KR100989153B1 - Psc girder connection structure with strength connector detail for substitution of rebar placement in deck and bridge construction method using the same - Google Patents

Abstract

PURPOSE: A cross-shaped PSC girder connecting structure with a horizontal reinforcement connecting material and a bridge construction method using the same are provided to be economically feasible by maximizing the strain efficiency of the PS tendon of a PSC girder. CONSTITUTION: A cross-shaped PSC girder connecting structure comprises a PSC girder(100) and a horizontal reinforcement connecting material(300). An upper flange(130) of the PSC girder is horizontally extended and is adjacent to the side of an extended upper flange of the PSC girder. A board-shape synthesis steel material(200) upwardly projected from the inside is embedded on both upper sides of the expanded upper flanges. A horizontal connection hole(210) is formed in the projected synthesis steel material.

Description

PSC GIRDER CONNECTION STRUCTURE WITH STRENGTH CONNECTOR DETAIL FOR SUBSTITUTION OF REBAR PLACEMENT IN DECK AND BRIDOD CONSTRUCTION METHOD USING THE SAME}

The present invention relates to a bridge construction method using a cross-type PS girder connection structure and a cross-type PS girder with a transverse rigid connector for easy replacement of the base plate reinforcing bar. More specifically, it is possible to construct the girder bridge between the long sections by enhancing the cross-section efficiency of the PS girder, but the upper flange is widened in the upper and lateral directions so that the PS girder bridge can be constructed without separately installing the deck slab formwork. In order to solve the problem of fixing the bottom plate reinforcement and deterioration of adhesion performance, the CS girder bridge and its construction method have been improved by arranging the connection member that can act as the bottom plate reinforcing bar. .

Prestressed concrete (PSC) is used to pre-press compressive stress in order to offset the tensile stress that occurs in concrete.In this case, prestress is introduced to the PS steel (PC steel wire, PC steel rod, etc.) Is introduced by fixing in concrete.

The emergence of this PSC structure created an opportunity to overcome the shortcomings of RC concrete, which is vulnerable to tension. Currently, the use of PS steels is active and various construction methods are being developed, and the construction of the PSC structure is widely performed.

In particular, in the field of bridge construction in Korea, as shown in FIG. 1A, the girder bridge having the CS girder 10 is being constructed more than other types of bridges. It is expected to increase.

In the conventional bridge system using the PS girder, the PS girder is manufactured at a factory or a place near the bridge construction site, transported to the site, mounted between the bridges, or between the bridges and the shifts, and then concrete-floored by the site pouring method. Plates and crossbeams were constructed.

   However, when the bridge deck is constructed with cast-in-place concrete, there is a problem in that construction costs are required because work by manpower, such as installation of a copper bar and formwork, is required.

In order to solve this problem, in recent years in the bridge construction method using the PS girder, instead of the cast-in-place concrete bridge deck, the bridge deck is manufactured in advance in the factory or the site, and then transferred to the site A method of constructing bridge decks in combination with PS girder has been proposed.

However, this method also requires additional construction costs due to the connection process between the girder and the bridge deck and the separate horizontal beam placement, and the composite behavior of the PS girder and the bottom plate connection according to the curing period of the concrete is limited. .

In addition, in the case of PS girder, various efforts have been introduced to increase the stiffness of the cross section.

For example, as shown in FIG. 1B, a segmented SPC girder 10 (SPLICED PRESTRESSED GIRDER) is introduced. An example of increasing rigidity of the compressive force on the upper flange by allowing the steel material 30 to be embedded in the upper flange is also introduced.

However, the steel that is embedded in the PS girder may be effective in enhancing the extension length of the PS girder, that is, the longitudinal stiffness, but the efficiency is not so effective in the lateral stiffness of the PS girder. There was a problem that can not fall.

In addition, the cross-sectional shape of the PS girder in the form of a bulb-T (Bulb-T) as shown in Figure 1c to extend the width of the upper flange, such as to expand the upper flange to replace the bottom plate function An example is also introduced.

In addition, an example of forming a cross-sectional height of the PS girder to determine the cross-sectional stiffness of the PS girder is formed by forming a central block of the upper flange of the PS girder. However, when protruding upward or extending the horizontal width of the upper flange, it is restricted from connecting the existing girder section and the main reinforcing bar of concrete, which is additionally placed. there was.

