KR100727675B1 - Concrete bridge deck and construction method thereof - Google Patents

Abstract

A concrete bridge deck is provided to increase the load carrying capacity of a bridge deck by enhancing arching effect using a horizontal fixing structure of a main girder and a slab by a flat bar, and to increase durability and to extend the service life of a bridge deck by preventing the crack formation against horizontal negative moment by placing FRP tendons on the bridge deck. The concrete bridge deck contains plural main girders(50) installed on a pier(40) in a line and provided with one or more pockets(52) where lower fixing members of a flat bar are placed inward to increase the fixing strength of a flat bar for the main girder, a flat bar(60) installed on the top of the main girder and provided with upper and lower fixing members such as connectors(62) or studs(64), a slab(70) located on the top of the flat bar and fixed to the upper part of the main girder by fixing members to increase arching effect against load of a bridge deck(100), thereby to increase load carrying capacity of the bridge deck, a tendon(80) manufactured with FRP(Fiberglass Reinforced Plastics) and placed to the inside of the slab parallel to the flat bar to supply tensile strength, and an anchorage(90) installed to the end of a sheath pipe(82a) of a triangular spacer(82) to fix two ends of the tendon.

Description

Concrete bridge deck and construction method

1 is a view showing a bridge built-in rebar according to the prior art.

Figure 2 is a perspective cross-sectional view of the concrete bridge deck according to a preferred embodiment of the present invention.

3 is an enlarged perspective view illustrating a portion 'A' of FIG. 2.

4 is a cross-sectional view showing the concrete bridge deck of FIG.

5 is a view showing the anchorage of the concrete bridge deck of Figure 4, (a) is a cross-sectional view (b) is a cross-sectional view taken along the line II 'of (a).

6A, 6B, 6C, 6D, and 6E are flowcharts illustrating the construction of the concrete bridge deck of FIG. 2.

<Explanation of symbols for the main parts of the drawings>

40: pier 50: mold

52: pocket 60: flat iron

62: perforbond connector 62a: locking groove

64: stud 70: slab

72: die 80: tendon

82: sheath tube triangular spacer 82a: sheath tube

90: Fixture 92: Case

94: wedge 96: cap

98: wax

100: concrete bridge deck

The present invention relates to a concrete bridge deck and its construction method, and more particularly, by improving the arching effect by the concrete mold and slab transverse structure of the flat iron to increase the load-bearing capacity of the bottom plate, arranging the FRP tendon The present invention relates to a concrete bridge deck and its construction method by suppressing cracking caused by a parent and thereby improving durability.

In general, domestic bridge decks are mainly made of reinforced concrete decks made by placing concrete and placing concrete after supporting the bars.

The construction method of the reinforced concrete deck plate is very long air and a lot of initial cracks in the transverse direction occurs. After the cracking occurs, moisture and cryoprotectant penetrate into the cracking portion over time, and this moisture and cryoprotectant may corrode the reinforcing steel in the bottom plate or accelerate the corrosion of the already existing steel.

As such, when the reinforcing bars in the bridge deck corrodes, as shown in FIG. 1, the cracks gradually enlarge and eventually cause punching shear fracture locally on the bottom plate. The bridge deck 10 with corroded rebars due to the wheel load of the vehicle passing through the bridge continues to undergo bending cracks, and the effective shear area of the slab continues to decrease as the bending cracks progress, eventually leading to shear by punching shear. Destruction will occur. Local damage of the bottom plate shortens the life span of the bridge, enormous maintenance costs due to the repair and reinforcement of the damaged bottom plate, and in the process of repairing the bottom plate, it also causes social overhead costs due to vehicle control. do.

The present invention has been devised to solve the above problems, by removing the source of the reinforcing bar inside the bottom plate that provides the cause of the damage of the bottom plate, arching by restraining the concrete mold and the bottom plate using flat iron on the outside of the bottom plate It enhances the load capacity of the bottom plate by enhancing the effect, and by placing the FRP tendon, it suppresses the cracking caused by the transverse parent moment, which is inevitable when three or more molds or a cantilever is present, thereby improving durability and strength. The purpose is to provide a bridge deck and its construction method.

