KR20160063300A - Precast concrete haunch blocks and it's bridge upper structure construction methods - Google Patents

Abstract

The present invention relates to a precast concrete haunch block which simplifies construction performance in a construction site, reduces construction costs, and improves the durability thereof, and a construction method of a bridge upper structure using the same. To achieve this, the precast concrete haunch block comprises: wall parts which have a certain thickness and a certain width and are arranged to face each other; a bottom plate which is formed by crossing the gap between the tops of the wall parts to be integrated; multiple steel connecting members which are formed on the outer side of the wall parts at uniform intervals and are partially embedded in the wall parts; and a deck plate which is partially embedded in the bottom plate while protruding upward.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a precast concrete block,

The present invention relates to a precast concrete hatch block and a method of constructing a bridge overhead structure using the same. More particularly, the present invention relates to a concrete hatch block for increasing rigidity and a precast concrete hatch block for constructing the bridge, And a method of constructing the upper structure.

Generally, the method of increasing the compression resistance of the upper flange during the construction of the bottom plate slab in steel girder is to increase the amount of steel of the upper flange or to increase the compression resistance of the upper flange by appropriately synthesizing the concrete.

In this case, the method of increasing the amount of steel material of the upper flange of electrons is not used as a method which does not consider economical efficiency. The method of synthesizing the latter concrete to the upper flange of the steel girder is, The method of synthesizing concrete is difficult because it is not universally applied.

In order to solve the above problems, Japanese Patent No. 10-0869568 has proposed an open-form composite concrete steel girder and a method of manufacturing the same.

As shown in FIGS. 1A to 1C, the conventional open type steel composite concrete steel girder is composed of a lateral side steel member 21 having a wide upper side and a narrow bottom side and being welded to the lower side of the side side steel member 21, An opening-shaped steel girder 20 provided with a U-shaped steel material 23 or an L-shaped steel material 25 on the upper side of the side steel material 21; A reinforced concrete reinforced concrete reinforced concrete reinforced concrete steel girder 30 provided with an open section concrete 24 with reinforced concrete and concrete laid thereon and an L-shaped steel material 25 installed facing the upper side of the lateral steel material 21 A reinforcing bar is disposed in a space between the L-shaped steel plates, a fixing hole 13 is provided at both ends in the longitudinal direction, a PS steel wire 12 is connected to a fixing hole provided at both ends, The concrete with the closed end 43 introduced with a prestress by introducing a tensile force into the PS steel wire, Reinforced steel is placed on the inner surface of the side steel member 21 and the bottom steel member 22 of the opening forming steel girder 20 and concrete is installed to simultaneously install the abdomen 41 and the floor concrete 42, A composite concrete reinforced concrete steel girder 40 in which an end finished steel plate 44 is provided at both ends of the abdomen and bottom concrete and each of the steel girders 30 and 40 manufactured as described above is subjected to a bending moment (30) are installed on both sides where the longitudinal moment is generated according to the distribution diagram, and a concrete moment steel concrete girder (40) is installed in the central section where the moment is generated. , And these are jointed to each other by welding or bolt-nuts, and are composite concrete steel girders (10).

In the conventional method of making a steel composite concrete steel girder having an open form, the lateral steel member 21 is provided on both sides of the lower portion narrowly and the bottom steel member 22 is welded to the lower portion of the lateral steel member 21. [ And a U-shaped steel material 23 or an L-shaped steel material 25 is provided on the upper side of the side steel material 21 to fabricate an opening-formed steel material girder 20, (22), and an open section concrete (24) is installed by installing concrete on the upper side of the installed side steel material (21). An L-shaped steel material 25, a fixing port 13 is provided at both ends in the longitudinal direction of the girder 20, a PS steel wire 12 is connected to a fixing port provided at both ends of the girder 20, concrete is laid , A tensioning force is applied to the PS steel wire, A reinforcement is placed on the inner surface of the side steel member 21 of the opening forming steel girder 20 and the bottom steel member 22 and the concrete is laid on the inside surface of the opening forming steel girder 20 so that the abdomen 41 and the bottom concrete 42 are simultaneously And the end portion finished steel plate 44 is installed at both ends of the installed abdomen and floor concrete. The composite concrete reinforced concrete steel girder 40 is fabricated, and each of the steel girders 30, (30) are provided on both sides where the longitudinal moment is generated according to the distribution curve in which the bending moment occurs, and in the central section where the moment is generated, a tensile strength of the tensile strength of the concrete specimen (40) are assembled and then assembled with each other by welding or bolt nuts, thereby manufacturing an open-ended steel composite concrete steel girder (10).

The conventional open-form composite concrete steel girder having a structure as described above and a method of manufacturing the same provide a method of increasing the rigidity of the upper flange of the steel girder by synthesizing a concrete upper casing with the upper flange of the steel girder. It is difficult to apply it universally even though the construction is complicated and difficult because of the applicability of the concrete upper casing due to the installation in the field.

Therefore, it is urgently required to develop a construction method and structure that can increase the rigidity of the upper flange of the steel girder while simplifying the workability in the field.

Patent No. 10-0869568 (Registration date November 13, 2008)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a precast concrete which is simple in site construction, low in construction cost, excellent in durability, And a method of constructing a bridge overhead structure using the same.

