KR20200092593A - Concrete slab of bridge with precast cantilever slab and concrete slab of bridge construction method therefor - Google Patents

Abstract

Provided are a bridge slab manufactured by a protective wall integrated type precast cantilever slab and a construction method thereof, wherein the bridge slab manufactured by the protective wall integrated type precast cantilever slab can install a precast slab between upper surfaces of installed girders, stably construct the protective wall integrated type precast cantilever slab on the girder at an outermost side, and have increased workability and economic feasibility. The bridge slab manufactured by the protective wall integrated type precast cantilever slab uses a temporary support which includes: a horizontal temporary beam horizontally extended in a transverse direction; and a vertical support fixed to the upper surface of the girder at the other end or a central portion of the horizontal temporary beam so as to resist conduction by a bending negative moment applied to the protective wall integrated type precast cantilever slab, and restricting the horizontal temporary beam.

Description

Bridge slab made of integrated precast cantilever slab and its construction method {CONCRETE SLAB OF BRIDGE WITH PRECAST CANTILEVER SLAB AND CONCRETE SLAB OF BRIDGE CONSTRUCTION METHOD THEREFOR}

The present invention relates to a bridge slab made of a protective wall-integrated precast cantilever slab and a construction method therefor. More specifically, a precast slab between the upper surfaces of the installed girders and a bridge slab made of a protective wall-integrated precast cantilever slab with excellent workability and economy while allowing a more stable construction of a protective wall integrated precast cantilever slab on the outermost girder. It is to provide a construction method.

Figure 1a shows the construction of a conventional precast concrete panel.

The slab installed on the outermost girder 1 of the bridge is called the cantilever slab 10 because it is installed hanging from the side of the girder 1.

That is, since the bending part moment is installed based on the lateral side of the outermost girder, it is called a cantilever slab 10, and such a bending positive moment in the opposite direction is generated so that the cantilever slab 10 is not conducted. Construction.

Accordingly, when constructing the cantilever slab 10 with cast-in-place concrete, it is necessary to install a bracket that is used as a round bar for supporting the formwork for the cantilever slab 10 on the side of the girder (1).These brackets are installed and dismantled. There was a problem that the last name is very low.

Therefore, in manufacturing the cantilever slab 10 in a precast manner and installing the lift, it must be installed by hanging to the side of the girder 1, so that conduction due to the bending moment should be restrained.

Accordingly, in the case of FIG. 1A, the hanger bar 15 is pulled out on the upper surface of the cantilever slab 10, the support block 30 is installed on the upper surface of the girder 1, and the cantilever slab 10 is used using the turnbuckle 40. It can be seen that) is not conducted by the bending part moment.

However, when the turnbuckle 40 and the support block 30 are used as described above, the cantilever slab 10 is additionally increased in use depending on the amount of use, and is forced to be embedded in the poured slab concrete, and the hanger bar 15 is added. The manufacturing cost of the cantilever slab 10 according to the formation also has to be increased, which inevitably lowers the economic efficiency.

Figure 1b shows the construction of a conventional precast concrete panel.

That is, the anchor 40 is pulled out on the upper surface of the girder 70 and the semi-circular connecting rebar 20 of the cantilever slab 10 is pulled out so that the connecting rebar 20 is connected to the anchor 40. It can be seen that the binding force capable of resisting the bending moment can be secured by the nut 50.

However, while constraining the connecting rebar 20 of the cantilever slab 10 to the anchor 40, the lifting state must be maintained by the equipment, and thus the work process is complicated and the air is forced to be delayed. .

Republic of Korea Patent No. 10-1237000 (Invention name: precast concrete panel construction method, publication date: February 26, 2013)

Accordingly, the present invention can minimize the material loss while efficiently operating the equipment for the installation of a protective wall-integrated precast cantilever slab, so that a rapid and economical bridge slab construction is possible, and a bridge slab made of a protective-wall precast cantilever slab and its construction This is a technical task to solve the provision of the method.

In addition, the present invention is to maximize the utilization of the block-out space (S) on the upper surface of the girder by installing a protective wall-integrated precast cantilever slab and a precast slab on the girder so as not to occupy the end space of the upper flange of the girder. It is a technical problem to solve the provision of a bridge slab made of a precast cantilever slab and its construction method.

