIG. 1 is a cross-sectional view of an arch deck in which the applicant of the present invention has been registered.

That is, it is possible to effectively serialize the slab girders by using the arch deck, thereby maximizing the merit of the conventional slab girder, thereby providing a more stable and economical method of constructing the slab girder bridge and solving the provision of the bridge,

(a) mounting a slab girder including a slab flange with a step at an end of the slab girder to the bridge substructure laterally spaced from each other; (b) installing an end of the deck to the step of the slab flange of the spaced apart slab girder; (c) connecting the slab flange connecting bars extending from the slab flange side end face of the spaced apart slab girder to each other; And (d) placing and curing the slab concrete on the upper surface of the deck so that the slab flange connecting reinforcing bars connected to each other are embedded, so that the adjacent slab flanges are integrated and continued,

The deck is formed in such a shape that the central portion of the deck is curved upwardly at both ends and the arch deck having an arch shape is used to directly support both ends of the arch deck at the step, The axial force P is transmitted to the abdomen of the slab girder through the slap portion of the slab girder along the slab flange.

At this time, since the spacing space between adjacent slab flanges 13a by the arch deck 20 does not need to be provided with a hull for pouring the slab concrete 16, a slab flange connection construction can be performed more quickly and economically,

Since the slab flange connecting reinforcing bar 15a protrudes from the side end face A1 of the slab girder, they are connected to each other in the upper space of the arch deck 20 by using a connecting reinforcing bar and a coupler. The slab concrete 16 is installed on the upper surface of the arch deck 20,

When the slab concrete 16 is cured, the slab flanges 13a can be structurally integrated with each other. Since such a joint reinforcing bar 15b functions as a kind of slab reinforcement, the thickness of the arch deck 20 can be minimized will be.

However, since the arch deck 20 is used only as a form to be simply supported on the step 14a of the slab flange without lateral restraint, there is a limit in that it can not serve as a structural member at all.

That is, since both ends of the arch deck 20 are not constrained as in the present invention, an actual displacement occurs in the lateral direction and the performance against the arching effect can not be sufficiently exhibited, and the arch deck 20, the slab concrete, and the slab flanges It is possible to have an arching effect in the state of being integrated with each other (formation of a bottom plate), so that there is a limit to the connection structure through the bottom plate,

This is because the thickness of the arch deck used only for the formwork is too thin and the strength is so low that there is a problem that the corner portion is damaged during transportation and mounting, and when the slab concrete is poured, the position is detached There was a limit in usability.

Korean Patent No. 10-1509505 (Title of the Invention: Method of constructing a slab girder bridge and its bridge, published on April 08, 2015)

Therefore, the present invention is not limited to simply acting as an inner reinforcing bar in the use of an arch deck in a slab girder bridge. Instead, the lateral reinforcing bars of the arch deck are directly connected to a slab flange on which the arch deck is installed, Providing a slab girder bridge made of arch deck which can fundamentally solve the connection site stiffness problem in the construction of slab girder by making the arch deck work as an actual structural member by having the arching effect by restricting the displacement and providing the construction method To solve the problem.

In order to accomplish the above object, a slab girder bridge made of an arch deck according to the present invention comprises:

A slab girder in which a step support portion is formed at an end portion of the slab flange side and a slab flange connecting reinforcing bar is horizontally extended from both side end faces A1 of the step portion supporting portion; An arch deck installed so as to support both ends at a step support portion of a slab girder adjacent to each other and installed so that a transverse inner reinforcing steel is connected to the slab flange connecting reinforcing steel to prevent lateral displacement; And a slab concrete paved so that a transverse direction inner reinforcing bar, a slab flange connecting reinforcing bar and a slab upper reinforcing bar are embedded so as to be integrated with the upper surface of the slab flange above the arch deck.