According to an aspect of the present invention, there is provided a precast concrete hunting block comprising: a wall portion having a predetermined thickness and width and disposed to face each other; A bottom plate integrally formed across an upper portion of the wall portion; A connecting steel member which is embedded in a predetermined portion of the wall portion while maintaining a predetermined distance therebetween; And a deck plate protruding upwardly at a predetermined portion of the bottom plate. The wall portion and the bottom plate are integrally formed of an inverted U-shaped or Z-shaped reinforced concrete as a whole, and are symmetrically or asymmetrically formed And a cut-out portion having a predetermined shape is formed at an outer lower end of the steel girder, and the cut-out portion is formed for tightly coupling the wall portion to the upper flange of the steel girder. The width of the cut-out portion extending over the upper flange is formed to be 1/2 of the width of the wall portion, and a plurality of the connecting steel members are arranged on the outer side of the wall portion, A loop reinforcement partially embedded in the form of a wrapping around a shear connector coupled to an upper flange, A truss root of a triangular shape, a square shape and a shaping shape is welded on a corrugated steel plate, and a cast iron muscle is welded in the longitudinal direction on the truss muscle. .

In order to accomplish the above object, there is provided a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention, comprising: a wall part having a predetermined thickness and width at a factory or a site; A bottom plate integrally formed across an upper portion of the wall portion; A connecting steel member which is embedded in a predetermined portion of the wall portion while maintaining a predetermined distance therebetween; And a deck plate protruding upwardly at a predetermined portion of the bottom plate. The wall portion and the bottom plate are integrally formed of an inverted U-shaped or Z-shaped reinforced concrete as a whole, and are symmetrically or asymmetrically formed And a cut-out portion having a predetermined shape is formed at an outer lower end of the steel girder, and the cut-out portion is formed for tightly coupling the wall portion to the upper flange of the steel girder. The width of the cut-out portion extending over the upper flange is formed to be 1/2 of the width of the wall portion, and a plurality of the connecting steel members are arranged on the outer side of the wall portion, A loop reinforcement partially embedded in the form of a wrapping around a shear connector coupled to an upper flange, And a truss root of a triangular shape, a quadrangular shape, and a shaping shape is welded on the corrugated steel plate, and a precast is welded on the truss root in a longitudinal direction, Making a concrete hunting block; Mounting a steel girder on the pre-installed alternating and piercing; Mounting a precast concrete hunting block over the entire upper flange of the steel girder; Placing and curing concrete in the precast concrete hunting block to synthesize an upper flange and a precast concrete hunting block of the steel girder; And placing and curing concrete on the top surface of the precast concrete hunting block to form a slab.

As described above, the precast concrete hatch block according to the present invention and the method of constructing a bridge overhead structure using the precast concrete block have the following effects.

First, the present invention has an advantage that the concrete hunting block for increasing the upper flange compression resistance can be installed economically and efficiently on the upper flange of the steel girder.

Second, the present invention is advantageous in that the stress of the upper flange is absorbed by the precast concrete hatch block to reduce the amount of steel used in the steel girder, thereby increasing the economic efficiency.

Third, the construction of the present invention is simple and can be universally applied.

Figs. 1A to 1C are views showing a conventional open-form composite concrete steel girder,
2 is a perspective view showing a first embodiment of a precast concrete hatch block according to the present invention,
3 is a sectional view showing a first embodiment of a precast concrete hatch block according to the present invention,
4 is a side view showing a first embodiment of a precast concrete hatch block according to the present invention,
FIG. 5 is a plan view showing a first embodiment of a precast concrete hatch block according to the present invention, FIG.
6 is a sectional view showing a state in which a first embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder,
FIG. 7 is a perspective view showing a second embodiment of a precast concrete hatch block according to the present invention, FIG.
8 is a sectional view showing a second embodiment of a precast concrete hunt block according to the present invention,
9 is a side view showing a second embodiment of a precast concrete hatch block according to the present invention,
FIG. 10 is a plan view showing a second embodiment of a precast concrete hatch block according to the present invention, FIG.
11 is a sectional view showing a state in which a second embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder,
12 is a perspective view showing a third embodiment of a precast concrete hatch block according to the present invention,
13 is a sectional view showing a third embodiment of a precast concrete hatch block according to the present invention,
FIG. 14 is a side view showing a third embodiment of a precast concrete hatch block according to the present invention, FIG.
15 is a plan view showing a third embodiment of a precast concrete hatch block according to the present invention,
16 is a sectional view showing a state in which a third embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder,
17 is a perspective view showing a fourth embodiment of a precast concrete hatch block according to the present invention,
18 is a sectional view showing a fourth embodiment of a precast concrete hunt block according to the present invention,
19 is a side view showing a fourth embodiment of a precast concrete hunt block according to the present invention,
20 is a plan view showing a fourth embodiment of a precast concrete hatch block according to the present invention,
Fig. 21 is a sectional view showing a state in which a fourth embodiment of a precast concrete hatch block according to the present invention is installed on a steel material U girder; Fig.
FIG. 22 is a perspective view showing a fifth embodiment of a precast concrete hatch block according to the present invention, FIG.
23 is a sectional view showing a fifth embodiment of a precast concrete hatch block according to the present invention,
24 is a side view showing a fifth embodiment of a precast concrete hatch block according to the present invention,
25 is a plan view showing a fifth embodiment of a precast concrete hatch block according to the present invention,
26 is a sectional view showing a state in which a fifth embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder,
27 is a perspective view showing a sixth embodiment of the precast concrete hatch block according to the present invention,
28 is a sectional view showing a sixth embodiment of a precast concrete hatch block according to the present invention,
29 is a side view showing a sixth embodiment of a precast concrete hatch block according to the present invention,
30 is a plan view showing a sixth embodiment of a precast concrete hatch block according to the present invention,
31 is a sectional view showing a state in which a sixth embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder,
32 is a perspective view showing a seventh embodiment of a precast concrete hatch block according to the present invention,
33 is a sectional view showing a seventh embodiment of a precast concrete hunt block according to the present invention,
34 is a side view showing a seventh embodiment of a precast concrete hatch block according to the present invention,
35 is a plan view showing a seventh embodiment of a precast concrete hatch block according to the present invention,
Fig. 36 is a sectional view showing a seventh embodiment of a precast concrete hatch block according to the present invention,
37 is a perspective view showing an eighth embodiment of a precast concrete hatch block according to the present invention,
38 is a sectional view showing an eighth embodiment of a precast concrete hatch block according to the present invention,
39 is a side view showing an eighth embodiment of a precast concrete hatch block according to the present invention,
40 is a plan view showing an eighth embodiment of a precast concrete hatch block according to the present invention,
41 is a sectional view showing a state in which an eighth embodiment of a precast concrete hatch block according to the present invention is installed on a steel material U girder.