In addition, the present invention is to provide a horizontal drainage hole of a protective wall-integrated precast cantilever slab as a support hole, thereby providing a stable and efficient construction of a bridge slab made of a protective wall-integrated precast cantilever slab and a technical problem to solve the provision of the construction method Shall be

In addition, the present invention is a bridge slab made of a protective wall-integrated precast cantilever slab that can be constructed simply and stably by using a temporary support structure of a wall-mounted precast cantilever slab in which a horizontal drain hole is not formed, and a construction method thereof It is considered as a technical task to solve the provision.

A bridge slab made of a protective wall-integrated precast cantilever slab of the present invention for achieving the above object includes a horizontal hypothesis beam horizontally extended horizontally so that one end is inserted into a horizontal drainage hole of a protective wall-integrated precast cantilever slab; And a vertical support fixed to the upper surface of the girder at the other end or the middle of the horizontal hypothesis beam to constrain the horizontal hypothesis beam to resist conduction by the bending moment acting on the protective wall-integrated precast cantilever slab; It is constructed to integrate the girder and the protective wall integrated precast cantilever slab to each other by installing the protective wall integrated precast cantilever slab on the outermost girder. A bridge slab made of a precast cantilever slab of a protective wall in which a slab concrete (C) or a slab finishing material is placed in the blotted-out space (S).

According to the present invention, it is possible to increase the usability and aesthetics because the precast cantilever slab, which is an integrated wall, is precisely fitted to the girder upper end (B) as a horizontal support beam and a vertical support as a temporary support, and then a bridge slab is constructed. This is it.

According to the present invention, since the horizontal hypothesis beam of the temporary support is recoverable and reusable, it is possible to increase the operation efficiency of the equipment while being stable, and thus it is possible to rapidly and economically manufacture and construct a bridge slab.

According to the present invention, the protection wall integrated precast cantilever slab maximizes the utilization of the protection wall integrated precast cantilever slab by enabling the horizontal drainage hole of the horizontal hypothesis beam to also be used as a support hole for drainage and support installation, thereby maximizing the efficiency and economical bridge Slab construction becomes possible.

According to the present invention, even when a horizontal drainage hole is not formed, the protective wall-integrated precast cantilever slab can be constructed by simply hanging it on a temporary support and then constructing a bridge slab, thereby enabling construction of a bridge slab with excellent workability and workability. .

1a and 1b is a construction diagram of a conventional precast concrete panel
Figures 2a, 2b, 2c and 2d is a perspective view of the construction and construction of a bridge slab made of a precast cantilever slab of the protection wall of the present invention,
3A, 3B, 3C, and 3D show a construction flow chart of a method for constructing a bridge slab made of a protective precast cantilever slab of the present invention.

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 to which the present invention pertains may easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part “includes” a certain component, it means that the component may further include other components, not to exclude other components, unless otherwise stated.

[Bridge slab made of precast cantilever slab 100 of the protection wall integral type of the present invention]

2A, 2B, 2C, and 2D show a perspective view and a constructional view of a bridge slab (A) made of a precast cantilever slab (100) integrated with a protective wall of the present invention.

First, the bridge slab (A) of the present invention is constructed with a protective wall integrated precast cantilever slab 100 and a precast slab 200.

At this time, the protective wall-integrated precast cantilever slab 100 and the precast slab 200 are pre-fabricated with the slab finishing material 600 or the slab concrete (C) mounted on the top surfaces of the girders 300 and 300a, respectively. By integrating the girder (300,300a), a protective wall integrated precast cantilever slab 100 and the precast slab 200 to complete the bridge slab (A).

In this case, the protective wall-integrated precast cantilever slab 100 is installed in the form of a cantilever on the outermost girder 300a in the transverse direction (right angle direction of the throttle direction), and the precast slab 200 is a girder 300 It is installed between the upper surface of the girder 300, and is also a method of constructing a bridge slab A by pouring slab finishing material 600 or slab concrete (C).

