KR102689719B1 - Concrete slab with end drain block for precast and construction method therefor - Google Patents

Abstract

After mounting the girder on the bridge substructure and mounting the precast slab, a water break ledge is integrally formed on the side of the precast slab, an additional precast water break block is installed on the upper surface of the water break slab, and then the precast water break is installed. This is about a precast slab using water break blocks and its construction method for constructing a bridge slab by connecting and integrating a protective wall to the break blocks. The precast slab using water break blocks is a precast that is combined with an integrated water break block. The water-cutting blocks are integrated to serve as a water-cutting means.

Description

Precast slab using water break blocks and its construction method {CONCRETE SLAB WITH END DRAIN BLOCK FOR PRECAST AND CONSTRUCTION METHOD THEREFOR}

The present invention relates to a precast slab using a water break block. More specifically, after mounting the precast slab on the bridge substructure, an integrated water-cutting block is formed on the side of the precast slab, an additional precast water-cutting block is installed on the upper surface of the integrated water-cutting block, and then the precast water-cutting block is installed. This relates to a precast slab using water-cutting blocks and its construction method, which constructs a bridge slab by integrating a precast protective wall into the block.

Figure 1a is a schematic diagram of a bridge construction using a conventional precast slab.

First, the steel girders (13) are spaced apart from each other in the horizontal direction, and precast slabs (11A, 11B) extending in the horizontal direction are installed on the upper surface of the steel girder.

The Pkicast slabs (11A, 11B) extend laterally to protrude laterally via the two most lateral steel girders, and in the longitudinal direction, the longitudinal connecting reinforcing bars (12) overlap each other to form a filler containing non-shrinkage mortar. Connect the precast slabs (11A, 11B) longitudinally using (G),

The pocket hole 15 formed in the precast slab accommodates the shear connector 14 on the upper surface of the steel girder 13, and the precast slab 11A, 11B is formed using a filler (not shown) containing non-shrinkage mortar. ) and steel girders (13, 14) are integrated.

Figure 1b is an exemplary view of a conventional waterproof sill formwork construction.

It can be seen that the waterproof ledge 20 is, for example, integrated with a block body on the upper surface of the slab 21 of a bridge to form a waterproof ledge by the block body, thereby preventing stagnation of running water by the waterproof ledge.

According to FIG. 1b, the waterproof sill 20 is made by first setting the water sill formwork before pouring the slab concrete on the upper surface of the slab 21 of the bridge, and then pouring the slab concrete 23 inside the water sill formwork. It can be seen that the bridge slab 21 and the waterproof sill 20 can be formed integrally, and the water sill formwork is a steel formwork and includes both side forms 24.

Figures 1c and 1d are illustrations of conventional precast protective wall construction.

That is, according to FIG. 1C, a concrete protective wall 32 is usually additionally installed on the lateral upper surface of the slab 31 of the bridge, and the concrete protective wall 32 is manufactured using a precast method and is fixed and installed on the upper surface of the slab 31. I do it.

This precast protective wall 32 has a hollow portion 34 formed inside to reduce weight, and the slab 31 and the concrete protective wall 32 of the bridge are formed by injecting filler (G) into this hollow portion. ) It can be seen that a method of integrating can be used.

At this time, a separate waterproof ledge is not installed, but the drain pipe 33 is installed to penetrate the slab 31 of the bridge at the area where the bottom of the precast protective wall 32 is located,

It can be seen that the running water may be drained into the space under the bridge through the drain pipe 33 through the gap in the bottom of the precast protective wall.

In this case, if running water accumulates in the lower part of the precast protective wall 32, it becomes a factor in deteriorating the durability of the bridge slab 31.

Furthermore, according to FIG. 1D, when installing the precast protective wall 32 on the upper surface of the bridge slab 31, the outer wall 35 of the precast protective wall is directed downward via the end surface E rather than the upper surface of the bridge slab. It can also be seen that one manufactured to extend can be used, and in this case, it can be seen that the drain pipe 33 is not installed separately.