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

[First Embodiment] A symmetric I hunting block

FIG. 2 is a perspective view showing a first embodiment of a precast concrete hatch block according to the present invention, FIG. 3 is a sectional view showing a first embodiment of a precast concrete hatch block according to the present invention, FIG. 5 is a plan view showing a first embodiment of a precast concrete hatch block according to the present invention. FIG. 5 is a side view showing a first embodiment of a precast concrete hunting block according to the present invention.

As shown in these drawings, the precast concrete hunting block B1 according to the present invention has a wall portion 10 having a predetermined thickness and width and disposed to face each other; And a plurality of connecting steel members 20 which are buried and connected to each other across the wall portions 10.

That is, the precast concrete hunting block B1 according to the present invention is a structure in which the wall portion 10 and the connecting steel 20 are combined with each other.

Here, the wall portion 10 is a pair of rectangular plate-shaped bodies made of reinforced concrete. The rectangular plate-shaped bodies are formed in an I-shape as a whole, and are symmetrical in the left and right direction. (12) is formed.

Particularly, the cut-out portion 12 is formed for tightly coupling the wall portion 10 to the upper flange P of the steel girder G. The cross-sectional shape of the cut-out portion 12 is L-shaped The cutout portion 12 is formed to have a height equal to the thickness of the upper flange P and the width of the cutout portion 12 spanning the upper flange P is equal to 1 / 2, respectively.

On the other hand, as the connecting steel member 20, a reinforcing bar, a steel bar, a bar steel, or the like is used.

In the precast concrete hatch block B1 according to the present invention, a pair of I-shaped wall portions 10 are positioned opposite to each other, and a connecting steel material 20 is disposed between the wall portions 10, Wherein the precast concrete hunting block B1 is installed over the entire upper flange P of the steel girder G and the wall portion 10 of the precast concrete hunting block B1 is connected to the wall of the wall portion 10 of the precast concrete hunting block B1, The concrete is placed and cured in the connecting steel member 20 between the upper and lower flanges P of the steel girder G to form a complete precast concrete hunting block B1 and the precast concrete hunting block B1 The concrete precast concrete block (B1) has a symmetrical structure and can be suitably used for a horizontal floor plate. The concrete precast concrete block (B1) has a structure in which a deck plate (50) Let the sound be revealed.

Hereinafter, construction of the precast concrete hatch block B1 according to the present invention will be described.

6 is a sectional view showing a state in which a first embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder.

As shown in this figure, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention comprises the steps of: preparing a precast concrete hatch block B1; Mounting a steel girder (G) on alternating and piercing surfaces; Mounting a precast concrete hunting block (B1) on an upper flange (P) of the steel girder (G); Placing and curing concrete in the precast concrete hunting block B1 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B1; A deck plate 50 is installed on the upper surface of the precast concrete hunting block B1, and concrete is placed and cured to form a slab.

That is, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention includes a step of constructing a precast concrete hatch block B1, a step of placing a steel girder G, a step of placing a precast concrete hatch block B1, A synthesis step of the upper flange P of the girder G and a precast concrete hunting block B1, and a slab forming step.

Here, the precast concrete hunting block B1 is manufactured by a wall part 10 having a predetermined thickness and width at a factory or a site, and disposed opposite to each other; And a connecting steel member 20 in which a plurality of the connecting members are buried and connected across the wall portions 10, the wall portion 10 is formed in an I-shape, and the wall portion 10 is formed in a right- And a precast concrete hunting block B1 having a cut-out portion 12 of a predetermined shape is formed on the inner lower end of the wall portion 10. [

Subsequently, the step of mounting the steel girder (G) places the steel girder (G) on the pre-installed alternating and piercing angles.

The pre-cast concrete hunting block (B1) mounting step then mounts the precast concrete hunting block (B1) on the upper flange (P) of the steel girder (G).

The step of combining the upper flange P and the precast concrete hunting block B1 of the steel girder G is performed by pouring and curing the concrete in the precast concrete hunting block B1 placed on the upper flange P The upper flange P of the steel girder G and the precast concrete hunting block B1 are combined.

Next, in the slab forming step, a deck plate 50 is installed on the upper surface of the precast concrete hunting block B1, and concrete is laid and cured to form a slab.

[Second Embodiment] Asymmetry I hunting block

FIG. 7 is a perspective view showing a second embodiment of a precast concrete hunting block according to the present invention, FIG. 8 is a sectional view showing a second embodiment of a precast concrete hunting block according to the present invention, FIG. 10 is a plan view showing a second embodiment of a precast concrete hatch block according to the present invention. FIG. 10 is a side view showing a second embodiment of a precast concrete hunt block according to the present invention.