Concrete bridge deck and a construction method according to a preferred embodiment of the present invention in order to achieve the above object, a plurality is installed side by side on the pier, a concrete mold formed at least one or more pockets on the upper surface along the longitudinal direction; A flat iron installed on the upper surface of the mold in a horizontal direction and having an upper fixing member and a lower fixing member disposed inside the pocket of the mold; And a slab configured to be fixed by the fixing members of the flat iron to be fixed to the upper portion of the mold.

At this time, the fixing member is a perforbond connector or stud.

Preferably, the perforbond connection member is formed with a locking groove or locking plate so that the slab is caught and restrained.

The present invention further includes tendons which are arranged inside the slab so as to be parallel to the flat iron and configured to provide a tension force.

In addition, further comprising a fixing device installed in the slab and the inner side to fix both ends of the tendon, the fixing device is disposed inside the slab so that one side is opened to the outside of the slab, so that the inner diameter is smaller toward the other side Formed cylindrical case; A wedge formed in close contact with an inner circumferential surface of the case and configured to move through the tendon, and pressurize the tendon as it moves toward the slab; And a cap configured to cover one side of the case, and a space between the wedge and the cap is filled with wax to maintain airtightness.

On the other hand, the tendon is preferably made of FRP (Fiber glass Reinforced Plastic) material, the slab concrete is preferably fiber reinforced concrete.

According to another aspect of the invention, preparing a plurality of concrete molds formed in at least one or more pockets along the longitudinal direction on the upper surface, and preparing a flat iron having a fixing member on the upper / lower surface (S10); Installing the plurality of molds side by side on a piers (S11); Installing a fixing member of the lower surface of the flat iron in a transverse direction with respect to the mold so as to be located inside the pocket part of the mold (S12); A step of installing a formwork for placing the slab formed on the upper part of the mold by a fixing force provided by the fixing members of the flat iron (S13); A method of constructing a concrete bridge deck is provided, comprising; and placing and curing concrete for the slab (S14).

At this time, the fixing member is a perforbond connector or stud.

Preferably, the perforbond connection member is formed with a locking groove or locking plate to be fixed to the slab.

The present invention may further include installing a tendon disposed inside the slab to be parallel to the flat iron and configured to provide a tension force.

At this time, the step of installing the tendon, after the step (S13), after installing the sheath tube support triangular spacer on the inner side of the formwork, the step of installing a sheath tube on top of the sheath tube support triangular spacer ; And after the step (S14), when the concrete of the slab reaches a certain strength, the step of tensioning by inserting the tendon in the sheath tube.

In addition, the present invention, in order to fix the end of the tension tendon, the step of installing the anchorage in the end of the sheath tube in the process of installing the sheath tube triangular spacer; further comprising, the anchorage, one side is the A cylindrical case disposed inside the slab so as to be opened to the outside of the slab and formed to have an inner diameter smaller toward the other side; A wedge formed in close contact with an inner circumferential surface of the case and configured to move the tendon, and configured to press and fix the tendon as it moves toward the slab; And a cap configured to cover one side of the case, and a space between the wedge and the cap is filled with wax to maintain airtightness.

More preferably, the present invention, in the step (S14), using a vibrator so that the concrete is densely packed inside the pocket portion of the mold;

On the other hand, the tendon is preferably made of FRP (Fiber glass Reinforced Plastic) material, the slab concrete is preferably fiber reinforced concrete.

Figure 4 is a cutaway cross-sectional perspective view of a concrete bridge deck according to a preferred embodiment of the present invention, Figure 5 is an enlarged perspective view showing a portion 'A' of Figure 4, Figure 6 is a cross-sectional view showing a concrete bridge deck of Figure 4 to be.

Referring to the drawings, the concrete bridge deck 100 of the present invention is a mold 50 installed on the pier 40, the flat iron 60 installed on the upper surface of the mold 50, and the upper surface of the flat iron 60 A slab 70 is positioned and configured to be secured to the top of the mold 50. Bridge bottom plate 100 is configured in this way refers to the structure on the alternating or pier bridges, the alternating or pier serves to safely transfer the load received from the upper side plate 100 to the ground.

The mold 50 is provided in a plurality of side by side on the pier 40, preferably side by side to be parallel to each other, it can form a multi-type structure consisting of two or more molds consisting of two molds.