That is, the integrated precast cantilever slab 100 of the protective wall is formed in a shape of a b in which the protective wall is integrally formed, and the precast slab 200 is formed in the form of a horizontal plate, and in the case of a full-deck method, separate slab concrete is not poured. Instead, the bridge slab (A) is constructed with only the slab finishing material 600, and in the case of the half-deck method, the bridge slab (A) is constructed by pouring slab concrete.

First, the girder 300, as shown in Figures 2a and 2b, as a bridge girder is usually made of an I-shaped cross section, the present invention will be described based on the PSC girder.

Accordingly, the girders (300, 300a) is composed of an upper flange 310, an abdomen and a lower flange, and an upper precast slab 200 is installed on the upper surfaces of the upper flange 310 and the upper flange 310, and the outermost girder 300a. In the protective wall integrated precast cantilever slab 100 is installed.

Accordingly, the space formed on the upper surface of the upper flange of the girder (300,300a) where the integrated precast cantilever slab (100) and the precast slab (200) are installed is a block-out space (S) and a finishing filler (600), such as concrete. The slab concrete (C) is filled so that the protective wall-integrated precast cantilever slab 100, the precast slab 200 and the girders 300 and 300a are integrated with each other to be synthesized.

Next, the protective wall-integrated precast cantilever slab 100 is installed at the end (B) of the upper flange 310 of the outermost girder 300a, and the protective wall is integrally formed as a whole in a cross-section.

It is manufactured in the factory and brought into the site, and then lifted and installed. It must be kept horizontal on the side of the outermost girder until it is integrated with the outermost girder (300a).

2A and 2B, the present invention uses a hypothesis support 500 including a horizontal hypothesis beam 510 and a vertical support 520.

First, the other end of the horizontal hypothesis beam 510 is inserted into a horizontal drainage hole 110 formed in the abdomen which is a rough middle of the protective wall-integrated precast cantilever slab 100, and is horizontal to the outermost girder 300a side. It serves to support the setting state to be maintained, and uses an H-type steel beam, but the lifting hook 511 for installation is formed on the top surface.

Accordingly, when the other end is in contact with the upper surface of the horizontal drainage hole 110, a bending part moment is generated at one end of the horizontal hypothesis beam 510 by the self-weight of the protective wall integrated precast cantilever slab 100. If this is not supported, the protective wall integrated precast cantilever slab 100 will attempt to conduct.

The vertical support 520 is to constrain the horizontal hypothesis beam 510 to the upper surface of the girder 300,300a at the other end or the middle of the horizontal hypothesis beam 510 in order to resist conduction by the bending moment.

2A and 2B, the vertical support 520 includes a vertical pipe 521, a vertical fixing bolt 522, an inner fastener 523, a support plate 524, and a height adjusting tool 525. .

First, the vertical pipe 521 is to be vertically extended upwards to the upper surfaces of the girders 300 and 300a, but at least have a height corresponding to the thickness of the bridge slab, and the inner lower end accommodates the inner fastener 523 as a fastening nut. do.

Accordingly, the lower flange is fixed to the upper surface of the girder (300,300a) using an anchor bolt, so that the vertical pipe 521 can be fixedly installed.

Next, the vertical fixing bolt 522 uses a rod-shaped bolt member with a lower end fastened to the inner fastener 523 fastened to the lower end of the vertical tube 521.

The length of the extension is such that it can penetrate the horizontal hypothesis beam 510 so that the head can be fixed on the horizontal hypothesis beam 510 so that the horizontal hypothesis beam 510 will be fixed in the upper space of the girder 300,300a. To make it possible.

The support plate 524 is positioned on the bottom surface of the horizontal hypothesis beam 510 so that the vertical fixing bolt 522 penetrates, and the height adjusting mechanism 525 fastened to the outer peripheral surface of the vertical fixing bolt 522 on the bottom surface of the supporting plate 524 ) Is fastened to the nut so that it can be set while adjusting the height of the support plate 524 while rotating the nut.

The height adjuster 525 is for supporting the support height of the support plate 524, and the horizontal hypothesis beam 510 using a nut fastened on the bottom surface of the support plate 524 and the top surface of the horizontal hypothesis beam 510. While setting the height of, the horizontal hypothesis beam 510 to the vertical fixing bolt 522 is stably fixed and separated.