As shown in these drawings, the precast concrete hunting block B1 according to the present invention has a wall portion 10 having a predetermined thickness and width and disposed to face each other; And a plurality of connecting steel members 20 which are buried and connected to each other across the wall portions 10.

That is, the precast concrete hunting block B1 according to the present invention is a structure in which the wall portion 10 and the connecting steel 20 are combined with each other.

Here, the wall portion 10 is a pair of rectangular plate-shaped bodies made of reinforced concrete, the cross-sectional shape of the rectangular plate-like body is formed in an I-shape as a whole, and is formed as a left-right asymmetric shape, The cut-out portion 12 is formed.

Particularly, the reason why the wall portion 10 is formed in an asymmetric shape with a height difference is that the slope of the bottom plate is 6% or more in the case of curved bridge, This is because the difference between the concrete amount and the weight increases and the negative factor of the increase in the amount of steel in the steel girder (G) can be excluded.

The cut part 12 is formed at the lower end of the wall part 10 so that the cut part 12 can be used to tightly couple the wall part 10 to the upper flange P of the steel girder G The cut-out portion 12 has an L-shaped cross-section, and the cut-out portion 12 has a height equal to the thickness of the upper flange P, The width of the cut-out portion 12 is 1/2 of the width of the wall portion 10.

On the other hand, as the connecting steel member 20, a reinforcing bar, a steel bar, a bar steel, or the like is used.

In the precast concrete hatch block B1 according to the present invention, a pair of I-shaped wall portions 10 are positioned opposite to each other, and a connecting steel material 20 is disposed between the wall portions 10, Wherein the precast concrete hunting block B1 is installed over the entire upper flange P of the steel girder G and the wall portion 10 of the precast concrete hunting block B1 is connected to the wall of the wall portion 10 of the precast concrete hunting block B1, The concrete is placed and cured in the connecting steel member 20 between the upper and lower flanges P of the steel girder G to form a complete precast concrete hunting block B1 and the precast concrete hunting block B1 The concrete precast concrete hatch block B1 has an asymmetric structure and is therefore suitably used for a sloped floor plate. Place discovered that.

Hereinafter, the construction of the precast concrete hatch block according to the present invention will be described.

11 is a sectional view showing a state where a second embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder.

As shown in this figure, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention comprises the steps of: preparing a precast concrete hatch block B1; Mounting a steel girder (G) on alternating and piercing surfaces; Mounting a precast concrete hunting block (B1) on an upper flange (P) of the steel girder (G); Placing and curing concrete in the precast concrete hunting block B1 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B1; A deck plate 50 is installed on the upper surface of the precast concrete hunting block B1, and concrete is placed and cured to form a slab.

That is, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention includes a step of constructing a precast concrete hatch block B1, a step of placing a steel girder G, a step of placing a precast concrete hatch block B1, A synthesis step of the upper flange P of the girder G and a precast concrete hunting block B1, and a slab forming step.

Here, the precast concrete hunting block B1 is manufactured by a wall part 10 having a predetermined thickness and width at a factory or a site, and disposed opposite to each other; And a connecting steel member 20 in which a plurality of connecting members are buried and connected across the wall portions 10, the wall portion 10 is formed in an I-shape, and the wall portion 10 is formed asymmetrically And a precast concrete hunting block B1 having a cut-out portion 12 of a predetermined shape is formed on the inner lower end of the wall portion 10. [

Subsequently, the step of mounting the steel girder (G) places the steel girder (G) on the pre-installed alternating and piercing angles.

The pre-cast concrete hunting block (B1) mounting step then mounts the precast concrete hunting block (B1) on the upper flange (P) of the steel girder (G).

The step of combining the upper flange P and the precast concrete hunting block B1 of the steel girder G is performed by pouring and curing the concrete in the precast concrete hunting block B1 placed on the upper flange P The upper flange P of the steel girder G and the precast concrete hunting block B1 are combined.

Next, in the slab forming step, a deck plate 50 is installed on the upper surface of the precast concrete hunting block B1, and concrete is laid and cured to form a slab.

[Third Embodiment] A symmetrical L-shaped swing block

FIG. 12 is a perspective view showing a third embodiment of a precast concrete hatch block according to the present invention, FIG. 13 is a cross-sectional view showing a third embodiment of a precast concrete hatch block according to the present invention, FIG. 15 is a plan view showing a third embodiment of a precast concrete hatch block according to the present invention. FIG. 15 is a side view showing a third embodiment of a precast concrete hunt block according to the present invention.

As shown in these drawings, the precast concrete hunting block according to the present invention has a wall portion 10 having a predetermined thickness and width and disposed to face each other; And a plurality of connecting steel members 20 which are buried and connected to each other across the wall portions 10.

That is, the precast concrete hunting block B1 according to the present invention is a structure in which the wall portion 10 and the connecting steel 20 are combined with each other.

Here, the wall portion 10 is formed of a pair of L-shaped plates made of reinforced concrete, and is symmetrical in the left and right direction, and a cut-out portion 12 having a predetermined shape is formed at the lower end.

Particularly, the cut-out portion 12 is formed for tightly coupling the wall portion 10 to the upper flange P of the steel girder G. The cross-sectional shape of the cut-out portion 12 is L-shaped The cutout 12 is formed to have the same height as the thickness of the upper flange P and the width of the cutout 12 spanning the upper flange P is set to 1/2 of the width of the wall 10 .

On the other hand, as the connecting steel member 20, a reinforcing bar, a steel bar, a bar steel, or the like is used.