According to an aspect of the present invention, there is provided a slab girder bridge construction method using an arch deck,

and a step formed by a side end face of the step (a) and a supporting step are formed on the side face of the slab flange, and a slab girder extending horizontally from the both side faces (A1) of the step support portion (140) ; (b) a body portion formed by an arch bottom plate having a curved central portion in an arch shape; A transverse inner reinforcing bar embedded in the arch bottom plate and having both ends protruded from the arch bottom plate; And a horizontal upper plate formed on an upper surface of the arch bottom plate and having a side inclined downwardly and formed with a longitudinal inner prismatic bar protruding therefrom; (c) connecting the transverse inner reinforcement bars to the slab flange connecting bars while mounting both ends of the arch deck to be supported on the step support portions of the slab flanges of adjacent slab girders; (d) causing the longitudinal internally-pronged reinforcing bars to extend upwardly from the top surface of the arch deck in communication with the longitudinal internally-pronged reinforcing bars of adjacent arch decks; (e) disposing a slab upper cast iron over the slab flange; And (f) casting the slab flange connecting reinforcing bars, the slab concrete so that the upper cast iron bars are embedded.

The transverse inner reinforcing bars of the arch deck according to the present invention are connected to the slab flange connecting reinforcing bars of the slab girder so that they are not transversely displaced due to hinge restraint so that they can have an arching effect even before the slab concrete is poured, As a substantial structural member, it is possible to effectively resist the bending moment, and the slab bottom cast iron can be rapidly slab-mounted as a kind of half deck according to the construction of the slab by only placing the upper main iron rope without laying.

Since both sides of the arch deck have a certain thickness and have a certain weight, they can not be displaced when the slab concrete is laid, so that workability and workability can be secured by preventing the falling. It is possible to reduce the occurrence factor of defects and to increase the sectional rigidity of the arch deck so that it is possible to easily apply even if the lateral spacing of the slab girder becomes large.

The arch deck of the present invention allows the longitudinal internally-pronged reinforcing bars to be connected to each other not only in the transverse direction but also in the longitudinal direction, and the longitudinal internally-pronged reinforcing bars are superimposed on each other on the upper surface of the arch deck, The composite performance with concrete can be sufficiently secured.

1 is a sectional view of a conventional half deck construction.
FIG. 2A is a view showing a construction of a slab girder bridge made of an arch deck of the present invention,
Figures 2b, 2c, 2d and 2e are perspective and connected perspective views of the slab girder and arch deck of the invention,
FIGS. 3A, 3B and 3C are flowcharts of a method of constructing a slab girder bridge made of an arch deck of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[The slab girder bridge made of the arch deck 200 of the present invention]

2A shows a construction diagram of a slab girder bridge made of an arch deck of the present invention.

First, as shown in FIGS. 2A and 3A, the slab girder bridge of the present invention is spaced laterally apart from the bridge girder 100 in a state in which the slab girder 100 is mounted on the bridge girder 300.

At this time, the slab girder 100 is divided into an intermediate slab girder and an outer slab girder, but is simply referred to as a slab girder 100 in FIG.

It can be seen that the slab flange 130 of the slab girder 100 spaced apart from each other is also laterally spaced from each other and that the arch deck 200 is positioned between the slab flanges 130 (140) of the housing

2A, the slab flanges 130 are connected such that the slab flange connecting bars 151 are connected to the transverse inner reinforcing bars 210 of the arch deck 200 at the step portion 140 and are transversely connected to each other .

That is, the transverse inner reinforcing bars 210 of the arch deck 200 are formed in a hinged connection state such that the displacement is constrained in the lateral direction at the step support portion 140 of the slab girder by using the coupler and the slab flange connection reinforcing bars 151 do.

Since the arch deck 200 is structurally integrated with the slab girder before the bottom plate is slab-concrete, the arch deck 200 has an arching effect. Therefore, the arch deck 200 functions as a structural member capable of effectively resisting the bending moment due to an operating load do.

In addition, since the hinge connection can prevent the slip, it is possible to prevent slipping and falling due to the slab concrete pouring.

In addition, it can be seen that the slab flange has a shear connection member 152 and is integrated with the slab concrete 160 to be integrated with each other, and the upper cast steel rope 310 is disposed above the upper flange to secure structural integrity.

