KR100631031B1 - Precasted concrete plate and bridge slab construction method using that - Google Patents

Abstract

A PC(Prestressed Concrete) plate and a bridge slab construction method using the PC plate are provided to shorten the labor force and time in disassembling a mold or a supporting structure by placing the PC plate on a girder and using the PC plate as a lower mold, to strengthen the PC plate by inserting a steel plate into the PC plate, and to stand bending moment even in a long distance between the girders without increasing a section area. A PC(Prestressed Concrete) plate(100) placed on a girder of a bridge and disposed at the lower side of a field-poured concrete to form a slab together with the concrete comprises a main body manufactured with concrete in a pre-casting method and formed like a plate; iron bars(20) buried in the main body and arranged at regular intervals along the length and the width of the girder; a steel plate(30) disposed in the main body and curved of the middle of the main body upward about both ends; and a protrusion structure(40) partially buried in the main body and exposed of the rest part on the upper surface of the main body to be buried in the field-poured concrete so as to steadily combine the PC plate with the concrete.

Description

Precasted concrete plate and bridge slab construction method using that}

1 is a view for explaining a step of constructing a slab of a conventional bridge.

FIG. 2 is a cross-sectional view of the II-II line shown in FIG. 1. FIG.

3 is a view showing a PC plate manufactured according to an embodiment of the present invention.

4 is a sectional view taken along the line IV-IV shown in FIG. 3;

5 is a cross-sectional view of the slab manufactured using the PC plate shown in FIG.

FIG. 6 is a view showing an example of a state in which the PC plate shown in FIG. 3 is mounted on a girder of a bridge. FIG.

FIG. 7 is a view for explaining a process of constructing a slab by placing concrete on an upper surface of a PC plate in a state where the PC plate is mounted on a bridge as shown in FIG. 6;

Explanation of symbols on the main parts of the drawings

10: body 20: rebar

30 steel sheet

40: protrusion structure 41: truss reinforcement

42: lattice bar 43: connecting wire

The present invention relates to a PC plate and a slab construction method of a bridge using the PC plate, and more particularly, it is possible to use only a part of the formwork necessary for site casting of concrete, thereby improving process inconvenience such as removing formwork. In addition, it is possible to improve the efficiency of the work by simplifying the whole process, and particularly relates to a PC plate that can be installed even when the distance between the girders and a slab construction method of the bridge using the PC plate.

As shown in FIG. 1, a general bridge structure is arranged in parallel in a horizontal direction with a plurality of bridges 1 placed on the ground at regular intervals and an upper surface of each adjacent bridge 1 at regular intervals. And a cross beam 3 installed in a direction orthogonal to the girder 2 at regular intervals between the girder 2 and each adjacent girder 2 to reinforce the deflection of the girder 2, and It consists of a slab 4 arranged on the top of the girder 2.

In order to construct the slab 4 corresponding to the upper construction of the bridge, as shown in Figures 1 and 2, the support structure for supporting the formwork 5 and the formwork 5 between the girders (2) (6) is to be provided and it is made by curing concrete (not shown) on top. The casting of the concrete is made in stages from one end of the girder to the other end, Figure 1 shows a state in which the slab (4) is formed only on a part of the girder (2).

The formwork 5 and the supporting structure 6 as a frame for curing the slab 4, taking into account the aesthetics after the construction is completed, or make it easy to visually identify when a crack occurs in the concrete It must be dismantled and removed to make it possible.

By the way, when the construction in the same manner as in the prior art there was a problem that takes a lot of manpower and time to dismantle the formwork (5) and the support structure (6).

On the other hand, in recent years, the tendency of the bridge to increase in size, the cross section of the girder 2 is increasing accordingly, the gap between the girder 2 is gradually increasing. When the girder 2 is long due to such a trend, the bending moment that the slab 4 must support increases, and as a result, the increase in the cross-section of the slab 4 and the increase of its own weight due to the increase in the cross-section, resulting in rebar Problems such as an increase in amount occur, and also the formwork 5 fails to withstand the bending moment due to the weight of concrete and collapses.