In addition, also in changing the cross-sectional shape of the PS girder, they all have the problem that there is no limit to the transverse connection stiffness, but to increase the longitudinal rigidity.

Accordingly, the present invention has been made to solve the above problems, it is possible to ensure the longitudinal connection rigidity of the PS girder while efficiently securing the longitudinal bending stiffness more economical and structurally efficient PS girder And the construction method thereof,

Maximize the tension efficiency of PS strainer of PS girder to increase the economic efficiency and prevent the overstrain of PS girder to ensure stability even when the bottom plate is replaced.

In addition, by lowering the height of the girder to make efficient use of the entire termination plan, it provides structural stability and economical efficiency.The secondary steel wire can be installed after the bottom plate is installed by installing the anchorage of the secondary steel wire on the side of the PS girder. It is an object of the present invention to provide a PSC girder structure having a top protruding wide flange that can provide sufficient space to improve workability.

In addition, after forming the composite girders, the composite girders may be mounted on the bridges or bridges, and the bridge decks of the composite girders and the bridge decks of the adjacent composite girders may be sufficiently rigid by using the composite steel and the lateral rigid connecting materials. The transverse rigid connector can act as the main reinforcing bar of the floor plate, thereby improving the details of the lateral connection of the floor plate, greatly shortening the construction period by simplifying the process,

The purpose of the present invention is to provide a PS composite girder which enables the long span of the PS girder bridge and makes it possible to make the lower part of the girder into a compressive stress state of an appropriate size, thereby greatly reducing the possibility of cracking.

The present invention

First, in the form of girder cross-section, the upper flange is expanded in the lateral direction to exclude the formwork for the construction of the bottom plate (slab), but to enhance the lateral stiffness and effectively secure longitudinal bending stiffness. To form a composite steel in the form of a steel plate with a lower portion embedded on both sides of the upper flange, the synthetic steel to form a transverse through hole

Synthetic steels of adjacent PSC girders are connected to each other through a lateral rigid connecting material so that the PSG girders with the widened upper flanges are integrated with each other laterally.

Accordingly, the lateral rigid connecting member is made of a structural member in the form of bar (bar, steel bar, etc.) in which a thread having a certain diameter is processed without using a simple connecting reinforcing rod and anchoring performance according to the reinforcement of the cast iron of the bottom plate. This deterioration of the workability was improved, and the lateral stiffness in the bottom plate was also improved.

Second, the cross-sectional shape of the PS girder is to expand the upper flange in the transverse direction, but the upper projection block is formed in the center of the upper surface of the PS girder over the entire extension length so that the upper surface of the upper flange of the PS girder The cross-sectional height of the PS girder by the protruding block is made larger than the cross-sectional height of the upper surface of the upper flange widened, and the upper side of the upper protruding block protrudes upwards from the inside so that the shear reinforcing bar is embedded in the bottom plate. By doing so, the top protrusion block of the PS girder functions as part of the bottom plate.

Third, the composite steel can also serve as an internal reinforcing bar disposed in the longitudinal direction in the bottom plate, and the bottom plate reinforcement for the reinforcement of the bottom plate is formed by forming a seating groove for the bottom plate reinforcement separately on the upper surface of the synthetic steel To facilitate.

Fourth, the PS C girder is different from the time before and after the manufacturing step, the mounting step and the bottom plate concrete 410 in order to install the PS tension material to be settled after the tension to install the prestress by the PS tension material efficiency This was to be promoted.

PS girder according to the present invention is configured to expand the upper flange in the upper and lateral direction to effectively increase the cross-sectional stiffness, and to install a composite steel and transverse rigid connector that can contribute to both longitudinal and transverse connection stiffness As a result, the structure is very advantageous installation structure, it is possible to construct the Ps. Girder bridge between the Jangji.

In addition, the upper projection block of the PS girder and the composite steel as the main member of the girder has the effect of reducing the mold height of the girder by increasing the cross-sectional coefficient of the PS girder.

In addition, the upper flange of the PS girder can function as a part of the bottom plate to form a thinner thickness of the bottom plate for the cast in place, reducing the secondary fixed load than the conventional thickness of the bottom plate of the PS girder Will be

The upper flange widened in the upper and lateral directions and the lateral rigid connecting members extending in the longitudinal direction can be used to improve the construction details of the base plate reinforcing bar and improve the workability. Compared to the PS girder stiffness can be used more than the primary prestress introduction force can be applied.