For example, when the slab finishing material is poured and cured up to the height of the vertical tube 521 of the vertical support 520, the lower end of the vertical fixing bolt 522 is loosened from the inner fastening hole 523 to support plate 524, height adjusting device ( 525) and the horizontal hypothesis beam 510.

In the end, the protection wall-integrated precast cantilever slab 100 is positioned while maintaining the horizontal state by the temporary support 500, and the protection wall-integrated precast cantilever slab 100 is mounted on the upper side of the girder by the mounting nut 400. It will be located at the end of the flange (B).

Next, the mounting nut 400 is provided with an eccentric sleeve 410, as shown in Figures 2a and 2b, the protective wall integral precast cantilever slab 100, the precast slab 200, the upper flange end of the girder (B ).

As described above, the block-out space S formed on the top of the upper flange 310 of the girders 300 and 300a has a protective wall-integrated precast cantilever slab 100 and a connection drawn out from the side of the precast slab 200 The rebar (not shown), the connecting rebar (not shown) drawn from the upper surface of the upper flange of the girder is a part that is settled while being connected to each other, so it must be formed with a space above a certain standard.

However, in the related art, since the bottom faces of the precast cantilever slab 100 and the precast slab 200 are installed so as to be supported, the blockout space is not possible due to the failure of the girder 300 to fit the upper flange end B. There was a problem in that the integration performance and aesthetics were deteriorated because S) had to be violated.

Accordingly, the present invention can secure the mounting precision of the protective wall integrated precast cantilever slab 100 and the precast slab 200 according to the lateral gradient by using the mounting nut 400, but also the protective wall integrated precast. The cantilever slab 100 and the precast slab 200 do not invade the block-out space S, that is, it can be installed in accordance with the girder upper flange end B.

Therefore; 2A and 2B, the mounting nut 400 is a cylindrical sleeve 410 through which an eccentric fastening hole 420 is penetrated. Accordingly, an eccentric bolt 430 is inserted into the eccentric fastening hole 420.

Normally, the girders 300 and 300a have a difference in the upper surface height as they go to both sides than the center of the lateral direction based on the lateral direction of the slab (gradient formation for drainage) and construction errors.

Accordingly, a construction error occurs at the height of the upper surface of the protective precast cantilever slab 100 or the precast slab 200, which is installed on the upper surface of the girder 300 and 300a.

Accordingly, the eccentric bolt 430 of the present invention has one side fastened to the cylindrical sleeve 410, and the other side is embedded and fixed to the lower side of the protective wall integrated precast cantilever slab 100 or the precast slab 200, thereby being cylindrical As the sleeve 410 is rotated, a difference occurs as the top surface height of the cylindrical sleeve 410 is rotated by the eccentric fastening hole 420.

Accordingly, while rotating the cylindrical sleeve 410, the lateral gradient of the integrated precast cantilever slab 100 or the precast slab 200 is adjusted,

Cylindrical sleeve 410 while the upper surface of the girder (200,300a) in contact with the upper surface 310 of the protective wall integrated precast cantilever slab (100) or precast slab (200) the position of the upper flange (310) of the girder (300) When the slab concrete is placed in accordance with the end, the finish of the end is easy to enhance the aesthetics.

Looking at the reference to Figure 2a, the girders (300,300a) is installed, between the upper surface of the upper flange of the girder precast slab 200 is installed at the upper flange end (B) by the mounting nut 400, , Vertical support 520 is installed on each of the two girders (300,300a), the horizontal hypothesis beam 510, while adjusting the height to the vertical support 520 to be positioned on the precast slab 200 and You can see that there is.

Accordingly, while lifting the side wall of the outermost girder into the lateral space of the outermost girder in the horizontal drainage hole 110 of the protective wall-integrated precast cantilever slab 100, the outermost girder by the cylindrical sleeve 410 is also inserted. It is to be set at the end of the upper flange of (300a).

At this time, the bridge drain pipe 120 is connected to the horizontal drain hole 110 so that rainwater derived from the upper surface of the bridge slab can be discharged along the bridge drain pipe 120 through the horizontal drain hole 110.