In the precast concrete hatch block B1 according to the present invention constructed as described above, a pair of L-shaped wall portions 10 are positioned so as to face each other, and a connecting steel material 20 is interposed between the wall portions 10, Wherein the precast concrete hunting block B1 is installed over the entire upper flange P of the steel girder G and the wall portion 10 of the precast concrete hunting block B1 is connected to the wall of the wall portion 10 of the precast concrete hunting block B1, The concrete is placed and cured in the connecting steel member 20 between the upper and lower flanges P of the steel girder G to form a complete precast concrete hunting block B1 and the precast concrete hunting block B1 The concrete precast concrete block (B1) has a symmetrical structure and can be suitably used for a horizontal floor plate. The concrete precast concrete block (B1) has a structure in which a deck plate (50) Let the sound be revealed.

16 is a sectional view showing a state in which a third embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder.

As shown in this figure, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention comprises the steps of: preparing a precast concrete hatch block B1; Mounting a steel girder (G) on alternating and piercing surfaces; Mounting a precast concrete hunting block (B1) on an upper flange (P) of the steel girder (G); Placing and curing concrete in the precast concrete hunting block B1 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B1; A deck plate 50 is installed on the upper surface of the precast concrete hunting block B1, and concrete is placed and cured to form a slab.

That is, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention includes a step of constructing a precast concrete hatch block B1, a step of placing a steel girder G, a step of placing a precast concrete hatch block B1, A synthesis step of the upper flange P of the girder G and a precast concrete hunting block B1, and a slab forming step.

Here, the precast concrete hunting block B1 is manufactured by a wall part 10 having a predetermined thickness and width at a factory or a site, and disposed opposite to each other; And a connecting steel member 20 in which a plurality of bridging members 20 are connected to each other across the wall portions 10. The wall portion 10 is formed in an L shape as a whole and the wall portion 10 has a symmetrical shape And a precast concrete hunting block B1 in which a cut-out portion 12 having a predetermined shape is formed at an inner lower end of the wall portion 10 is manufactured.

Subsequently, the step of mounting the steel girder (G) places the steel girder (G) on the pre-installed alternating and piercing angles.

The pre-cast concrete hunting block (B1) mounting step then mounts the precast concrete hunting block (B1) on the upper flange (P) of the steel girder (G).

The step of combining the upper flange P and the precast concrete hunting block B1 of the steel girder G is performed by pouring and curing the concrete in the precast concrete hunting block B1 placed on the upper flange P The upper flange P of the steel girder G and the precast concrete hunting block B1 are combined.

Next, in the slab forming step, a deck plate 50 is installed on the upper surface of the precast concrete hunting block B1, and concrete is laid and cured to form a slab.

[Fourth Embodiment] Asymmetrical L-type hunting block

FIG. 17 is a perspective view showing a fourth embodiment of a precast concrete hatch block according to the present invention, FIG. 18 is a sectional view showing a fourth embodiment of a precast concrete hatch block according to the present invention, FIG. FIG. 20 is a plan view showing a fourth embodiment of a precast concrete hatch block according to the present invention. FIG. 20 is a side view showing a fourth embodiment of a precast concrete hunt block according to the present invention.

As shown in these drawings, the precast concrete hunting block B1 according to the present invention has a wall portion 10 having a predetermined thickness and width and disposed to face each other; And a plurality of connecting steel members 20 which are buried and connected to each other across the wall portions 10.

That is, the precast concrete hunting block B1 according to the present invention is a structure in which the wall portion 10 and the connecting steel 20 are combined with each other.

Here, the wall part 10 is a pair of rectangular plate-shaped bodies made of reinforced concrete, the rectangular plate-shaped bodies having an L-shaped cross section, a left-right asymmetric shape, The cut-out portion 12 is formed.

Particularly, the reason why the wall portion 10 is formed in an asymmetric shape with a height difference is that the slope of the bottom plate is 6% or more in the case of curved bridge, This is because the difference between the concrete amount and the weight increases and the negative factor of the increase in the amount of steel in the steel girder (G) can be excluded.

The cut part 12 is formed at the lower end of the wall part 10 so that the cut part 12 can be used to tightly couple the wall part 10 to the upper flange P of the steel girder G The cut-out portion 12 has an L-shaped cross section. The cut-out portion 12 has a height equal to the thickness of the upper flange P, The width of the portion 12 is 1/2 of the width of the wall portion 10.

On the other hand, as the connecting steel member 20, a reinforcing bar, a steel bar, a bar steel, or the like is used.

In the precast concrete hatch block B1 according to the present invention constructed as described above, a pair of L-shaped wall portions 10 are positioned so as to face each other, and a connecting steel material 20 is interposed between the wall portions 10, Wherein the precast concrete hunting block B1 is installed over the entire upper flange P of the steel girder G and the wall portion 10 of the precast concrete hunting block B1 is connected to the wall of the wall portion 10 of the precast concrete hunting block B1, The concrete is placed and cured in the connecting steel member 20 between the upper and lower flanges P of the steel girder G to form a complete precast concrete hunting block B1 and the precast concrete hunting block B1 The concrete precast concrete hatch block B1 has an asymmetric structure and is therefore suitably used for a sloped floor plate. Place discovered that.

Hereinafter, the construction of the precast concrete hatch block according to the present invention will be described.

21 is a sectional view showing a state in which a fourth embodiment of a precast concrete hatch block according to the present invention is installed on a steel material U girder.