In addition, the mold 50 has at least one pocket 52 on the upper surface thereof is formed along the longitudinal direction. The pocket portion 52 has a groove-shaped structure that is deeply penetrated inwardly from the upper surface of the mold 50, and the pocket portion 52 having this structure is preferably along the longitudinal direction on the upper surface of the mold 50. It is formed to be spaced apart from each other by a predetermined interval.

The pocket portion 52 configured as described above has a function of improving the fixing force on the mold 50 of the flat iron 60 by disposing the lower fixing member of the flat iron 60 to be described later.

The flat iron 60 has a fixing member on the upper and lower portions, and the lower fixing member is disposed inside the pocket part 52 of the mold 50 and is installed in the transverse direction with respect to the mold 50. This fixing member is preferably a perforbond connecting material 62 or stud 64. That is, when the flat iron 60 is provided with a perforbond connecting member 62 on the upper surface and the stud 64 is installed on the lower surface, the stud 64 is disposed inside the pocket portion 52 of the mold 50. Although not shown in the drawings, when the stud is installed on the upper surface and the perforbond connecting material is installed on the lower surface, the perforbond connecting material is configured to be disposed inside the pocket portion 52 of the mold 50. .

Of course, the fixing member of the present invention is not limited thereto, and both the upper and lower surfaces of the flat iron 60 may be provided with the perforbond connecting member 62 or both the studs 64 may be installed. In addition, as a fixing member installed on the upper and lower surfaces of the flat iron 60, a connection member other than the perforbond connector 62 or the stud 64 may be used. On the other hand, the connecting material such as perforbond connector 62 or stud 64 is welded or installed on the flat iron 60 using a coupling member such as a screw.

Preferably, the perforated connection member 62 is formed with a locking groove 62a or a locking plate 62b so that the slab 70 is caught and fixed. The locking groove 62a or the locking plate 62b is filled with concrete in the process of placing concrete to make the slab 70. As such, when the concrete is filled in the locking groove 62a or the locking plate 62b to reach a certain strength, the locking groove 62a or the locking plate 62b provides a fixing force so that the slab 70 does not move. On the other hand, as shown in the drawing of the present invention, the perforbond connecting member 62 may be provided with a locking groove 62a and a locking plate 62b.

In the present invention, the flat iron 60 serves to support the load in the concrete bridge having the slab 70 of the arch structure made to overcome the load acting on the bottom plate 100 without embedding the reinforcing bar. In particular, by supporting the load of the positive moment acting portion of the bridge center to improve the bearing force due to the arch structure of the slab (70). In addition, the flat iron 60 simplifies the process of making the bridge shortens the construction period and at the same time extends the life of the bridge.

The slab 70 is configured to be provided with a fixing force by the fixing members of the flat iron 60 is fixed to the upper portion of the mold 50. That is, the flat iron 60 is firmly fixed to the mold 50 by the fixing member provided on the lower surface, and the slab 70 is formed by the mold 50 by providing the fixing force to the slab 70 by the fixing member provided on the upper surface. It is firmly fixed to the top of the. Thus, the slab 70 is firmly fixed to the transverse direction of the mold 50, thereby improving the arching effect on the load of the bottom plate 100 to increase the load capacity of the bottom plate 100. .

On the other hand, the concrete bridge deck 100 of the present invention further includes a tendon 80 is arranged to provide a tension force to the inner side of the slab 70 to be parallel to the flat iron 60. Tendon 80 is disposed in the transverse direction of the mold 50 so as to be parallel to the flat iron 60, for supporting the sheath tube to install such a tendon 80 to be arranged at a predetermined distance from the lower surface of the slab 70. A triangular spacer 82 is provided, and a sheath tube 82a is provided on an upper portion of the triangular spacer 82 for supporting the sheath tube. The tendon 80 is inserted into the sheath tube 82a and is thus installed in the transverse direction inside the slab 70.

The present invention further includes a fixing unit 90 installed at the end of the sheath tube 82a of the triangular spacer 82, as shown in FIG. 7, to fix both ends of the tendon 80 configured as described above. .

The fixing unit 90 includes a cylindrical case 92, a wedge 94 installed to be in close contact with the inner circumferential surface of the case 92, and a cap 96.

The cylindrical case 92 is disposed so that one side is opened to the outside of the slab 70, the inner diameter is reduced to the other side.