However, due to the recent spraying of snow removal agents, it is directed to the extreme side of the bridge slab and in the process of being drained by the precast protective wall, the post-cast protective wall or precast protective wall is deteriorated, causing a problem of accelerated deterioration of the durability of the bridge slab, leading to a collapse accident. There was a problem that something like this could happen.

Republic of Korea Patent No. 10-1993-0015603 (Title of invention: Waterproof jaw formwork, Publication date: March 20, 1995) Republic of Korea Patent No. 10-2453839 (Title of invention: Bridge protective wall structure using precast protective wall members, Publication date: October 14, 2022)

Accordingly, in the present invention, when manufacturing a precast slab, a waterproof ledge is manufactured in advance, but the drain pipe is positioned away from the waterproof ledge to handle drainage such as running water, and a water-cutting block is additionally installed on the waterproof ledge, thereby forming a waterproof ledge. The problem is to provide a precast slab using a water cutoff block that can drain rainwater to the outside and lower side of the bridge even through the water cutoff block while reinforcing the water cutoff block.

In addition, the present invention secures the installation space for the precast protective wall by placing a precast protective wall on the upper surface of the water cutoff block, and drains rainwater along the precast protective wall to the outside and lower side of the bridge along the water cutoff block. The problem to be solved is to provide a precast slab using possible water-blocking blocks and its construction method.

The precast slab using the water cutting block of the present invention to achieve the above problem is,

A concrete block that is integrally formed to protrude from the lateral upper surface when manufacturing a concrete horizontal plate, and is formed on the upper surface so that the water-breaking block connecting rebar is drawn out; an integrated water-blocking block; And the vertical block extends downward while contacting the integrated water break block and the horizontal end surface of the concrete horizontal plate, and the horizontal block, which is formed in a direction perpendicular to the vertical block and has internal connecting reinforcing bars drawn out horizontally, is the upper surface of the integrated water break block. A precast water-cutting block that is placed on the water-cutting block connecting reinforcing bars and internal connecting reinforcing bars and is coupled to the integrated water-cutting block. Including, the integrated water-cutting block and the precast water-cutting block are integrated. It will serve as a means to cut off water.

The precast slab construction method using the water-cutting block capable of drainage treatment of the present invention to achieve the above problem is,

(a) After manufacturing the bridge girder, constructing the bridge girder on the abutment and pier, manufacturing a precast slab using an integrated water break block, bringing it to the site, and combining it with the bridge girder; And (b) connecting the precast slab using water break blocks in the longitudinal direction using water break block longitudinal connecting bars, and additionally installing a precast protective wall to complete the bridge, including (a) ) A precast slab using an integrated water-cutting block is a concrete block formed to protrude from the upper side of the concrete horizontal plate as a whole when manufacturing a concrete horizontal plate. And the vertical block extends downward while contacting the integrated water break block and the horizontal end surface of the concrete horizontal plate, and the horizontal block, which is formed in a direction perpendicular to the vertical block and has internal connecting reinforcing bars drawn out horizontally, is an integrated water break block. A precast water cutting block that is placed on the upper surface of the block and is coupled to the integrated water cutting block by connecting the water cutting block connecting bars and internal connecting bars to each other, including the integrated water cutting block and the precast water cutting block. It is integrated and serves as a means to cut off water.

According to the present invention, the water-cutting block is manufactured integrally with the precast slab, and the high-strength integrated water-cutting block can effectively prevent deterioration due to snow removal agents, etc., thereby ensuring durability, and in addition to the integrated water-cutting block. By connecting and installing precast water break blocks, rainwater can naturally drain to the outside into the lower space of the bridge, making it possible to provide a precast slab using water break blocks that can secure the durability of the precast slab more effectively and its construction method.

According to the present invention, a drain pipe is formed in the precast slab, spaced apart from the integrated water cut-off block, so that running water, etc. can be drained into the lower space of the bridge through the drain pipe, thereby improving the drainage effect of the integrated water cut-off block and the precast water cut-off block. It is possible to provide a precast slab and its construction method using a water-blocking block.