In addition, the introduction of prestressing for each construction stage enables the design to resist the bottom plate stiffness in the composite section.

Therefore, with the manufacturing cost of the existing PS girder, it is possible to secure the mold height and the ground length equivalent to that of the synthetic preflex-based method, and it is excellent in workability and economical efficiency because no additional formwork is required when placing the floorboard.

The installation of the transverse rigid connector ensures the transverse rigidity and plays the role of the base plate reinforcing bar, thus facilitating the lateral distribution of the load.

      In addition, the application of the expanded upper flange according to the present invention eliminates the need for a separate formwork and bundling for the construction of on-site concrete decks, and reduces the reinforcing assembly work on site, compared to the continuous construction method of the conventional PS Girder bridge. Can greatly reduce the labor costs of the field.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

Figure 1a is a perspective view of a conventional PS girder,
1B is a cross-sectional view of a conventional SPC girder,
1C is a cross-sectional view of a conventional bulb-tee PS girder,
Figure 2a is a connection diagram of the cross-type PS girder with a transverse rigid connector to facilitate the replacement of the bottom plate cast steel of the present invention
Figure 2b is a cross-sectional view of the bridge using the cross-type PS girder with a transverse rigid connector to facilitate the replacement of the bottom plate cast steel reinforcing bar of the present invention
Figures 3a, 3b, 3c and 3d is a bridge construction flow chart using a cross-type PS girder with a transverse rigid connector to facilitate the replacement of the bottom plate cast steel of the present invention,
Figure 4 is a PS tensioning construction of the cross-type PS girder with a transverse rigid connector to facilitate the replacement of the bottom plate cast steel of the present invention of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. 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 the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

<PS girder 100 according to the present invention>

FIG. 2A is a cross-sectional view of the PS girder 100 in which the bottom plate 400 is synthesized.

Referring to FIG. 2, the PS girder 100 is composed of a lower flange 110, an abdomen 120, an upper flange 130 widened in the lateral direction, and an upper protrusion block 140. It can be seen that it is formed into a cross-section).

At this time, the upper flange 130 is to be widened in the transverse direction (orthogonal direction) so that the upper flange 130 to function as a formwork for placing the bottom plate concrete 410 in connection with the construction, In addition, it can be seen that the cross-sectional coefficient of the resistance cross section of the PS girder according to the width of the upper flange is increased to increase the cross-sectional rigidity against the load.

Since the widened upper flange 130 is constantly arranged in the longitudinal direction (the longitudinal direction of the PS girder longitudinally), it contributes to the enhancement of the longitudinal bending stiffness of the PS girder, longitudinal cross-sectional stiffness (bending stiffness) If the structure can be more structurally enhanced, there is an advantage in that the prestress introduction efficiency by the PS tension member can be improved more effectively.

Thus, in the present invention, the composite steel 200 is installed on both upper surfaces of the widened upper flange 130.

Such synthetic steel 200 can be produced using a sheet steel sheet.

First, the synthetic steel 200 is formed so that the lower portion is buried in the upper surface of the widened upper flange to protrude upward, the horizontal connection hole 210 spaced apart from each other in the longitudinal direction in the synthetic steel 200 protruded upwards Will be formed.

This may be referred to as fastening of the lateral rigid connection member 300 as described below.

The synthetic steel 200 is not formed over the entire extension length of the expanded upper flange 130 of the PS girder, the extension so that the bending moment due to the load acting on the PS girder is limited to the largest generation range The length L1 is adjusted.

As a result, it can be seen that it is possible to install a more economical and efficient composite steel 200, more specifically, the composite steel 200 between the spaced apart from the end surface of the PS girder toward the center of the PS girder To be installed.

The composite steel 200 may be installed on the upper surface of both sides of the upper flange, but when the PS girder is installed on the outermost side in the transverse direction may be installed on the upper surface of the inner upper flange.

In addition, a seating groove 220 is further formed on the upper surface of the synthetic steel 200 so that later reinforcement of the bottom plate transverse rebar can be seated in the seating groove of the synthetic steel 200 so that reinforcement of the transverse reinforcement of the bottom plate is easy. You can do that.