Accordingly, the construction of the bridge slab is completed through a slab finishing material 600 such as concrete in addition to the blotted-out space S between the sidewalls of the precast cantilever slab 100 and the precast slab 200 and the upper flange of the girder. To be able to.

At this time, as shown in Figures 2a and 2b, the protective wall integral precast cantilever slab 100 and the precast slab 200 side is formed so that the step is formed so that the waterproof performance is improved as the flow path increases when the rainwater penetrates While doing so, it is advantageous to secure the integrity as the contact area with the slab finishing material 600 increases.

Accordingly, in the construction of the full-deck method, the slab finishing material 600 is filled only in the space S that is blocked out to the upper surface heights of the precast cantilever slab 100 and the precast slab 200, so that the vertical support 520 ), but the vertical tube 521 and the internal fastener 523 inside the vertical tube are buried, but the vertical fixing bolt 522, the support plate 524, and the height adjusting device 525 can be separated and recovered. As a result, it is possible to increase economic efficiency and efficiency.

In addition, the horizontal hypothesis beam 510 does not need to support the integral precast cantilever slab 100 when the final protection wall-integrated precast cantilever slab 100 is integrated with the girder 300, so the horizontal hypothesis beam from the horizontal drainage hole It is recovered by subtracting (510).

In FIG. 2A, in particular, the temporary support beam 500 including the horizontal hypothesis beam 510 and the vertical support 520 for installing the protective precast cantilever slab 100 was examined, and the bridge slab A was transversely. It can be seen that a plurality of precast slabs 200 can be installed while being extended, and according to FIG. 2C, the horizontal hypothesis beams 510 can be set by connecting them horizontally.

In this case, since the supporting capacity of the protective wall-integrated precast cantilever slab 100 is increased, it is possible to set the position of the protective wall-integrated precast cantilever slab 100 more stable.

Furthermore, as shown in FIG. 2D, it may be constructed in a half-deck method, in which case, instead of the slab finishing material 600, the slab concrete (C) is higher than the upper surface height of the integrated precast cantilever slab 100 and the precast slab 200. Although it is to be formed, the slab concrete (C) is a vertical tube 521 constituting the vertical support 520 and the inner fastener 523 inside the vertical tube is embedded, but the vertical fixing bolt 522, the support plate 524 ), the height adjuster 525 can be separated and recovered, thereby increasing economic efficiency and efficiency.

In addition, since the protective wall-integrated precast cantilever slab 100 may be used in which the horizontal drain pole 110 is not formed, in this case, the end of the horizontal hypothesis beam 510 can be mounted on a connector formed on the upper surface of the protective wall to hang. By adopting, it can be seen that the extension length of the vertical fixing bolt 522 constituting the vertical support 520 can be extended upward.

[Construction method of bridge slab made of precast cantilever slab with integrated protection wall of the present invention]

3A, 3B, 3C, and 3D show a construction flow chart of a method for constructing a bridge slab made of a protective precast cantilever slab 100 of the present invention.

The bridge slab construction method, after installing the precast slab 200 and the temporary support 500 on the girders (300,300a), the protective beam integrated precast cantilever slab (100) on the horizontal hypothetical beam (510) of the temporary support 500 ), the slab finishing material 600 is poured or the slab concrete is poured into the block-out space S of the upper surface of the girder 300,300a, and the bridge slab ( It can be said as a method of constructing A).

Looking specifically at this,

After mounting the girders (300, 300a) on the bridge undercarriage, install the vertical support (520) of the hypothetical support (500) as described above on the upper flange of the girder, and then use the eccentric support nut (400). The precast slab 200 is positioned according to the end of the upper flange to be installed.

At this time, the vertical support 520 is to be fixed to the upper surface of the girder (300,300a) using an anchor bolt, the lower flange of the vertical tube 521, as shown in Figure 3a, as a fastening nut at the bottom of the vertical tube 521 The internal fastener 523 is accommodated. Accordingly, a vertical fixing bolt 522 is installed in a manner of fastening the lower end to the inner fastening hole 523, and a nut, which is a height adjusting hole 524, is fastened to the vertical fixing bolt 522, and the vertical fixing bolt 522 is provided. It can be seen that the support plate 524 is set in the height adjusting device 524 by allowing the support plate 524 to penetrate therethrough.