According to the present invention, the longitudinal connecting reinforcing bars of the precast slab are placed inside the integrated water breaking block, so that the connection performance by the longitudinal connecting reinforcing bars through the inside of the precast slab can be more effectively secured using the water breaking block. It becomes possible to provide cast slabs and their construction methods.

Figure 1a is a schematic diagram of a bridge construction using a conventional precast slab;
Figure 1b is an example of conventional waterproof jaw formwork construction,
Figures 1C and 1D are examples of conventional precast protective wall construction;
Figure 2a is an example of a precast slab using the water cutting block of the present invention,
Figure 2b is an example of longitudinal connection of a precast slab using a water break block,
Figure 2c is an example of precast water-cutting block installation of a precast slab using a water-cutting block;
Figures 3a and 3b show an example of a precast slab construction method using the water cutting block of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts unrelated to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to “include” a certain element, this means that it may further include other elements rather than excluding other elements, unless specifically stated to the contrary.

[Precast slab (100) using water cutting block of the present invention]

Figures 2a, 2b, and 2c are an example of a precast slab 100 using a water break block of the present invention, an example longitudinal connection of the precast slab 100 using a water break block, and a water break block using a water break block. This is an example of installation of the precast water cutting block (130) of the precast slab (100).

Referring to FIG. 2a, the precast slab 100 using the water-cutting block is in the form of a concrete horizontal plate 110, which is manufactured in advance by precasting, and has an integrated water-cutting block 120 on the lateral upper surface. It is formed.

In addition, referring to Figure 2b, a precast water disconnection block 130 is additionally integrated on the upper surface of the integrated water disconnection block 120, and a precast protective wall 150 is installed on the precast water disconnection block 130. .

Furthermore, referring to FIG. 2C, the precast slab 100 using the water break block is mounted on the bridge girder 200 to extend in the transverse direction, and the water break block longitudinal connecting reinforcing bar 140 and the integrated water break block By connecting them in the longitudinal direction using (120), a precast slab (100) using water cutting blocks is constructed on the bridge girder (200).

For this purpose, referring to FIGS. 2A, 2B and 2C, the precast slab 100 using the water interruption block includes a concrete horizontal plate 110, an integrated water interruption block 120, and a precast water interruption block 130. , the water-cutting block is formed including longitudinal connecting reinforcing bars (140) and a precast protective wall (150).

First, referring to FIG. 2A, the concrete horizontal plate 110 is a concrete horizontal plate formed using concrete using a steel form in advance in a factory using a precast method, and serves as the body of the precast slab.

In other words, it is a size that is easy to manufacture, transport, and mount on a bridge girder, and is made of precast concrete horizontal plates with constant lateral length (L1), longitudinal length (L2), and thickness (T). .

It can be seen that a plurality of pocket holes 111 are formed spaced apart in this concrete horizontal plate 110, and the shear connector 240 extending upward on the upper surface of the bridge girder 200 to be mounted is formed in the pocket hole 111. It is possible to integrate the bridge girder 200 and the concrete horizontal plate 110 by the filler (G) received inside and containing non-shrinking mortar.

In addition, it can be seen that the concrete horizontal plate 110 has a drain pipe 112 formed to penetrate the concrete horizontal plate 110 and is spaced apart from the integrated water cutting block 120.

Accordingly, the running water (rainwater, etc.) according to the lateral gradient of the concrete horizontal plate 110 is first drained into the space under the bridge through the drain pipe 112, so that the integrated water cutoff block 120 allows a relatively small amount of running water to accumulate. This makes it possible to minimize the problem of deterioration of durability of the concrete horizontal plate 110 due to deterioration of the integrated water-cutting block 120.

In addition, the concrete horizontal plate 110 has an irregular thickness of T1 in the transverse direction, and the area in contact with the bridge girder 200 is formed with a thickness of T2 (>>T1).

The rigidity of the concrete horizontal plate 110 can be strengthened by increasing the thickness of the area supported by the bridge girder 200.