In addition, the cross-sectional height of the upper flange 130 is further formed in the center of the upper surface of the PS girder in order to ensure a sufficient cross-sectional height to increase the longitudinal bending rigidity of the PS girder, the upper protrusion block 140 is formed over the entire extension length The upper flange upper surface of the PS girder so that the cross-sectional height of the PS girder by the upper protrusion block 140 is larger than the cross-sectional height of the upper surface of the upper flange widened, the upper surface of the upper protrusion block 140 Shear reinforcement 150 to protrude upward from the inside to be embedded in the bottom plate is formed to protrude.

Accordingly, the upper protrusion block 140 may sufficiently secure an effective cross-sectional height to enhance bending stiffness, and the upper protrusion block 140 may be buried as a part of the bottom plate when placing the bottom plate concrete 410 later. The bending rigidity of the PS girder can be secured sufficiently without increasing the mold height.

In addition, the shear reinforcement 150 is formed to extend above the inner rotor of the PS girder, thereby contributing to the integration of the bottom plate and the PS girder.

Further, the widened upper flange side lower portion is to be formed so that the key block 160 protrudes in the transverse direction, which is in the state that the bottom plate concrete 410, finishing plate 500 to be described later on the upper surface of the key block is supported. The bottom plate 400 is formed by pouring the bottom plate concrete 410 on the upper surface of the PS girder. Furthermore, the formation position of the key block 160 may be located under the widened upper flange side or on the widened upper flange side according to the site conditions.

Basically, the PS girder is further provided with a parabolic PS tension member 170 therein. The PS tension member 170 is installed to be tension-fixed on both end surfaces of the lower flange of the PS girder. The strain is settled after tensioning to increase the efficiency of the PS tension material.

It is installed between the composite steel 200 is to make the PS girder 100 is integrated with each other in the transverse direction is a lateral rigid connection member (300).

Conventional PS girder that has a widened upper flange to facilitate the construction of the bottom plate to connect the internal reinforcement to the outside by projecting the internal reinforcing bar set inside the upper flange to connect to each other, By using connecting reinforcing bar, it simply has the function of connecting the widened upper flanges to each other. In addition, the connection reinforcing bar is not secured to secure the fixing and the attachment length of the reinforcement of the PS girder and the bottom plate causes a problem.

However, in order to improve the lateral rigidity in the bottom plate, but the basic function as such connecting reinforcing bar, the present invention will use a lateral rigid connecting member 300 in the form of a thread (bar).

That is, in order to enhance the lateral rigidity of the bottom plate is to enable the lateral rigid connection member 300.

Accordingly, the lateral rigid connecting member 300 uses a screw fastening portion 310 formed at both ends thereof, but is inserted into the lateral connecting hole 210 of the synthetic steel 200 to be connected to the lateral connecting hole of another adjacent synthetic steel. After extending to 210, the lateral rigid connection member 300 is fastened to the synthetic steel 200 using the fastening nut 320 to the screw fastening portion 310.

As a result, the lateral rigid connection member 300 is fixed to the composite steel 200 to be embedded in the bottom plate (slab) when placing the bottom plate concrete 410 to enhance the lateral rigidity of the bottom plate (slab), As it can replace the role of the cast iron that resists the moment of moment acting on the bottom plate, the PS girder can be structurally integrated with each other in the transverse direction, which plays a very important role in the transverse connection stiffness.

Thus, the synthetic steel 200 may not only contribute to the enhancement of the longitudinal bending stiffness, but also may contribute to the lateral rigidity of the bottom plate and the lateral connecting rigidity of the PS girder together with the lateral rigid connecting member 300.

<Bridge construction method using PS girder 100 according to the present invention>

In the installation of the PS girder 100 according to the present invention, a conventional bridge construction model will be described briefly, and the features of the installation of the PS girder 100 according to the present invention will be described in detail. Let's take a look at the bridge construction.

First, as shown in FIG. 3a, the bridge substructure 600 is first constructed by spaced apart from each other with the shifts installed with the PS girder 100 of the present invention. Of course, in the case of multi-span bridges, bridges will be installed between the shifts.

The bridge girder 100 according to the present invention is mounted on the bridge lower structure 600.

The PS girder 100 is provided with a widened upper flange 130, a top protrusion block 140, a shear reinforcing bar 150, PS tension member 170 and is formed in a cross-shaped cross section as a whole, widened upper flange 130 The synthetic steel 200 is installed on both sides of the upper surface, and the key block 160 is formed at the lower side of the widened upper flange 130.