At this time, the slab flange connecting reinforcing bars 151 and the transverse inner reinforcing bars 210 are formed so as to surround the adjacent ends by using the coupler 153 in a state where the end portions are adjacent to each other, And the like.

At this time, since the slab flange connecting reinforcing bars 151 and the transverse inner reinforcing bars 210 are connected to each other at the step 140, there is a problem that the central axes do not coincide with each other. Thus, the grip couplers, So that workability and structural integrity can be ensured.

The arch deck 200, to which the slab flange connecting reinforcing bars 151 and the transverse inner reinforcing bars 210 are connected, is designed to function as a practical structural member, . That is, as the structural member, the cross-sectional thickness of the arch deck 200 can be increased to sufficiently cope with the lateral spacing distance of the slab girder installed between the ground.

[The slab girder (100) of the present invention]

2B is a perspective view of the slab girders 100 of the present invention.

The slab girder according to the present invention may be referred to as an integral part, but it can be divided into an intermediate slab girder 100a and an outer slab girder 100b in detail, which is classified according to the installation position of the slab girder.

It can be seen that the intermediate slab girder 100a is formed as a slab girder having an I-shaped cross section as a whole and is formed of a lower flange 110a, a stern portion 120a and a slab flange 130a have. A slab girder 500a having a box-shaped cross section formed by the lower flange 110a, the abdomen portion 120a and the slab flange 130a can be applied as shown in FIG. 2E.

It can be seen that the step 140a is formed at both side ends of the slab flange 130a and that the both side surfaces A1 and the supporting upper surface A2 are formed naturally by the step 140a .

At this time, it can be seen that the slab flange connecting reinforcing bars 151 extend horizontally from both side end faces A1.

As a result, it can be seen that the slab girder according to the present invention is basically formed in a left-right symmetrical cross section, and the step support portion 140 is slightly laterally protruded on the basis of the widths W1 and W2 Able to know.

It can also be seen that a hooking portion 170a is formed at the connection portion of the two slab flanges 130a from the upper end of the abdomen portion 120a. At this time, the step 140a and the spiral portion 170a are integrally formed with the slab flange 130a.

Further, as shown in FIG. 2B, the two outer slab girders 100b are mounted on the outermost side of the slab girder bridge so that one end of the slab flange extends a little longer, and the step 140b is formed only at the other end. There is no difference from the slab girder 100a.

It can be seen that the outer slab girder 100b is formed into an I-shaped cross-section as a whole and is formed of the lower flange 110b, the abdomen portion 120b, and the slab flange 130b.

It can be seen that the step 140b is formed only at one end of the slab flange 130b for supporting the arch deck 200 and the side end surface A1 and the step portion 140 are formed by the step 140b, To be formed naturally.

At this time, it can also be seen that the slab flange connection reinforcing bars 151 and the slab flange upper connecting reinforcing bars 152 extend horizontally from the side end surface A1.

At this time, as described above, the other end of the slab flange in which the step 140b is not formed is extended longer than the width of the lower flange for the construction of the soundproof wall base, etc., and the further extended width W3 can be minimized. There is no significant difference in that the slab girder according to the present invention is basically formed into a left-right symmetrical cross-section.

It can also be seen that a hook portion 170b is formed at the connection portion of the two slab flanges 130b from the upper end of the abdomen portion 120b.

This outer slab girder 100b is installed at the outermost side of the bridge substructure 300 as shown in Fig.

[Connection between the slab girders 100a and 100b of the present invention and the arch deck 200]

FIGS. 2c, 2d and 2e are perspective views of the arch deck 200, which is a connection perspective view of the slab girders 100a, 100b and the arch deck 200 of the present invention.

First, a plurality of intermediate slab girders 100a are spaced apart from one another at regular intervals between the outer slab girders 100b.

Since the slab flanges of the slab girders are also spaced apart from each other, they are connected to each other to be continuous.

The arch deck 200, the slab flange connecting reinforcing bars 151 and the upper cast iron rods 310 are used for this purpose.