The present invention was derived in order to solve the above-mentioned problems, a part of the slab of the bridge to be manufactured by the PC plate by the precasting method to be mounted on the girder by using the PC plate as the lower formwork to build the slab only by the side formwork This greatly reduces the manpower and time required for dismantling the formwork and the supporting structure, and increases the rigidity of the PC plate by inserting a steel plate into the PC plate, so that the warpage is not increased even when the gap between the girders is long. An object of the present invention is to provide a PC plate capable of supporting moments and a slab construction method of a bridge using the PC plate.

In order to achieve the above object, the present invention is mounted on the girder of the bridge, disposed in the lower portion of the cast concrete, in the PC plate constituting the slab together with the cast concrete,

It is produced in a precast manner, the plate-shaped body made of concrete;

A reinforcing bar embedded in the main body, the reinforcing bar having a predetermined interval in the longitudinal direction and the width direction of the girder;

A steel sheet disposed inside the main body and curved in a curved shape such that a central portion thereof rises upward from both ends thereof;

A part which is embedded in the main body, and the other part is exposed to the upper surface of the main body to be embedded in the site-casting concrete to secure the coupling between the PC plate and the site-casting concrete; It provides a PC plate comprising a.

The compressive strength of the body is preferably not less than the compressive strength of the cast-in-place concrete.

It is preferable that the thickness of the said main body is 50 mm or more and 60% or less of the slab thickness.

The protruding structure,

A pair of truss bars embedded in the main body in parallel with each other and disposed to extend in the width direction of the girder;

A lattice bar disposed side by side with the pair of rebars at a position exposed to the outside of the main body of the central upper portion of the pair of rebars; And

It is preferable that a plurality of connecting wires are provided in the width direction of the girder and connect the pair of reinforcing bars and the lattice bar to each other.

On the other hand, the present invention in the slab construction method of the bridge to mount a plurality of girders on the upper surface of the pier, to form a slab on the top of the girder,

A PC plate manufacturing step of manufacturing a PC plate according to claim 1;

A PC plate installation step of installing the manufactured PC plate on the girder;

A slab construction step of reinforcing the reinforcing bar on the upper part of the installed PC plate, the concrete is cast on-site to synthesize the PC plate and the cast-in-place concrete integrally and then curing the slab to form a slab; It provides a slab construction method of the bridge comprising a.

The compressive strength of the concrete forming the PC plate is preferably not less than the compressive strength of the cast-in-place concrete.

Before the PC plate installation step,

A mortar coating step of applying cement mortar to the PC plate on the girder at the position where the PC plate is installed on the girder so that the PC plate can be fixed without slipping on the upper surface of the girder;

It is preferable to further include.

On the other hand, before the PC plate installation step,

A rubber plate installation step of installing a rubber plate on the girder upper surface of the position where the PC plate is installed on the girder, to prevent the PC plate from slipping on the upper surface of the girder, and to prevent leakage of the cast-in-place concrete;

It is preferable to further include.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a view illustrating a PC plate manufactured according to an embodiment of the present invention, FIG. 4 is a cross-sectional view of the IV-IV line shown in FIG. 3, and FIG. 5 is a slab manufactured using the PC plate shown in FIG. It is a cross section of.

PC plate 100 according to an embodiment of the present invention is a structure mounted on the girder (2) of the bridge, at the bottom of the cast-in-place concrete 50 that is poured at the bridge construction site at the time of construction of the slab 200 And the slab 200 (see FIG. 5) together with the cast-in-place concrete 50.

The PC plate is composed of a main body 10, a reinforcing bar 20, a steel plate 30 and a protruding structure 40.

The main body 10 is made of concrete and is formed in a plate shape. The body 10 is manufactured in a precast manner. In general, the main body 10 has the shape of a long rectangle in one direction.