In addition, while rotating the mounting nut 400, the cylindrical sleeve 410 of the mounting nut 400 is aligned with the lateral gradient in a process to stably contact the upper surface of the upper flange of the girder, and the final girder (300,300a) The precast slab 200 is installed in accordance with the end of the upper flange 310.

The precast slab 200 is a horizontal plate corresponding to the thickness of the bridge slab, so it is installed in a full-deck manner because no slab concrete is separately placed, and a step is formed on the side, and although not shown, the connecting reinforcing bar is an upper flange. It is allowed to be drawn into the block-out space S in the upper portion so that it can be buried by the slab finishing material 600.

Next, as shown in FIG. 3B, the horizontal hypothesis beam 510 of the hypothesis support 500 is installed on the fixed support 520.

That is, by lifting the horizontal hypothesis beam 510, which is the H-shaped steel load with the citation ring formed, the head of the vertical fixing bolt 522 set in the vertical tube 521 penetrates through the vertical through hole formed in the flange to support the plate. (524) The horizontal hypothesis beam 510 is horizontal in such a manner that it is supported on the upper surface, is adjusted to a desired height using the height adjuster 525, and the vertical fixing bolt 522 is fastened to the horizontal hypothetical beam 510 on the upper surface. Will be set to.

Since two fixed supports 520 are installed, the horizontal hypothesis beam 510 can be stably installed, and it does not matter if the horizontal hypothesis beams 510 are connected to each other in the horizontal direction as shown in FIG. 2C.

At this time, the other end of the horizontal hypothesis beam 510 is extended to the side more than the outermost girder 300. Accordingly, it can be seen that the installation is possible by lifting the protective wall integrated precast cantilever slab 100 and inserting it into the horizontal drainage hole 110 at the other end of the horizontal hypothesis beam 510.

Thus, as shown in Figure 3c, lifting the protective wall-integrated precast cantilever slab 100 and inserting it into the horizontal drain hole 110 at the other end of the horizontal hypothesis beam 510 while using the mounting nut 400 and also the protective wall-integrated free It can be seen that the cast cantilever slab 100 can also be installed in accordance with the upper flange ends of the outermost girders 300 and 300a.

Thus, four girders (300, 300a) are installed, so four fixed supports (520) are installed, and the horizontal hypothesis beam (510) is horizontally set on two fixed supports (520), and the outermost side girders (300a). It can be seen that the protection wall-integrated precast cantilever slab 100 is supported and installed on the horizontal hypothesis beam 510 in such a manner that each is horizontally inserted.

Next, as shown in FIG. 3B, a vertical drain pipe is connected to the horizontal drain hole 110 of the protective wall-integrated precast cantilever slab 100, and the slab finish 600 is blown out to the upper surface of the vertical pipe 521. It is filled with (S) to finish.

Since the height of the vertical tube 521 is aligned with the upper surface height of the protective wall-integrated precast cantilever slab 100 and the precast slab 200, the slab finishing material 600 may be filled up to the upper surface of the vertical tube 521.

Thus, as shown in Figure 3d, when the slab finish 600 is finally cured, the girder 300, the integrated precast cantilever slab 100, and the precast slab 200 are structurally integrated with each other, and these operations are sequentially performed on the bridge. It proceeds according to the extension length, and only a part of the fixed support 520 is sacrificed and the horizontal hypothesis beam 510 is recovered.

That is, unlike the inside of the vertical tube 521 of the fixed support 520, since the slab finish 600 is not filled, the horizontal hypothesis beam 510 is protected by releasing the height adjustment tool 525 on the vertical fixing bolt 522. The vertical pipe 521 in which the final internal fastener 523 is accommodated by collecting and recovering while removing it from the horizontal drain hole 110 of the integral precast cantilever slab 100 and also supporting plate 524 and vertical fixing bolt 522 together. ),, Only the mounting nut 400 is sacrificed in a manner that is embedded in the slab finishing material.

As a result, it is possible to complete the bridge slab (A) by finishing the interior of the vertical pipe 521 with final concrete.