Accordingly, there is a change in the installation height of the longitudinal reinforcing bar 113 and the transverse reinforcing bar 114, that is, the concrete horizontal plate 110 with a thickness T2 is greater than the longitudinal internal rebar placed in the concrete horizontal plate 110 with a thickness T1. Since the longitudinal reinforcing bars 113 placed in can be placed lower, longitudinal rigidity can be reinforced with the effect of increasing the distance from the neutral axis,

The advantage is that the transverse reinforcing bars 114, which are reinforced with the concrete horizontal plate 110 of thickness T1 to T2, can also be reinforced slanted further downward from the upper surface of the concrete horizontal plate 110, so that lateral rigidity reinforcement is also possible. You can have .

Next, referring to FIGS. 2A and 2B, the integrated water cutting block 120 is formed integrally together when manufacturing the concrete horizontal plate 110, and is a concrete block protruding from the upper surface of the side of the concrete horizontal plate 110. The flowing water flows in both directions due to the lateral gradient and serves as a means to cut off water to prevent it from pooling toward the bridge girder (200).

Referring to Figure 2a, this integrated water cutting block 120 can be formed to have a certain thickness to match the lateral end surface of the concrete horizontal plate 110, and can also be formed along the longitudinal direction of the concrete horizontal plate 110. It can be seen that it is formed to correspond to the direction length (L2),

It can be formed to be spaced apart from the lateral end surface of the concrete horizontal plate 110.

A drain pipe 112 is formed on the concrete horizontal plate 110, spaced apart from this integrated water-cutting block 120, and a water-cutting block longitudinal connecting rebar 140 is formed on the longitudinal end surface to be drawn out, so that the concrete horizontal plate ( 110) is used for longitudinal connection,

The water-breaking block connecting rebar 123 is drawn out from the upper surface of the integrated water-breaking block 120 and is used to connect the precast water-breaking block.

Next, referring to FIGS. 2a and 2b, the precast water-block (130) is further integrated with the integral water-block (120) using the water-block connecting reinforcing bar (123) to allow water to drain to the outer space of the concrete horizontal plate (110), thereby protecting the concrete horizontal plate (110) more effectively. In other words, it is possible to additionally secure the role of a water-blocking means to prevent water from pooling toward the bridge girder (200).

Accordingly, the above precast water-cutting block (130) is formed in an overall “ㄱ” or “ㅏ” shape, and the internal connecting reinforcing bar (133) is pulled out so that it can be connected to the water-cutting block connecting reinforcing bar (123).

Accordingly, the vertical block 131 extends downward while contacting the integrated water cutting block 120 and the end surface of the concrete horizontal plate 110, and is formed in a direction perpendicular to the head of the vertical block 131, and internal connecting reinforcing bars. As the horizontal block 132, from which (133) is drawn out horizontally, is placed on the upper surface of the integrated water cutting block 120,

The water-cutting block connecting bar (123) and the internal connecting bar (133) are connected to each other, and the precast water-cutting block (130) and the integrated water-cutting block (120) are combined and integrated using filler (G), not shown. Together, they serve as a means of cutting off water.

Furthermore, the precast water break block 130 can be used as an additional anchoring space for the transverse tension member (not shown) drawn toward the end surface of the concrete horizontal plate 110, thereby securing the reinforcement effect of the concrete horizontal plate 110. , it is also desirable to form a hollow part to reduce weight.

At this time, in contrast to the “ㄱ” shape, the “ㅏ” shape can be formed in a shape that allows the horizontal block (132) to extend horizontally at the approximate center of the vertical block (131). Although not shown, the internal connecting reinforcement ( 133) can also be pulled out horizontally from the horizontal subblock 132.

The water cutting block longitudinal connecting reinforcing bar 140 is a reinforcing bar for longitudinal connection of concrete horizontal plates 110 in contact with each other in the longitudinal direction, as shown in FIGS. 2B and 2C,

For example, the integrated water cutting block 120 extends from the inside to the outside and is bent in a semicircle (formed into a loop shape) by the concrete horizontal plate 110,

In a state in which the ends are treated as horizontal connecting reinforcing bars with expansion head reinforcing bars so that the longitudinal connecting reinforcing bars (140) of the water cutting block overlap each other or are connected using expansion head reinforcing bars and couplers,

Transverse connecting reinforcing bars 142 are additionally reinforced at the longitudinal joint 141 of the concrete horizontal plate 110, and the longitudinal joint 141 is finished with filler (G) to form a concrete horizontal plate ( 110) can be integrated.