The compressive strength of the concrete constituting the main body 10 is preferably not less than the compressive strength of the cast-in-place concrete (50). This is because it is structurally stable that the compressive strength of the main body 10 is greater than the compressive strength of the cast-in-place concrete 50, and when the compressive strength is weak, a crack may occur in the transport process.

The thickness of the main body 10 is 50mm or more, and 60% or less of the thickness of the slab 200.

When the thickness of the main body 10 is 50 mm or less, it is difficult to embed the stranded wire 30 because it is too thin, and its cross section is too small, which may cause problems such as cracking during transportation due to a drop in overall strength. Very high.

In addition, when the thickness of the main body 10 is 60% or more of the thickness of the slab 200, since the thickness of the cast-in-place concrete 50 is relatively thin compared to the thickness of the main body 10, the main body 10 and the main body ( 10) is easily cracked in the joints connected to each other, if the main body 10 is too thick, the weight of the main body 10 is large, there is a high possibility of difficulty in carrying or installation during construction, limiting the thickness It is preferable.

The reinforcing bar 20 is embedded in the main body 10, it is disposed at a predetermined interval in the longitudinal direction and the width direction of the girder (2).

The steel plate 30 is disposed inside the main body 10. The steel sheet 30 has a shape in which the center portion thereof rises upward from both ends thereof, and thus, when the bending moment acts on the PC plate 100, the bending moment is supported together with the reinforcing bar 20. . As shown in FIG. 3, the steel sheet 30 is disposed to be long in the direction of the long side of the main body 10.

3 shows that one steel sheet is embedded in the main body 10, the number and thickness of the steel sheet, its curved shape, etc. can be appropriately modified according to the load supported by the PC plate 100.

The steel sheet 30 is manufactured in advance so as to form the above-described form, that is, its central portion rises from both ends thereof, and is installed in a form for forming the main body 10, and the main body 10 by the method of pouring concrete. It is possible to bury in, it is also possible to bury the concrete 10 after it is inserted into the body (10).

The protruding structure 40 is composed of a pair of truss reinforcing bar 41, a lattice bar 42 and a plurality of connecting wire 43.

The pair of truss bars 41 are embedded in the main body 10 in parallel with each other, and are arranged long in the width direction of the girder 2.

The lattice bar 42 is disposed above the center of the pair of truss reinforcing bars 41, and the lattice bar 42 is spaced apart from the truss reinforcing bars 41 by a predetermined distance to the outside of the main body 10. To be located at The lattice bar 42 is arranged side by side with the truss reinforcing bars (41).

As shown in FIGS. 3 and 4, the connecting wire 43 connects the truss bars 41 and the lattice bar 42 to each other. Both ends of the connecting wire 43 are hooked, and are caught in the truss reinforcing bar 41. In order to connect the lattice bar 42 and the truss reinforcing bar 41 with each other, a junction part of the lattice bar 24 and the connecting wire 43 and a junction part of the truss reinforcing bar 41 and the connecting wire 43 Fix by welding or fix by using thin wire.

As shown in FIG. 5, a part of the pair of truss reinforcing bars 41 and the connecting wire 43 among the components of the projecting structure 40 assembled as described above are embedded in the main body 10, and the lattice bar ( 42 and the rest of the connecting wire 43 is exposed to the upper surface of the main body 10, it is later embedded in the site-cast concrete (50). A portion of the lattice bar 42 and the connecting wire 32 is embedded in the cast-in-place concrete 50, thereby making it possible to solidify the synthesis of the PC plate 100 and the cast-in-place concrete 50. In addition, since the lattice bar 42 also functions as reinforcing steel for cast-in-place concrete, it serves to share a part of the load of the slab 200 formed by combining the PC plate 100 and the cast-in-place concrete. In addition, the lattice bar 42 also serves as a flexural reinforcement material that resists work loads generated by equipment or labor generated when the slab 200 is cast in situ.