Furthermore, as shown in Figure 2d, when the temporary support 500 is to be hung on the end of the protective wall integrated precast cantilever slab 100, not shown,

Installing a precast slab 200 between the girder and the upper flange of the girder; A horizontal hypothesis beam 510 extending horizontally in a transverse direction so that one end is hung at an end of the protective wall integrated precast cantilever slab 100; And a protective wall integral type precast cantilever slab 100 fixed to the upper surface of the girder 300 at the other end or the middle of the horizontal hypothesis beam 510 to resist conduction by bending moment acting on the horizontal hypothesis beam 510. Installing a temporary support 500 including a vertical support 520 for restraining the upper surface of the girder upper flange; And a step of installing the protective wall-integrated precast cantilever slab 100 so as to be supported on the outermost girder so that one end is hung at the end of the protective wall-integrated precast cantilever slab 100. Bridge slab can be constructed.

The above description of the present invention is for illustration only, and those skilled in the art to which the present invention pertains can understand that it can be easily modified to other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims rather than the above detailed description, and it should be interpreted that all changes or modified forms derived from the meaning and scope of the claims and equivalent concepts thereof are included in the scope of the present invention. do.

100: all-wall precast cantilever slab
110: horizontal drain hole
200: precast slab
300: girder 300a: outermost girder
310: upper flange
400: Mounting nut 410: Cylindrical sleeve
4520: eccentric fastening hole 430: eccentric bolt
500: temporary support 510: horizontal hypothesis beam
511: lifting hook 520: vertical support
521: vertical tube 522: vertical fixing bolt
523: internal fastener 524: support plate
525: height adjustment device 600: slab finish
A: Bridge slab B: Upper flange end

Claims (10)