First, the arch deck 200 is a reinforced concrete deck having an arch shape in which the central portion is curved upward at both ends.

The arch deck 200 is manufactured in the form of a precast concrete panel. It can be seen that a shear connection member 230 (C-shaped, horseshoe-shaped, stud, etc.) is formed on the upper surface.

When a load is applied to the arch deck 200, a load is transmitted in the axial direction, so that the axial force P due to the load is transmitted to both ends.

This axial force P acts on the slab flange 130a of the slab girders 100a which are mounted on both sides with a kind of horizontal force.

In order to effectively support such an axial force, the present invention forms a step 140a at the end of the slab flange so that the end of the arch deck 200 is axially supported on the side edge A1 by the step.

As shown in FIG. 2C, the arch deck 200 is formed to include a transverse inner reinforcement 210, a longitudinal inner transverse reinforcement 220, a shear connection 230, and a trunk 240. .

Accordingly, it can be seen that the body 240 is formed as an arch bottom plate 241 having a curved central portion in an arch shape.

It is understood that the transverse inner reinforcing bars 210 are embedded in the arch bottom plate 241 so that both end portions are arranged to have a constant protruding length.

The transverse inner reinforcement 210 is connected to the slab flange connecting reinforcing bar 151 to have continuity.

The upper surface of the arch bottom plate 241 may be formed as a horizontal top plate 242 and the side surface of the horizontal top plate 242 may be downwardly inclined so that the longitudinal inner prongs 220 protrude .

It will be appreciated that the longitudinal interlocking barb 220 is bent in a semicircular shape so that it is looped with the longitudinal interlocking barb 220 of the adjacent arch deck 200, The upper surface of the arch deck 200 is exposed upward.

Further, a plurality of shear connectors 230 are spaced apart from each other on the upper surface of the horizontal top plate 242 so that the slab concrete 160 and the arch deck 200 are integrated with each other.

Basically, the spacing space between adjacent slab flanges 130a and 130b by the arch deck 200 does not need to be provided with a bucket or the like for installing the slab concrete 160, thereby enabling a quick and economical slab construction And,

At this time, the slab flange connection reinforcing bars 151 protrude from the side end faces A1 of the slab flanges 130a and 130b and are connected to the lateral reinforcing bars 210 of the arch deck 200.

Since the transverse inner reinforcement 210 is formed on the arch bottom plate 241 of the arch deck 200, it can be seen that the transverse inner reinforcement 210 is connected to the slab flange connecting reinforcing bar 151.

In addition, it can be seen that the shear connecting member 152 is installed on the upper part of the slab flange and the slab upper cast iron rope 310 is laid.

The slab flange connecting reinforcing bars 151 and the arch decks 200 according to the present invention are connected to each other by the transverse inner reinforcing bars 210 so that the structural members of the arch deck 200 and the slab girder 100, It is possible to maximize the rigidity.

The slab concrete 160 is laid on the upper surface of the arch deck 200 so that the transverse inner reinforcement 210, the longitudinal inner pruning shear reinforcement 220, the shear connection material 230 and the upper slab foundation casting 310 are embedded .

Thus, when the slab concrete 160 is cured, the slab girder, the arch deck, the slab girder and the slab concrete can be structurally integrated with each other, so that the slab and the slab girder are completely integrated.

Therefore, according to the present invention, the slab girders 100 are integrated with each other in the longitudinal direction and the transverse direction by the arch deck 200 and the slab concrete 160, and the upper surfaces of the slab girders 100 are finished to be equal to each other, Able to know.

Thus, it is possible to increase the structural performance and safety of the arch deck 200 by arranging the slab upper cast iron rope 310,

The arch deck 200 serves as a structural member rather than the thickness of the conventional arch plate, thereby preventing shaking or displacement when the slab concrete 160 is laid,

The arch deck 200 is connected to the slab girder by the slab flange connecting reinforcing bars 151, so that the dispersion and the transmission to the working load can be surely secured, thereby enabling an effective slab construction.