As shown in FIGS. 2A and 2C, the precast protective wall 150 is a concrete protective wall installed on the upper surface of the precast water blocking block 130 using fasteners such as anchors, and is manufactured using a precast method. .

In the case of the present invention, since it is fastened and fixed to the upper surface of the precast water cut-off block 130 separately from the integrated water cut-off block 120, the possibility of deterioration is minimized because water stagnation due to running water is hardly encountered, so the precast protective wall 150 Together with this, it becomes more effective in securing the durability of the concrete horizontal plate 110.

This precast protective wall 150 can be modified in shape, such as forming a soundproof wall foundation (soundproof wall foundation) built on a bridge at the bottom, and this will be referred to as a precast protective wall 150 including a soundproof wall foundation. .

[Precast slab (100) construction method using the water cutting block of the present invention]

Figures 3a and 3b are illustrations of a method of constructing a precast slab 100 using the water cutting block of the present invention.

Referring to FIGS. 3A and 3B, the method of constructing the precast slab (100) using the water cutting block is constructed by mounting the bridge girder (200) on the abutment and pier, which are the bridge substructure, but separately at a factory, etc. A precast slab (100) using an integrated water cutting block (120) is manufactured and brought to the site,

It is placed on the mounted bridge girder (200) and installed on the bridge girder (200), and the precast water disconnection block (130) is installed on the integrated water disconnection block (120), or the precast water disconnection block (130) is installed on the bridge girder (200). It can be installed in advance on the integrated water cutoff block (120) and then installed on the bridge girder (200). After connecting the precast slab in the longitudinal direction,

It can be said to be a method of constructing a bridge by finally installing the precast protective wall 150 on the precast water blocking block 130.

Accordingly, according to FIG. 3a, after manufacturing the bridge girder 200 on site, the bridge girder 200 is constructed on the abutment and pier 300, and the precast slab 100 using water cutting blocks is manufactured. It is brought to the site and coupled to the bridge girder (200).

The abutments and piers 300, which are the bridge substructure, can usually be constructed using reinforced concrete.

The bridge girder 200 is, for example, an I-type steel girder and is composed of an upper flange, an upper flange, and a lower flange. A shear connector 240 is formed on the upper surface of the upper flange, and the bridge girder is formed using the shear connector 240. (200) and the precast slab (100) using the water cutting block of the present invention are integrated with each other.

At this time, it can be seen that the precast slab using the water break block is formed integrally with the water break block 120 integrated into the concrete horizontal plate 110, and the water break block longitudinal connecting reinforcing bar 140 seen above is additionally formed.

For this purpose, it can be seen that a plurality of pocket holes 111 are formed spaced apart from the concrete horizontal plate 110, and it can be seen that the drain pipe 112 is formed spaced apart from the integrated water cutoff block 120.

In addition, the integrated water-cutting block 120 is a concrete block protruding from the upper surface of the side of the concrete horizontal plate 110 and is integrally formed to serve as a water-cutting means to primarily solve the problem of water stagnation.

According to Figure 3a, for example, a precast slab 100 using a water break block in which a plurality of integrated water break blocks 120 and water break block longitudinal connecting reinforcing bars 140 are formed on the upper surface of four bridge girders 200. It can be seen that the bridge girders 200 are extended and supported on the bridge girders 200 extending laterally and longitudinally, and are set to be connected to each other in the longitudinal direction.

In addition, in the precast slab 100 using a water-cutting block, the precast water-cutting block 130 is integrally connected to the integrated water-cutting block 120 in advance or at the site.

At this time, the precast water breaking block 130 is formed overall in an “ㄱ” or “ㅏ” shape, and the internal connecting reinforcing bar 133 is drawn out so that it can be connected to the water breaking block connecting reinforcing bar 123, The vertical block 131 and the horizontal block 132 are formed integrally.