The wedge 94 positioned inside the case 92 is in close contact with the inner circumferential surface of the case 92, and a through hole is formed such that the tendon 80 in the sheath tube 82a is moved and disposed. It is configured to press the tendon 80 as it moves toward the slab 70 side. That is, the wedge 94 is formed so as to correspond to the shape of the inner surface of the case 92, so as to be pressed from all sides toward the other side of the case 92, the width of the through hole is also reduced, thereby the inside of the through hole The tendon 80 is also pressed and settled. It is preferable that the non-slip structure of the tendon 80 is formed on the inner surface of the through hole of the wedge 94. The non-slip structure is not limited to any structure as long as the tendon 80 is firmly fixed, such as a plurality of protrusions or threaded protrusion lines formed on the inner surface of the through hole.

In addition, the cap 96 is configured to cover one side of the case 92, the wax 98 is filled in the space between the wedge 94 and the cap 96 to maintain the airtight.

On the other hand, the tendon 80 is preferably made of a material of FRP (Fiber glass Reinforced Plastic). The FRP is a material mixed with glass fiber and plastic, resistant to external impact, very high in tensile strength, stronger than iron, and lighter than aluminum. Such FRP replaces the metal, ceramic materials, etc., which have been used in the past, and is light, has excellent durability, impact resistance, abrasion resistance, etc., and does not have rust, heat deformation, and easy processing.

In addition, the concrete of the slab 70 is preferably fiber reinforced concrete. The fiber reinforced concrete prevents the cracking of the concrete by using fibers, nonwoven fabrics and fabrics, and has excellent mechanical properties. Such fiber-reinforced concrete has an excellent resistance to cracking by sharing the cracked part with the other part, and has an advantage of improving durability of the concrete by having an excellent resistance to heat change and heat shrinkage.

A method of constructing the concrete bridge deck 100 according to the preferred embodiment of the present invention will be described in detail.

First, a plurality of concrete molds 50 having at least one pocket 52 formed in a length direction on the upper surface thereof are prepared, and a flat iron 60 having a fixing member is prepared on the upper and lower surfaces (S10). The pocket portion 52 has a groove-shaped structure that is deeply penetrated inwardly from the upper surface of the mold 50, and the pocket portion 52 having such a structure is preferable along the longitudinal direction on the upper surface of the mold 50. It is formed to be spaced apart from each other at regular intervals.

Then, as shown in Figure 8a, the plurality of molds 50 are installed side by side on the pier 40 (S11). The mold 50 is preferably installed side by side to be parallel to each other, it may be a multi-mold structure consisting of two or more molds consisting of two molds.

Subsequently, as shown in FIG. 8B, the fixing member of the bottom surface of the flat iron 60 is installed in the transverse direction with respect to the mold 50 so as to be positioned inside the pocket 52 of the mold 50 (S12).

In this case, the fixing member is preferably a perforbond connector 62 or stud 64. The flat iron 60 having such a fixing member has a stud 64 of the pocket 52 of the mold 50 when the perforbond connector 62 is installed on the upper surface and the stud 64 is installed on the lower surface. It is installed to be placed inside. In addition, although not shown in the drawings, when the studs 64 are installed on the upper surface of the flat iron 60 and the perforated connector 62 is installed on the lower surface, the perforon connector 62 is formed of the mold 50. It is arranged to be inside the pocket portion 52.

Of course, the fixing member of the present invention is not limited thereto, and both the upper and lower surfaces of the flat iron 60 may be provided with the perforbond connecting member 62 or both the studs 64 may be installed. In addition, as a fixing member installed on the upper and lower surfaces of the flat iron 60, a connection member other than the perforbond connector 62 or the stud 64 may be used.

Preferably, the perforbond connector 62 may be provided with a locking groove 62a or a locking plate 62b so that the slab (70 in FIG. 8E) is caught and fixed. The locking groove 62a or the locking plate 62b is filled with concrete in the process of placing concrete to make the slab 70 to be described later. As such, when the concrete is filled in the locking groove 62a or the locking plate 62b to reach a certain strength, the locking groove 62a or the locking plate 62b provides a fixing force so that the slab 70 does not move. . On the other hand, as shown in the drawing of the present invention, the perforbond connecting member 62 may be provided with a locking groove 62a and a locking plate 62b.

Then, as shown in FIG. 8C, a fixing force is provided by the fixing members of the flat iron 60 to form the slab 72 for placing the slab (70 of FIG. 8E) formed on the upper portion of the mold 50. Install) (S13).