A horizontal hypothesis beam 510 horizontally extended in a horizontal direction so that one side end is inserted into the horizontal drain hole 110 of the protective wall integrated precast cantilever slab 100; And a horizontal hypothesis beam 510 fixed to the upper surface of the girder 300,300a at the other end or the middle of the horizontal hypothesis beam 510 in order to resist conduction by the bending moment acting on the integrated precast cantilever slab 100. Vertical support (520) for restraining; by installing a protective wall integral precast cantilever slab (100) on the outermost girder (300a) using; girder (300,300a), protective wall integral type The precast cantilever slab 100 is constructed to be integrated with each other,
A slab concrete (C) or a slab finishing material (600) is placed in the blotted-out space (S) between the sidewalls of the precast cantilever slab (100) and the precast slab (200) and the top of the girder (300,300a). Bridge slab made of integrated precast cantilever slab. A horizontal hypothesis beam 510 horizontally extended in a transverse direction so that one side end is hung on the upper surface of the protective wall integrated precast cantilever slab 100; And a horizontal hypothesis beam 510 fixed to the upper surface of the girder 300,300a at the other end or the middle of the horizontal hypothesis beam 510 in order to resist conduction by the bending moment acting on the integrated precast cantilever slab 100. Vertical support (520) for restraining; by installing a protective wall integral precast cantilever slab (100) on the outermost girder (300a) using; girder (300,300a), protective wall integral type The precast cantilever slab 100 is constructed to be integrated with each other,
A slab concrete (C) or a slab finishing material (600) is placed in the blotted-out space (S) between the sidewalls of the precast cantilever slab (100) and the precast slab (200) and the top of the girder (300,300a). Bridge slab made of integrated precast cantilever slab. The method according to claim 1 or 2,
A precast slab 200 is further installed between the girder 300 and the upper flange of the girder 300, and is blotted out between the precast slab 200 and the side of the precast slab 200 and the upper side of the girder upper flange. A bridge slab made of a protective wall-integrated precast cantilever slab in which a slab concrete (C) or a slab finishing material 600 is placed in the space S to integrate the girder 300 and the precast slab 200 together. The method according to claim 1 or 2,
The protective wall integrated precast cantilever slab 100 and the side of the precast slab 200 are formed with a step so that the waterproof performance is improved as the flow path increases, and the contact area with the slab finishing material 600 or the slab concrete (C) A bridge slab made of a precast cantilever slab integrated with a protective wall that ensures integrity due to the increase. The method according to claim 1 or 2,
The horizontal hypothesis beam 510 uses an H-type steel beam, but uses a lifting hook 511 for installation on the upper surface,
The vertical support 520
The girder (300,300a) is fixed to the upper surface so as to extend vertically upward, but at least to have a height corresponding to the thickness of the bridge slab, the inner bottom vertical tube 521 for receiving the inner fastener 523 as a fastening nut; And the lower end is fastened to the inner fastener 523 fastened to the inside of the lower end of the vertical tube 521 so as to be able to penetrate the horizontal hypothetical beam 510 vertically to fix the head on the horizontal hypothetical beam 510. A bridge slab made of a protective wall-integrated precast cantilever slab, including; a vertical fixing bolt 522 formed so that the horizontal hypothesis beam 510 can be fixed in the upper space of the girder (300, 300a). The method of claim 5,
Located on the bottom surface of the horizontal hypothesis beam 510 so that the vertical fixing bolt 522 penetrates, and on the bottom surface of the support plate 524, a height adjusting mechanism 525 is fastened to the outer peripheral surface of the vertical fixing bolt 522, A bridge slab made of a protective wall integrated precast cantilever slab that allows the height adjuster 525 to rotate to adjust the height of the support plate 524. The method according to claim 1 or 2,
Using the mounting nut 400, the protective wall integral precast cantilever slab 100 or the precast slab 200 is installed in accordance with the end B of the upper flange 310 of the girder 300,300a, and the mounting nut 400 is
One side of the eccentric bolt 430 is fastened to the cylindrical sleeve 410, and the other side is fixed to the bottom side of the protective wall integrated precast cantilever slab 100 or the precast slab 200, so that the cylindrical sleeve 410 As the rotation, the height of the top surface of the cylindrical sleeve 410 by the eccentric fastening hole 420 causes a difference to occur with rotation,
While rotating the cylindrical sleeve 410 so that the cylindrical sleeve 410 is in contact with the upper surface of the upper flange 310 of the girder, the position of the protective wall integrated precast cantilever slab 100 or the precast slab 200 is lifted ( A bridge slab made of a precast cantilever slab integrated with a protective wall that facilitates finishing of the end when slab concrete is placed in conformity with the end (B) of the upper flange 310 of 300). (a) installing a precast slab 200 between the girder and the upper flange of the girder;
(b) a horizontal hypothesis beam 510 extending horizontally in a horizontal direction so that one end is inserted into the horizontal drain hole 110 of the protective wall integrated precast cantilever slab 100; And a horizontal hypothesis beam 510 which is fixed to the upper surface of the girder 300,300a at the other end or the middle of the horizontal hypothesis beam 510 in order to resist conduction by a bending moment acting on the integrated precast cantilever slab 100. Installing a temporary support 500 including a vertical support 520 for constraining the upper surface of the girder upper flange; And
(c) One side end of the horizontal hypothesis beam 510 is inserted into the horizontal drainage hole 110 of the protective wall integrated precast cantilever slab 100 to support the protective wall integrated precast cantilever slab 100 to the outermost girder. A method of constructing a bridge slab made of a precast cantilever slab integrated with a protective wall, including a step of installing as much as possible. (a) installing a precast slab 200 between the girder and the upper flange of the girder;
(b) a horizontal hypothesis beam 510 which is horizontally extended in a transverse direction so that one end is hung at an end of the protective wall integrated precast cantilever slab 100; And a horizontal hypothesis beam 510 fixed to the upper surface of the girder 300,300a at the other end or the middle of the horizontal hypothesis beam 510 in order to resist conduction by the bending moment acting on the integrated precast cantilever slab 100. Installing a temporary support 500 including a vertical support 520 for constraining the upper surface of the girder upper flange; And
(c) installing a protective wall-integrated precast cantilever slab 100 so as to be supported on an outermost girder so that one end is hung at an end of the protective wall-integrated precast cantilever slab 100; Bridge slab construction method. The method of claim 8 or 9,
After the step (c), the slab concrete (C) in the blotted-out space (S) of the upper side of the upper flange of the girder (300,300a) between the side of the protective wall integrated precast cantilever slab 100 and the precast slab 200 Or a method of constructing a bridge slab made of a precast cantilever slab integrated with a protective wall further comprising the step of pouring the slab finishing material (600).

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