Accordingly, some of the PS tension members 170 may be pre-tensioned and settled in the manufacturing stage in order to be able to resist the fixed load of the own weight of the PS girder.

Next, as shown in FIG. 3b, the bottom plate concrete 410 finish plate 500 is installed on the top surface of the key block 160.

This is to prevent the bottom plate concrete 410 from leaking between the two sides of the widened upper flange spaced apart, whereby the thickness (h) of the bottom plate 400 and the bottom plate concrete 410 placed between the two sides. The height to the top of the bottom plate is measured.

Next, the lateral rigid connecting member 300, that is, a bar having threaded portions 310 formed at both ends thereof, is inserted into the lateral connecting hole 210 of the synthetic steel 200, and both ends thereof are fastened to the adjacent synthetic steel 200. It is fastened and fixed by the nut 320.

As a result, the lateral rigid connecting member 300 can replace the role of the main reinforcing bar to resist the static moment acting on the bottom plate, the PS girder can be integrated with each other in the lateral direction to ensure sufficient lateral connection rigidity It becomes possible.

In addition, the PS girder integrated with each other by the lateral rigid connector 300 does not need to install a large number of cross beams, so the cross beams are installed only at both ends or branch portions of the PS girder, thereby simplifying the work by the cross beam installation. You can do it.

Next, as shown in FIG. 3c, the bottom plate reinforcement is reinforced in the transverse direction, which allows the bottom plate reinforcement 420 to be seated in the seating groove 220 formed on the upper surface of the composite steel 200 so as to be reinforced in the transverse direction. Will be

In consideration of the convenience of work, it is preferable to allow the reinforcing bar assembly to be integrally installed in the seating groove.

Next, the bottom plate 400 is formed by forming the bottom plate concrete 410 by forming the upper flange widened as shown in FIG. 3D.

The bottom plate concrete 410 has a shear reinforcement 150, a synthetic steel 200, a transverse rigid connector 300 and a bottom plate reinforcement 420 protruding upward from the upper protrusion block 140 of the widened upper flange You can see that this is buried

As a result, it can be seen that the PS girder 100 and the bottom plate 400 are integrated with each other.

In addition, the composite steel 200 is also embedded in the bottom plate concrete 410 to enhance the longitudinal rigidity of the bottom plate, the horizontal rigid connection member 300 is also embedded in the bottom plate concrete 410 to form the bottom plate It can be seen that it is possible to replace the role of the cast steel to resist the cement part and to improve the lateral stiffness of the bottom plate.

Of course, after the bottom plate 400 is formed it will be possible to further form the median, railings and pavement layers required for the bridge.

Furthermore. PS tension member 170 of the PS girder 170 as shown in Figure 4 to strain and settle (171, 172, 173) after the formation of the PS girder 100, the bottom plate concrete 410, median, railings and pavement layer further formed After the tension, the remaining PS tension members 174 and 175 may be tensioned and fixed, such as by tensioning and fixing the PS tension members at each construction stage, thereby increasing the efficiency of prestress introduction.

That is, the PS strainer is tensioned and fixed in the state where the PS girder and the bottom plate are synthesized, so that the prestress is introduced by the PS tension member in an advantageous state to secure the bending stiffness by the composite section. Work is possible.

100: Cruciform PS girder with transverse rigid coupling material of the present invention
110: lower flange
120: Abdomen
130: expanded upper flange
140: top protrusion block
150: shear rebar
160: key block
170: PS tension material
200: synthetic steel
210: horizontal connection hole
220: settling groove
300: lateral rigid connector
400: bottom plate
410: bottom plate concrete
420: bottom plate rebar
500: Deadline

Claims (10)