As shown in this figure, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention comprises the steps of: preparing a precast concrete hatch block B1; Mounting a steel girder (G) on alternating and piercing surfaces; Mounting a precast concrete hunting block (B1) on an upper flange (P) of the steel girder (G); Placing and curing concrete in the precast concrete hunting block B1 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B1; A deck plate 50 is installed on the upper surface of the precast concrete hunting block B1, and concrete is placed and cured to form a slab.

That is, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention includes a step of constructing a precast concrete hatch block B1, a step of placing a steel girder G, a step of placing a precast concrete hatch block B1, A synthesis step of the upper flange P of the girder G and a precast concrete hunting block B1, and a slab forming step.

Here, the precast concrete hunting block B1 is manufactured by a wall part 10 having a predetermined thickness and width at a factory or a site, and disposed opposite to each other; And a connecting steel member 20 in which a plurality of bridging members 20 are connected to each other across the wall unit 10. The wall unit 10 is formed in an L shape and the wall unit 10 is formed asymmetrically And a precast concrete hunting block B1 having a cut-out portion 12 of a predetermined shape is formed on the inner lower end of the wall portion 10. [

Subsequently, the step of mounting the steel girder (G) places the steel girder (G) on the pre-installed alternating and piercing angles.

The pre-cast concrete hunting block (B1) mounting step then mounts the precast concrete hunting block (B1) on the upper flange (P) of the steel girder (G).

The step of combining the upper flange P and the precast concrete hunting block B1 of the steel girder G is performed by pouring and curing the concrete in the precast concrete hunting block B1 placed on the upper flange P The upper flange P of the steel girder G and the precast concrete hunting block B1 are combined.

Next, in the slab forming step, a deck plate 50 is installed on the upper surface of the precast concrete hunting block B1, and concrete is laid and cured to form a slab.

[EMBODIMENT 5] The U-shaped symmetrical deck plate combined with the hatch block

FIG. 22 is a perspective view showing a fifth embodiment of a precast concrete hatch block according to the present invention, FIG. 23 is a sectional view showing a fifth embodiment of a precast concrete hatch block according to the present invention, FIG. FIG. 25 is a plan view showing a fifth embodiment of a precast concrete hatch block according to the present invention. FIG. 25 is a side view showing a fifth embodiment of a precast concrete hunt block according to the present invention.

As shown in these drawings, the precast concrete hunting block according to the present invention has a wall portion 10 having a predetermined thickness and width and disposed to face each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30).

That is, the precast concrete hatch block B2 according to the present invention is a structure in which the wall portion 10, the bottom plate 30, the connecting steel 40, and the deck plate 50 are combined with each other.

The wall portion 10 and the bottom plate 30 are integrally formed of an inverted U-shaped reinforced concrete as a whole, are symmetrically formed, and cut out portions 12 having a predetermined shape are formed at an outer lower end thereof do.

Particularly, the cut-out portion 12 is formed for tightly coupling the wall portion 10 to the upper flange P of the steel girder G. The cross-sectional shape of the cut-out portion 12 is L-shaped The cutout portion 12 is formed to have a height equal to the thickness of the upper flange P and the width of the cutout portion 12 spanning the upper flange P is equal to 1 / 2, respectively.

The connecting steel member 40 is a kind of loop reinforcing steel that is embedded at a predetermined distance while keeping a predetermined distance between a plurality of the outer side of the wall member 10 and is installed in a form to enclose a shear connection member coupled to the upper flange P .

The deck plate (50) is a member that is partially embedded in the bottom plate (30) and protruding upward. The deck plate (50) is welded to the corrugated steel plate with truss roots having a triangular, In the longitudinal direction.

The precast concrete hatch block B2 according to the present invention having the above-described structure has an inverted U-shaped cross section as a whole, and the precast concrete hunt block B2 is installed on the upper part of the steel girder G The precast concrete hatch block B2 is connected to the upper flange P of the steel girder G by a connecting steel material 40 and concrete is placed and cured on the connecting steel material 40, And a slab is formed by pouring concrete into a deck plate (50) of the precast concrete hatch block (B2) to form a pre-cast concrete hunting block (B2) It is noted that the cast concrete hunt block B2 is symmetrical and can be suitably used mainly for horizontal floor slabs.

Hereinafter, the construction of the precast concrete hatch block according to the present invention will be described.

26 is a sectional view showing a fifth embodiment of the precast concrete hatch block according to the present invention in a state in which the steel U girder is installed.

As shown in this drawing, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention comprises the steps of: manufacturing a precast concrete hatch block B2; Mounting a steel girder (G) on alternating and piercing surfaces; Mounting a precast concrete hunting block (B2) on an upper flange (P) of the steel girder (G); Placing and curing concrete in the precast concrete hunting block B2 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B2; And pouring and curing concrete on the upper surface of the precast concrete hunting block B2 to form a slab.

That is, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention includes a step of constructing a precast concrete hunt block B2, a step of placing a steel girder G, a step of placing a precast concrete hunt block B2, A synthesis step of the upper flange P of the girder G and a precast concrete hunting block B2, and a slab forming step.

Here, the precast concrete hunting block B2 is manufactured by a wall unit 10 having a predetermined thickness and width at a factory or a site, and disposed opposite to each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30). The wall portion (10) is formed in an inverted U shape and is formed in a symmetrical shape, A precast concrete hunting block B2 having a cut-out portion 12 of a predetermined shape is manufactured.

Subsequently, the step of mounting the steel girder (G) places the steel girder (G) on the pre-installed alternating and piercing angles.

Next, the pre-cast concrete hunting block B2 is placed on the upper flange P of the steel girder G, and the pre-cast concrete hunting block B2 is mounted.