In this way, the water-cutting block connecting reinforcing bar 123 and the internal connecting reinforcing bar 133 are connected to each other, and the precast water-cutting block 130 and the integrated water-breaking block 120 are connected to each other using a filler (G), not shown. By integrating it, it is possible to secondarily solve the problem of durability deterioration due to water stagnation.

Next, according to FIG. 3b, the precast slab 100 using the water break block is connected in the longitudinal direction using the water break block longitudinal connecting reinforcing bar 140, and a precast protective wall 150 is additionally installed. The bridge is completed.

Referring to FIG. 2C, the water cutting block longitudinal connecting reinforcing bar 140 is a reinforcing bar for longitudinal connection of concrete horizontal plates 110 in contact with each other in the longitudinal direction and extends from the inside of the integrated water breaking block 120 to the outside to connect the concrete. The horizontal plate 110 is bent into a semicircle (formed into a loop shape), or

It can be seen that the ends are made of expanded head reinforcing bars and treated as horizontal connecting reinforcing bars so that the longitudinal connecting reinforcing bars 140 of the water cutting block overlap each other or are formed in a state in which the expanded head reinforcing bars are connected using a coupler.

Accordingly, transverse connecting reinforcing bars 142 are additionally reinforced at the longitudinal joint 141 of the concrete horizontal plate 110, and the longitudinal joint 141 is finished with filler (G) to form concrete horizontal plates that contact each other in the direction. It can be seen that (110) can be integrated.

Next, the bridge is completed by installing a precast protective wall (150) on the precast water cutting block (130) connected to the upper surface of the integrated water cutting block (120) integrated with the concrete horizontal plate (110), and the precast protective wall (150) may utilize a precast barrier containing a sound barrier foundation.

In addition, the precast protective wall 150 or the precast protective wall 150 including the soundproof wall foundation is a concrete protective wall installed on the precast water blocking block 130 using fasteners such as anchors.

Accordingly, the final bridge slab construction can be completed in the same manner as additionally constructing a pavement layer on the final concrete horizontal plate 110.

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

The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

100: Precast slab using water break blocks
110: Concrete horizontal plate
111: pocket hole 112: drain pipe
113: longitudinal rebar 114: transverse rebar
120: Integrated water disconnection block 123: Water disconnection block connecting rebar
130: Precast water cutting block 131: Vertical block
132: Horizontal block 133: Internal connecting rebar
140: Water cutting block longitudinal connection rebar
141: longitudinal joint 142: transverse connecting rebar
150: Precast protective wall 200: Bridge girder
240: Shear connector 300: Abutment, pier
G: Filler

Claims (7)