Subsequently, a tendon (80 in FIG. 8E) is installed to be disposed inside the slab 70 so as to be parallel to the flat iron 60 and configured to provide a tension force.

In order to install the tendon 80 in this manner, first, as shown in FIG. 8D, the sheath tube support triangular spacer 82 is installed inside the formwork 72, and then the sheath tube support triangular spacer 82 is installed. The sheath pipe 82a is installed at the top of the). That is, the tendons (80 of FIG. 8e) are arranged in the transverse direction of the mold 50 so as to be parallel to the flat iron 60, such that the tendons 80 are installed so as to be located at a predetermined interval above the lower surface of the slab (70). In order for the tendon 80 to be drawn in, the sheath pipe 82a is installed.

Then, as shown in Figure 8e, the concrete for the slab 70 is poured and cured (S14). At this time, the vibrator is used so that the concrete is densely packed inside the pocket portion 52 of the mold 50. After a certain time has elapsed, when the concrete of the slab 70 reaches a certain strength, the tendon 80 is inserted into the sheath tube 82a to be elongated.

In order to fix the end of the tensioned tendon 80, after the sheath tube 82a is installed, a fixing unit 90 is installed at the end of the sheath tube 82a.

The fixing unit 90 is disposed inside the slab 70 and is disposed to open at one side to the outside of the slab 70, and the cylindrical case 92 formed to have a smaller inner diameter toward the other side, and the case 92. The through hole is formed to be in close contact with the inner circumferential surface of the sheath tube 82a so as to be disposed inward, and the wedge configured to press and fix the tendon 80 as it moves to the other side of the slab 70. 94, and a cap 96 configured to cover one side of the case 92.

The wedge 94 positioned inside the case 92 is in close contact with the inner circumferential surface of the case 92 and is formed with a through hole through which the tendon 80 is movable, and the tendon moves toward the slab 70. 80). That is, the wedge 94 is formed so as to correspond to the shape of the inner surface of the case 92, the pressure is pushed from all sides toward the other side of the case 92 to reduce the size of the through-holes, thereby The tendon 80 is also pressed and settled. It is preferable that the non-slip structure of the tendon 80 is formed on the inner surface of the through hole of the wedge 94. The non-slip structure is not limited to any structure as long as the tendon 80 is firmly fixed, such as a plurality of protrusions or threaded protrusion lines formed on the inner surface of the through hole.

On the other hand, tendon 80 used in the concrete bridge deck 100 construction process of the present invention, it is preferably made of a material of FRP (Fiber Reinforced Plastic). Furthermore, the concrete for the slab 70 is preferably fiber reinforced concrete.

Concrete bridge deck according to the present invention and its construction method, it is possible to improve the arching effect by the transverse fixing structure to the concrete mold and slab of flat iron to increase the load capacity of the bottom plate. That is, according to the present invention, the flat iron is firmly fixed to the mold by the fixing member provided on the lower surface, and the slab is firmly fixed to the upper portion of the mold by improving the arching effect by providing the fixing force to the slab by the fixing member provided on the upper surface. It can enhance the load capacity of the bottom plate.

In addition, the concrete bridge deck and the construction method according to the present invention further comprises a tendon is disposed inside the slab parallel to the flat iron and configured to provide a tension force, thereby suppressing the occurrence of cracking due to the transverse parent moment Durability can be improved. That is, the present invention preferably by placing a tendon made of a material of FRP (Fiber glass Reinforced Plastic), which is safe for corrosion, on the upper surface of the bottom plate, thereby eliminating damage to the bottom plate due to corrosion of the steel and suppressing cracks as much as possible. This can extend the life of the bottom plate.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

Claims (16)