The step of synthesizing the upper flange P and the precast concrete hunting block B2 of the steel girder G is performed by pouring and curing the concrete in the precast concrete hunting block B2 placed on the upper flange P The upper flange P of the steel girder G and the precast concrete hunting block B2 are combined.

Next, in the slab forming step, concrete is placed and cured in the deck plate 50 provided on the upper surface of the precast concrete hunting block B2 to form a slab.

[Sixth Embodiment] A hatch block combined with an inverted U-shaped asymmetric deck plate

FIG. 27 is a perspective view showing a sixth embodiment of a precast concrete hatch block according to the present invention, FIG. 28 is a sectional view showing a sixth embodiment of a precast concrete hatch block according to the present invention, FIG. 30 is a plan view showing a sixth embodiment of a precast concrete hatch block according to the present invention. FIG. 30 is a side view showing a sixth embodiment of a precast concrete hunting block according to the present invention.

As shown in these drawings, the precast concrete hatch block B2 according to the present invention has a wall portion 10 having a predetermined thickness and width and disposed to face each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30).

That is, the precast concrete hatch block B2 according to the present invention is a structure in which the wall portion 10, the bottom plate 30, the connecting steel 40, and the deck plate 50 are combined with each other.

The wall portion 10 and the bottom plate 30 are integrally formed of an inverted U-shaped reinforced concrete as a whole, are formed asymmetrically, and a cut portion 12 having a predetermined shape is formed at an outer lower end thereof do.

Particularly, the reason why the wall portion 10 is formed in an asymmetric shape with a height difference is that the inclination of the bottom plate 30 eliminates the increase in the quantity of concrete and the increase in load when the horizontal deck plate 50 is used, The bending is minimized by closing the upper portion before the concrete is poured and the sectional rigidity of the bottom plate 30 is greatly increased by the combined action of the deck plate 50 and the integral precast concrete block B2, G) can be reduced.

The cut-out portion 12 is formed for tightly coupling the wall portion 10 to the upper flange P of the steel girder G. The cross-sectional shape of the cut-out portion 12 is L-shaped The cutout portion 12 is formed to have a height equal to the thickness of the upper flange P and the width of the cutout portion 12 spanning the upper flange P is equal to 1 / 2, respectively.

The connecting steel material 40 is a kind of loop reinforcing steel which is embedded at a certain distance while keeping a predetermined distance between a plurality of the outer side of the wall part 10 and is installed in such a manner as to enclose a shear connection material joined on the upper flange P .

The deck plate 50 is a member that is partially embedded in the bottom plate 30 and protrudes upwardly. The deck plate 50 is welded to the corrugated steel plate with truss roots of a triangular, rectangular, In the longitudinal direction.

The precast concrete hatch block B2 according to the present invention having the above-described structure has an inverted U-shaped cross section as a whole, and the precast concrete hunt block B2 is installed on the upper part of the steel girder G The precast concrete hatch block B2 is connected to the upper flange P of the steel girder G by a connecting steel material 40 and concrete is placed and cured on the connecting steel material 40, And a slab is formed by pouring concrete into a deck plate (50) of the precast concrete hatch block (B2) to form a pre-cast concrete hunting block (B2) Since the cast concrete block B2 is asymmetric, it can be used mainly for inclined bottom plates.

Hereinafter, construction of the precast concrete hatch block B2 according to the present invention constructed as described above will be described.

31 is a cross-sectional view showing a state in which a sixth embodiment of a precast concrete hatch block according to the present invention is installed on a steel U girder.

As shown in this drawing, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention comprises the steps of: manufacturing a precast concrete hatch block B2; Mounting a steel girder (G) on alternating and piercing surfaces; Mounting a precast concrete hunting block (B2) on an upper flange (P) of the steel girder (G); Placing and curing concrete in the precast concrete hunting block B2 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B2; And pouring and curing concrete on the upper surface of the precast concrete hunting block B2 to form a slab.

That is, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention includes a step of constructing a precast concrete hunt block B2, a step of placing a steel girder G, a step of placing a precast concrete hunt block B2, A synthesis step of the upper flange P of the girder G and a precast concrete hunting block B2, and a slab forming step.

Here, the precast concrete hunting block B2 is manufactured by a wall unit 10 having a predetermined thickness and width at a factory or a site, and disposed opposite to each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30). The wall section (10) is formed in an inverted U shape and is formed in a left - right asymmetrical shape, A precast concrete hunting block B2 having a cut-out portion 12 of a predetermined shape is manufactured.

Subsequently, the step of mounting the steel girder (G) places the steel girder (G) on the pre-installed alternating and piercing angles.

Next, the pre-cast concrete hunting block B2 is placed on the upper flange P of the steel girder G, and the pre-cast concrete hunting block B2 is mounted.

The step of synthesizing the upper flange P and the precast concrete hunting block B2 of the steel girder G is performed by pouring and curing the concrete in the precast concrete hunting block B2 placed on the upper flange P The upper flange P of the steel girder G and the precast concrete hunting block B2 are combined.

Next, in the slab forming step, concrete is placed and cured in the deck plate 50 provided on the upper surface of the precast concrete hunting block B2 to form a slab.

[Seventh Embodiment] A hatch block for both Z-shaped symmetrical deck plates

FIG. 32 is a perspective view showing a seventh embodiment of a precast concrete hatch block according to the present invention, FIG. 33 is a sectional view showing a seventh embodiment of a precast concrete hatch block according to the present invention, FIG. 35 is a plan view showing a seventh embodiment of a precast concrete hatch block according to the present invention. FIG. 35 is a plan view showing a seventh embodiment of a precast concrete hunt block according to the present invention.