In addition, since the longitudinal interlocking barb 220 is synthesized on the slab concrete 160 on the upper surface of the arch deck 200, structural integrity in the longitudinal direction can be easily secured.

[Construction method of slab girders and arch deck 200 of the present invention]

FIGS. 3A, 3B and 3C show a construction sequence of a slab girder bridge according to the present invention.

That is, a method of forming the packing layer 400 after mounting the intermediate and outer slab girders 100a and 100b according to the present invention on the bridge substructure 300 will be described.

First, as shown in FIG. 3A, the bridge substructure 300 including the bridge and the pier is firstly constructed, and the middle and outer slab girders 100a and 100b are manufactured separately.

The intermediate and outer slab girders 100a and 100b, which are transported and transported on site, are horizontally mounted one by one in the bridge substructure 300 installed.

For example, the intermediate slab girders 100a may be horizontally spaced apart from each other at the central portion of the bridge substructure 300, and the outer slab girders 100b may be respectively mounted on both outermost sides of the intermediate slab girder 100a .

Next, as shown in FIG. 3B, the arch deck 200 is installed so as to be supported by the exposed steps 140a and 140b between the slab flanges of the middle and outer slab girders 100a and 100b spaced laterally.

Further, the transverse inner reinforcing bars 210 protruding horizontally from the installed arch deck 200 and the slab flange connecting reinforcing bars 151 are connected to each other to securely fix the arch deck 200.

In addition, the longitudinal inner hooking bars 220 protruding from the upper portion of the arch deck 200 are overlapped and bound to each other.

It can be seen that the arch decks 200 are integrated with the slab girder in the transverse direction and the arch decks 200 are bound to each other in the longitudinal direction.

It can be understood that the slab-shaped upper mainframe 310 is further disposed above the arch deck 200 and the slab flange, so that the slab concrete 160 and the slab girder 200 can be substantially integrated.

Next, the slab concrete 160 is laid on the upper surface of the arch deck 200 so that the slab girders 100 are successively integrated with each other in the lateral direction.

The upper surface of the slab girder 100 is finished at the same height as the upper surface of the arch deck 200 and the slab concrete is laid on the slab girder 100 and the upper portion of the arch deck 200, Able to know.

Next, as shown in FIG. 3C, the packing layer 400 is installed on the upper surface of the slab girder 100 to finish the upper surface of the bridge, and necessary barrier walls are also constructed to complete the bridge.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Slab girder 100a, 100b: Middle slab girder, Outer slab girder
110: lower flange 120: abdomen
130, 130a, 130b: slab flange 140, 140a, 140b:
A1: side surface of the stepped portion A2:
151: Slab flange connection reinforcement 152: Girder section shear connector
160: slab concrete 170a, 170b:
200: Arch Deck
300: Bridge infrastructure 400: Packing layer

Claims (10)