A plurality of concrete molds 50 installed side by side on the piers 40 and having at least one pocket 52 formed on the upper surface thereof in the longitudinal direction; A flat iron (60) installed on the upper surface of the mold (50) and having a upper fixing member and a lower fixing member disposed inside the pocket portion (52) of the mold (50); And A slab (70) configured to be fixed by an upper fixing member of the flat iron (60) to be fixed to an upper portion of the mold (50); Concrete bridge deck 100, characterized in that it comprises a. The method of claim 1, The fixing member is a concrete bridge deck (100), characterized in that the perforbond connector (62) or stud (64). The method of claim 2, The perforbond connector 62 is a concrete bridge bottom plate 100, characterized in that the locking groove (62a) or the locking plate (62b) is formed so that the slab (70) is caught and restrained. The method of claim 1, Concrete bridge bottom plate (100), characterized in that it further comprises a tendon (80) disposed inside the slab (70) to be parallel to the flat iron (60) is configured to provide a tension force. The method of claim 4, wherein Further comprising a fixing unit 90 is installed on the inner side of the slab 70 to fix both ends of the tendon 80, The fixing unit 90, One side is disposed to open to the outside of the slab 70, the cylindrical case 92 is formed so that the inner diameter is smaller toward the other side; A wedge 94 in close contact with the inner circumferential surface of the case 92 and formed with a through hole in which the tendon 80 is movable, and configured to press and fix the tendon 80 as it moves to the other side of the case 92; And A cap 96 configured to cover one side of the case 92; Concrete bridge bottom plate 100, characterized in that the space between the wedge (94) and the cap (96) is filled with wax (98) to maintain airtightness. The method according to claim 4 or 5, The tendon 80 is a concrete bridge deck 100, characterized in that made of a material of FRP (Fiber glass Reinforced Plastic). The method according to any one of claims 1 to 5, Concrete of the slab 70 is concrete bridge deck 100, characterized in that the fiber reinforced concrete. (S10) preparing a plurality of concrete molds 50 having at least one pocket 52 formed in a longitudinal direction on an upper surface thereof, and preparing a flat iron 60 having fixing members on upper and lower surfaces thereof; (S11) installing the plurality of molds 50 side by side on the piers 40; (S12) installing the fixing member of the lower surface of the flat iron (60) with respect to the mold (50) so as to be located inside the pocket portion (52) of the mold (50); (S13) installing a formwork (72) for placing the slab (70) formed on top of the mold (50) by a fixing force provided by the fixing members of the flat iron (60); And (S14) pouring and curing concrete for the slab (70); Construction method of the concrete bridge deck 100, comprising a. The method of claim 8, The fixing member is a construction method of the concrete bridge deck 100, characterized in that the perforbond connector 62 or stud (64). The method of claim 9, The perforbond connecting member 62 is a construction method of the concrete bridge deck 100, characterized in that the locking groove (62a) or the locking plate (62b) is formed so that the slab (70) is caught and fixed. The method of claim 8, Installing the tendon 80 is disposed inside the slab 70 so as to be parallel to the flat iron 60 is configured to provide a tension force; the construction of the concrete bridge deck 100 further comprises a Way. The method of claim 11, Installing the tendon 80 is, After the step (S13), after installing the sheath tube support triangular spacer 82 on the inside of the formwork 72, the step of installing a sheath tube (82a) on the top of the sheath tube support triangular spacer; And After the step (S14), when the concrete of the slab 70 reaches a certain strength, the step of tensioning by inserting the tendon 80 in the sheath pipe (82a); concrete bridge floor plate comprising a Construction method of (100). The method of claim 12, In order to fix the end of the tensioned tendon 80, after the sheath tube 82a is installed, the fixing unit 90 is installed at the end of the sheath tube 82a; The fixing unit 90, A cylindrical case (92) disposed inside the slab (70) and disposed to open at one side to the outside of the slab (70), the inner diameter of the slab being reduced toward the other side; The through-hole is formed to be in close contact with the inner circumferential surface of the case 92 and the tendon 80 in the sheath tube 82a is moved to be disposed inward, and the tendon 80 is moved as it moves to the other side of the case 92. A wedge 94 configured to press firmly; And Cap 96 is configured to cover one side of the case 92; Construction method of the concrete bridge deck 100 characterized in that it comprises a. The method of claim 8, In the step (S14), using a vibrator so that the concrete is densely packed inside the pocket 52 of the mold 50; construction of the concrete bridge deck 100 further comprises a Way. The method according to any one of claims 11 to 14, The tendon 80 is a construction method of the concrete bridge deck 100, characterized in that made of a material of FRP (Fiber glass Reinforced Plastic). The method according to any one of claims 8 to 14, In the step (S14), the concrete is a construction method of the concrete bridge deck 100, characterized in that the fiber reinforced concrete.

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