Hereinafter, an embodiment of constructing a slab of a bridge using the above-described PC plate will be described in detail.

FIG. 6 is a view showing an example of a state in which the PC plate shown in FIG. 3 is mounted on the girder of the bridge, and FIG. 7 is a top surface of the PC plate in the state where the PC plate is mounted on the bridge. This is a view for explaining the construction of the slab by placing concrete in the field.

The slab construction method of the bridge according to an embodiment of the present invention consists of a PC plate manufacturing step, mortar coating step, PC plate installation step, slab construction step.

The manufacturing process of the PC plate 100 is a step of manufacturing the PC plate 100 described above. The PC plate 100 stands for precast concrete plate and refers to a concrete plate manufactured in a factory dedicated to the production of the PC plate 100 rather than the site.

In order to manufacture this, after installing the formwork in a factory dedicated to the production of the PC plate 100, the reinforcing bar 20 and the steel plate 30 and the projecting structure 40 is placed on the formwork, and the concrete is poured and cured. The steel sheet 30 may of course be inserted after curing of concrete before curing.

When manufacturing the PC plate 100 by the precasting method, the factory is manufactured by using a fixed facility in the factory, so that it is possible to work in the optimum conditions, and the accuracy (precision) and strength compared to the concrete product installed in the field There is an advantage that can improve the (强度).

At this time, the compressive strength of the concrete forming the body 10 of the PC plate 100 is not less than the compressive strength of the cast-in-place concrete (50).

When the PC plate 100 is manufactured, it is transported to the site.

Mortar coating step is a step of applying the cement mortar to the upper surface of the girder (2). Mortar coating operation is to apply to the upper surface of the position where the PC plate 100 is installed on the girder (2), so that the PC plate 100 can be attached well without slipping on the upper surface of the girder (2) It's work.

The PC plate installation step refers to the step of installing the PC plate 100 manufactured as described above and transported to the site on the mortar-coated girder 2.

The installation of the PC plate 100 on the girder 2 may use a crane, which may use a bogie as described in the specification of Patent No. 403989 filed by the applicant of the patent application. Is as shown in FIG.

The slab construction step is a step of forming a slab by synthesizing the PC plate 100 and the cast-in-place concrete 50, reinforces the necessary reinforcing bar on the top of the PC plate 100 installed as described above, and cast the concrete By curing the slab is completed.

7 is a view for explaining the slab construction step, showing that the cast-in-place of the concrete step by step from the left side of the drawing, the illustration of the reinforcing bars to be disposed on the formwork and the PC plate upper surface for convenience.

In the above, the embodiment in which the compressive strength of the PC plate body is not smaller than the compressive strength of the cast concrete is described. However, the compressive strength of the PC plate body is not necessarily smaller than the compressive strength of the cast concrete. As long as the difference is not remarkable, the object of the present invention can be achieved.

In the above description, a protrusion structure consisting of a pair of truss bars, a lattice bar and a connecting wire is described, but the protrusion structure is not necessarily provided with all of the above-listed components, some of which are embedded in the body, and others of the body Exposed to the upper surface, provided with a structure capable of solidifying the synthesis of the PC plate and the cast-in-place concrete is not beyond the scope of the present invention.

In the above description, a method of constructing a slab of a bridge including a mortar coating step is described. However, instead of applying mortar, a rubber plate is installed on the upper surface of the girder to prevent the PC plate from slipping, and at the same time, the cast-in-place concrete is fine between the girder and the PC plate. It may be prevented from leaking through the gap, such a configuration is not contrary to the technical idea of the present invention.

On the other hand, mortar must be applied or the rubber plate is not necessarily installed, and after the PC plate is mounted on the girder without the application of the mortar or the installation of the rubber plate is also not beyond the scope of the present invention.