When manufacturing the concrete horizontal plate 110, a concrete block is integrally formed to protrude from the upper surface of the side, and an integrated water cutting block 120 is formed so that the water cutting block connecting reinforcing bar 123 is drawn out from the upper surface; And the vertical block 131 extends downward while contacting the integrated water cutting block 120 and the transverse end surface of the concrete horizontal plate 110, and is formed in a direction perpendicular to the vertical block 131 and includes internal connecting reinforcing bars. The horizontal block 132, from which (133) is drawn out horizontally, is placed on the upper surface of the integrated water-cutting block 120, and the water-cutting block connecting rebar 123 and the internal connecting rebar 133 are connected to each other to form an integrated water-cutting block. Including a precast water-cutting block 130 coupled to the block 120, wherein the integrated water-cutting block 120 and the precast water-cutting block 130 are integrated to serve as a water-cutting means. Precast slab using blocks. According to paragraph 1,
The concrete horizontal plate 110 is a precast concrete horizontal plate,
A plurality of pocket holes 111 are formed to be spaced apart, so that the shear connector 240 extending upward on the upper surface of the bridge girder 200 to be mounted is received inside the pocket hole 111, thereby forming the bridge by the filler (G). A water-cutting block is provided so that the girder 200 and the concrete horizontal plate 110 are integrated, and the drain pipe 112 formed to penetrate the concrete horizontal plate 110 is formed spaced apart from the integrated water-cutting block 120. Precast slab used. According to paragraph 1,
As a reinforcing bar for longitudinal connection of concrete horizontal plates 110 in contact with each other in the longitudinal direction,
The integrated water-cutting block (120) extends from the inside to the outside and is bent in a semicircle (formed into a loop shape) by the concrete horizontal plate (110), or the end is treated as a horizontal connecting rebar with an expanded head rebar to form a longitudinal connecting rebar for the water-cutting block. With (140) overlapping each other or connected using expansion head rebar and coupler,
Transverse connecting reinforcing bars 142 are additionally reinforced at the longitudinal joint 141 of the concrete horizontal plate 110, and the longitudinal joint 141 is finished with filler (G) to form concrete that contacts each other longitudinally. A precast slab using a water break block further including a water break block longitudinal connecting rebar (140) that integrates the horizontal plate (110). According to paragraph 1,
A concrete protective wall additionally installed on the upper surface of the precast water-cutting block 130 using a water-cutting block further comprising a precast protective wall 150 manufactured by a precast method or a precast protective wall 150 including a soundproof wall foundation. Precast slab. (a) After manufacturing the bridge girder 200, construct the bridge girder 200 on the abutment and pier 300, and manufacture the precast slab 100 using the integrated water cutting block 120. Bringing it to the site and coupling it to the bridge girder (200); and
(b) A precast slab (100) using a water-cutting block is connected in the longitudinal direction using a water-cutting block longitudinal connecting rebar (140), and a precast protective wall (150) including a precast protective wall or soundproof wall foundation is installed. It includes the step of completing the bridge by additional installation,
The precast slab 100 using the integrated water cutting block 120 in step (a),
When manufacturing the concrete horizontal plate 110, a concrete block is integrally formed to protrude from the upper surface of the side, and an integrated water cutting block 120 is formed on the upper surface so that the water cutting block connecting reinforcing bar 123 is drawn out; And the vertical block 131 extends downward while contacting the integrated water cutting block 120 and the transverse end surface of the concrete horizontal plate 110, and is formed in a direction perpendicular to the vertical block 131 and includes internal connecting reinforcing bars. The horizontal block 132, from which (133) is drawn out horizontally, is placed on the upper surface of the integrated water-cutting block 120, and the water-cutting block connecting rebar 123 and the internal connecting rebar 133 are connected to each other to form an integrated water-cutting block. A water-cutting block that serves as a water-cutting means by integrating the integrated water-cutting block 120 and the precast water-cutting block 130, including a precast water-cutting block 130 coupled to the block 120. Precast slab construction method using . According to clause 5,
The precast slab 100 using the integrated water cutting block 120 in step (a),
As a reinforcing bar for longitudinal connection of concrete horizontal plates 110 that contact each other in the longitudinal direction, it extends from the inside of the integrated water cutting block 120 to the outside and is bent in a semicircle (formed into a loop shape) by the concrete horizontal plate 110. In a state in which the ends are treated as horizontal connecting reinforcing bars with expanded head reinforcing bars so that the longitudinal connecting reinforcing bars (140) of the water cutting block overlap each other or are connected using expansion head reinforcing bars and couplers, the longitudinal connection of the concrete horizontal plate (110) Transverse connecting reinforcing bars 142 are additionally reinforced at the directional joint 141, and the longitudinal joint 141 is finished with filler (G) to integrate the concrete horizontal plates 110 that are in longitudinal contact with each other in the direction. A precast slab construction method using a water break block further including water break block longitudinal connecting reinforcing bars (140). According to clause 5,
The concrete horizontal plate 110 has an irregular thickness of T1 in the transverse direction, and the area in contact with the bridge girder 200 is formed with a thickness of T2 (>>T1), so that the concrete horizontal plate 110 with a thickness of T2 is formed. ) It is possible to reinforce longitudinal rigidity by allowing the longitudinal reinforcing bars (113) placed in the lower to be placed lower, and the transverse reinforcing bars (114) reinforced from the concrete horizontal plate (110) of thickness T1 to thickness T2. A precast slab construction method using water break blocks that allows reinforcement to be inclined further downward from the upper surface of the concrete horizontal plate (110), thereby enabling lateral rigidity reinforcement.