The upper flanges of the PS girder comprising the upper flange, the abdomen and the lower flange are connected to each other in the transverse direction to the PS seam girder transverse connection structure that can eliminate the formwork for placing the bottom plate concrete 410 In
The upper flange of the PS girder is laterally extended so as to be adjacent to each other with the side of the extended upper flange of the adjacent PS girder, and the upper surface of the sides of the extended upper flanges as a plate-like steel protruding upward from the inside The CS girder is embedded so that the maximum bending moment occurring in the seed girder is extended in a predetermined section and the protruding synthetic steel is formed with a plurality of transverse connection holes in the longitudinal direction; And
A transverse rigid connection member inserted into the transverse connecting hole and installed to be fastened to the composite steel so that adjacent PSC girders are structurally integrated with each other;
Cross-shaped PS girder connection structure provided with a transverse rigid connector for easy replacement of the base plate cast iron, characterized in that it comprises a. According to claim 1, wherein the upper projection block is formed in the center of the upper surface of the PS girder over the entire extension length so that the upper flange upper surface of the PS girder is the upper cross-sectional height of the PS girder by the upper projection block widened The upper surface of the flange is larger than the cross-sectional height, and the upper surface of the upper protrusion block is formed so that the shear reinforcing bar protruding upward from the inside to be embedded in the bottom plate protrudes transversely to facilitate replacement Cross type PS girder connection structure with rigid connector. The bottom plate concrete 410 of the bottom of the expanded upper flange side of the PS girder is further formed so that the protruding key block to support the finishing plate, the bottom plate concrete 410 on the upper surface of the key block ) Cross plate PS girder connection provided with transverse rigid connector for easy replacement of the base plate reinforcing bar, characterized in that the bottom plate is formed by placing the bottom plate concrete 410 on the upper surface of the PS girder while supporting the finishing plate. rescue. The method of claim 2, wherein the synthetic steel is installed in a predetermined section where the maximum bending moment occurs in the PS girder to adjust the extension length so as not to be formed at both ends of the PS girder, the upper surface of the composite steel There is a cross-type PS girder connection structure provided with a transverse rigid connector for easy replacement of the base plate reinforcing bar, characterized in that the bottom plate reinforcing bar is further formed to be seated grooves to be seated in the transverse direction. [5] The concrete of claim 4, wherein the bottom plate concrete 410 is poured in a state in which the bottom plate reinforcing bar is further placed in the transverse direction, and the CS girder is manufactured, mounted, and bottom plate concrete. (410) Cross-type PS girder connection structure provided with a transverse rigid connector for easy replacement of the base plate reinforcing bars, characterized in that the PS tension material is installed to be settled after tension by varying the time sequentially in the step before and after pouring. . In the PS girder construction method that can eliminate the formwork for placing the bottom plate concrete (410) by connecting the upper flange of the PS girder comprising the upper flange, the abdomen and the lower flange transversely to each other,
The upper flange extends in the lateral direction, and is installed on both upper surfaces of the extended upper flanges so as to protrude upward from the inside and extend in a predetermined section in which a maximum bending moment occurs. A PS C girder having a plurality of synthetic steels formed in a direction thereof is installed in the lower bridge structure such that the PS C girder is adjacent to each other with a side of an extended upper flange of an adjacent PS C girder;
Inserted into the transverse connecting holes of the synthetic steel to allow both ends to be fastened to the synthetic steel so that the PSG girders are integral with each other in the transverse direction;
Bridge construction method using a cross-shaped PS girder, comprising the step of forming a bottom plate concrete 410 on top of the PS girder. According to claim 6, The PS girder is to form a top projection block in the center of the upper surface of the upper flange over the entire extension length so that the upper flange top surface of the PS girder has a cross-sectional height of the PS girder by the upper protrusion block Cross-sectional height of the upper surface of the upper flange wider, but the upper surface of the top projection block is cross-shaped PS, characterized in that to be used to protrude upward from the inside is formed so that the shear reinforcement to be embedded in the bottom plate Bridge construction method using girder. According to claim 7, Before the bottom plate concrete 410 is placed on the top surface of the synthetic steel using a bottom plate in which the bottom groove is further formed so that the bottom plate reinforcement can be seated in the transverse direction Bridge construction method using the cross-type PS girder, characterized in that the reinforcing bars are arranged in the transverse direction, the shear reinforcing bar and the bottom plate reinforcement. The bottom plate concrete 410 of claim 8, wherein the bottom plate concrete 410 is formed to protrude so that the bottom plate concrete 410 finishing plate is supported under the extended upper flange side end surface of the PS girder. 410) Bridge construction method using a cross-type PS girder, characterized in that the bottom plate is formed by pouring the bottom plate concrete (410) on the upper surface of the PS girder in a state that the finishing plate is supported. 10. The method according to any one of claims 6 to 9, wherein the PS tension member installed in the PS girder is different in sequential order during the PS girder manufacturing step, the mounting step, and the step of placing the bottom plate concrete 410 before and after. Bridge construction method using the cross-type PS girder, characterized in that to be settled after the tension.

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