A slab girder 100 formed at an end of the step support 140 at the side of the slab flange 130 and the slab flange connection reinforcing bars 151 extending horizontally from both end faces A1 of the step 140;
The transverse inner reinforcement 210 is connected to the slab flange connecting reinforcing bars 151 so as to prevent lateral displacement from occurring, while both end portions of the transverse inner reinforcement 210 are installed on the step support portions 140 of the adjacent slab girder 100 An arch deck 200; And
And a slab concrete 160 to which the transverse inner reinforcement 210 and the slab flange connecting reinforcing bar 151 are connected and the upper slab reinforcement 310 is embedded so that the arch deck 200 and the slab flange are integrated, ,
The arch deck 200 may be structurally integrated with the slab girder 100 to have an arching effect prior to the placement of the slab concrete 160,
The slab flange connecting reinforcing bar 151 and the transverse inner reinforcing bar 210 are wrapped around each other by using a coupler 153 which is a compression sleeve in a state in which ends of the reinforcing bar 151 are adjacent to each other, The arch deck 200 is installed so that the transverse direction inner reinforcement 210 is connected to the slab flange connecting reinforcing bars 151 so that lateral displacement does not occur, Slab girder bridge. The method according to claim 1,
The slab girder (100)
The slab girder bridge is formed of a lower flange, an abdomen, and a slab flange, and has a tapered portion at a connecting portion of both slab flanges from the upper end of the abdomen. The slab girder is made of an arch deck having a step support portion 140 at both ends of the slab flange. The method according to claim 1,
The slab girder 100 may be formed of a box-shaped single-sided slab girder 500a
A slab girder bridge formed of an upper deck, a lower flange, an abdomen, and a slab flange, wherein the slab flange is provided with a step support portion 140 at both lateral ends thereof. The method according to claim 1,
The arch deck (200)
A body 240 formed by an arch bottom plate 241 having a curved central portion in an arch shape;
A transverse inner reinforcing bar 210 embedded in the arch bottom plate 241 and having both ends protruded from the arch bottom plate; And
And a horizontal top plate (242) formed on the upper surface of the arch bottom plate (241) and having a side inclined downwardly and formed with a longitudinal inner prongs (220) protruding therefrom. 5. The method of claim 4,
The arch deck 200 is manufactured in the form of a precast concrete panel so that a shear connection material 230 is formed on the upper surface of the arch deck 200 to be combined with the slab concrete 160
The load acting on the arch deck 200 is transmitted to the both ends of the axial force P and the axial force P is supported by the slab flanges on both sides of the slab girders, . 5. The method of claim 4,
The longitudinal inner reinforcing bars 210 are connected to the slab flange connecting reinforcing bars 151 and the longitudinal interdigitating reinforcing bars 220 are connected to the longitudinal inner connecting reinforcing bars 220 of the adjacent arch deck 200 The slab girder bridge is made of an arch deck which is exposed upward from the upper surface of the arch deck 200 to be buried in the slab concrete 160. (a) a step support portion 140 is formed at an end portion of the slab flange 130 side and slab flange connection reinforcing bars 151 extend horizontally from both side end faces A1 of the step portion supporting portion 140 ) To the bridge substructure (300);
(b) a body portion 240 formed of an arch bottom plate 241 having a curved central portion in an arch shape; A transverse inner reinforcing bar 210 embedded in the arch bottom plate 241 and having both ends protruded from the arch bottom plate; And a horizontal top plate (242) formed on the upper surface of the arch bottom plate (241), the side surface of the arch deck (200) being inclined downwardly and formed with the longitudinal internal prongs (220) protruding therefrom.
(c) the transverse inner reinforcement 210 is installed on the step support portion 140 of the slab flange 130 of the adjacent slab girder 100 so that both ends of the arch deck 200 are supported, To be connected to the reinforcing bar (151);
(d) causing the longitudinal internally-pronged reinforcing bar (220) to extend upwardly from the upper surface of the arch deck (200) to the longitudinal internally-pronged reinforcing bars (220) of the adjacent arch deck (200);
(e) connecting the slab upper cast iron rope (310) to the slab flange and laying it; And
(f) Placing the slab concrete (160) on the arch deck (200) so that the slab flange connecting reinforcing bars (151) and the upper slab reinforcing bars (310)
In the step (b), the adjacent ends of the slab flange connecting reinforcing bar 151 and the transverse inner reinforcing bar 210 are surrounded by the coupler 153, which is a compression sleeve, The transverse direction inner reinforcing bars 210 are connected to the slab flange connecting reinforcing bars 151 so as to prevent the transverse displacement from occurring, A method of constructing a slab girder bridge made of an arch deck to prevent conduction. delete 8. The method of claim 7,
The slab girder 100 of the step (a) is provided with an intermediate slab girder 100a between the outer slab girders 100b and the outer slab girder 100b, the middle slab girder 100a, the middle slab girder 100a, Wherein the arch deck (200) is installed such that both ends of the arch deck (200) are supported on the step between the intermediate slab girders (100a). 8. The method of claim 7,
Further comprising the step (g) of forming a packing layer (400) on the upper surface of the slab concrete (160) integrated with the slab girder (100) after the step (f).

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