In the above, the state in which the PC plate is mounted in the width direction of the girder has been shown and described, but the PC plate is not necessarily mounted in the width direction of the girder, and when mounted on the cross beam connecting the girder in the longitudinal direction of the girder It may be installed as, such implementation is also included in the technical idea of the present invention.

In the above description of the preferred embodiment of the present invention, the technical idea of the present invention is not necessarily limited to the embodiments described above, various PC plate and the PC plate without departing from the technical idea of the present invention It can be specified by the construction method of the bridge using.

In the case of using the PC plate as described above, since the PC plate plays the role of the lower formwork, there is an advantage that does not need to remove the lower formwork generated when the entire slab is made of cast-in-place concrete.

In addition, by inserting the steel plate rising upwards on the PC plate to increase the rigidity of the entire PC plate, it is possible to support a large bending moment without changing the cross section, even if the gap between the girder is thinner than before There is an advantage that you can use the slab. Due to the recent trend toward longer bridges, the gap between girders is also increasing. If the gap between girder becomes longer, the slab must support a large bending moment, and if the existing slab is used, the cross section must be increased to support the large bending moment. Therefore, additional reinforcement means are needed to support the bending moment due to its own weight. However, when the PC plate according to the present invention is used, even when the distance between the girders is increased, it is possible to support a large bending moment without increasing the cross section, so it is structurally stable and very efficient, and construction at a very low cost in terms of construction cost. This possible alternative can be suggested.

Claims (8)

In the PC plate which is mounted on the girder of the bridge, is disposed under the cast-in-place concrete, and forms the slab together with the cast-in-place concrete, It is produced in a precast manner, the plate-shaped body made of concrete; A reinforcing bar embedded in the main body, the reinforcing bar having a predetermined interval in the longitudinal direction and the width direction of the girder; A steel sheet disposed inside the main body and curved in a curved shape such that a central portion in a longitudinal direction of the main body rises upward from both ends thereof; A part which is embedded in the main body, and the other part is exposed to the upper surface of the main body to be embedded in the site-casting concrete to secure the coupling between the PC plate and the site-casting concrete; PC plate, characterized in that comprises a. The method of claim 1, PC plate, characterized in that the compressive strength is not less than the compressive strength of the cast-in-place concrete. The method of claim 1, The thickness of the main body is 50mm or more and the PC plate, characterized in that 60% or less of the slab thickness. The method of claim 1, The protruding structure, A pair of truss bars embedded in the main body in parallel with each other and disposed to extend in the width direction of the girder; A lattice bar disposed side by side with the pair of rebars at a position exposed to the outside of the main body of the central upper portion of the pair of rebars; And A PC plate provided in the width direction of the girder, and comprising a plurality of connecting wires connecting the pair of reinforcing bars and the lattice bar to each other. In the slab construction method of the bridge to mount a plurality of girders on the upper surface of the pier, and to form a slab on the top of the girder, A PC plate manufacturing step of manufacturing a PC plate according to claim 1; A PC plate installation step of installing the manufactured PC plate on the girder; A slab construction step of reinforcing the reinforcing bar on the upper part of the installed PC plate, the concrete is cast on-site to synthesize the PC plate and the cast-in-place concrete integrally and then curing the slab to form a slab; Slab construction method of the bridge comprising a. The method of claim 5, The slab construction method of the bridge, characterized in that the compressive strength of the concrete forming the PC plate is not less than the compressive strength of the cast-in-place concrete. The method of claim 5, Before the PC plate installation step, A mortar coating step of applying cement mortar to the PC plate on the girder at the position where the PC plate is installed on the girder so that the PC plate can be fixed without slipping on the upper surface of the girder; Slab construction method of the bridge further comprising a. The method of claim 5, Before the PC plate installation step, A rubber plate installation step of installing a rubber plate on the girder upper surface of the position where the PC plate is installed on the girder, to prevent the PC plate from slipping on the upper surface of the girder, and to prevent leakage of the cast-in-place concrete; Slab construction method of the bridge further comprising a.

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