As shown in these drawings, the precast concrete hatch block B2 according to the present invention has a wall portion 10 having a predetermined thickness and width and disposed to face each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30).

That is, the precast concrete hatch block B2 according to the present invention is a structure in which the wall portion 10, the bottom plate 30, the connecting steel 40, and the deck plate 50 are combined with each other.

The wall portion 10 and the bottom plate 30 are integrally formed of a Z-shaped reinforced concrete as a whole, are symmetrically formed, and a cut-out portion 12 having a predetermined shape is formed at an outer lower end .

Particularly, the cut-out portion 12 is formed for tightly coupling the wall portion 10 to the upper flange P of the steel girder G. The cross-sectional shape of the cut-out portion 12 is L-shaped The cutout 12 is formed to have the same height as the thickness of the upper flange P and the width of the cutout 12 spanning the upper flange P is set to 1/2 of the width of the wall 10 .

The connecting steel member 40 is a kind of loop reinforcing steel that is embedded at a predetermined distance while keeping a predetermined distance between a plurality of the outer side of the wall member 10 and is installed in a form to enclose a shear connection member coupled to the upper flange P .

The deck plate (50) is a member that is partially embedded in the bottom plate (30) and protruding upward. The deck plate (50) is welded to the corrugated steel plate with truss roots having a triangular, In the longitudinal direction.

The precast concrete hunting block B2 according to the present invention having the above-described structure has a Z-shaped cross-section as a whole. The precast concrete hunting block B2 is installed on the upper part of the steel girder G, The precast concrete hunting block B2 is connected to the upper flange P of the steel girder G by a connecting steel material 40 and the concrete is placed and cured on the connecting steel material 40, A concrete precast concrete block B2 is formed by combining with the flange P and concrete is placed in the deck plate 50 of the precast concrete block B2 to form a slab, It is noted that the concrete hunting block (B2) has a symmetrical structure and therefore can be suitably used mainly for horizontal floor slabs.

Hereinafter, the construction of the precast concrete hatch block according to the present invention will be described.

Fig. 36 is a sectional view showing a seventh embodiment of a precast concrete hatch block according to the present invention installed on a steel U girder.

As shown in this drawing, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention comprises the steps of: manufacturing a precast concrete hatch block B2; Mounting a steel girder (G) on alternating and piercing surfaces; Mounting a precast concrete hunting block (B2) on an upper flange (P) of the steel girder (G); Placing and curing concrete in the precast concrete hunting block B2 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B2; And pouring and curing concrete on the upper surface of the precast concrete hunting block B2 to form a slab.

That is, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention includes a step of constructing a precast concrete hunt block B2, a step of placing a steel girder G, a step of placing a precast concrete hunt block B2, A synthesis step of the upper flange P of the girder G and a precast concrete hunting block B2, and a slab forming step.

Here, the precast concrete hunting block B2 is manufactured by a wall unit 10 having a predetermined thickness and width at a factory or a site, and disposed opposite to each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upwardly at a predetermined portion of the bottom plate (30). The wall portion (10) is formed in a Z shape and is symmetrically formed at the outer bottom A precast concrete hunting block B2 on which a cut-out portion 12 having a predetermined shape is formed is manufactured.

Subsequently, the step of mounting the steel girder (G) places the steel girder (G) on the pre-installed alternating and piercing angles.

Next, the pre-cast concrete hunting block B2 is placed on the upper flange P of the steel girder G, and the pre-cast concrete hunting block B2 is mounted.

The step of synthesizing the upper flange P and the precast concrete hunting block B2 of the steel girder G is performed by pouring and curing the concrete in the precast concrete hunting block B2 placed on the upper flange P The upper flange P of the steel girder G and the precast concrete hunting block B2 are combined.

Next, in the slab forming step, concrete is placed and cured in the deck plate 50 provided on the upper surface of the precast concrete hunting block B2 to form a slab.

[Eighth Embodiment] A hatch block combined with an L-shaped asymmetric deck plate

FIG. 37 is a perspective view showing an eighth embodiment of a precast concrete hatch block according to the present invention, FIG. 38 is a sectional view showing an eighth embodiment of a precast concrete hatch block according to the present invention, FIG. 40 is a plan view showing an eighth embodiment of a precast concrete hatch block according to the present invention. FIG. 40 is a side view showing an eighth embodiment of a precast concrete hunt block according to the present invention.

As shown in these drawings, the precast concrete hatch block B2 according to the present invention has a wall portion 10 having a predetermined thickness and width and disposed to face each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30).

That is, the precast concrete hatch block B2 according to the present invention is a structure in which the wall portion 10, the bottom plate 30, the connecting steel 40, and the deck plate 50 are combined with each other.

The wall portion 10 and the bottom plate 30 are integrally formed of a Z-shaped reinforced concrete as a whole, formed asymmetrically in the left and right directions, and have a predetermined cut-out portion 12 formed in the outer lower end thereof .

Particularly, the reason why the wall portion 10 is formed in an asymmetric shape with a height difference is that the slope of the bottom plate is 6% or more in the case of curved bridge, The difference is that the concrete quantity is increased and the weight is increased, so that the negative factor of increasing the amount of steel of the steel girder (G) can be dispatched.

The cut-out portion 12 is formed for tightly coupling the wall portion 10 to the upper flange P of the steel girder G. The cross-sectional shape of the cut-out portion 12 is L-shaped The cutout portion 12 is formed to have a height equal to the thickness of the upper flange P and the width of the cutout portion 12 spanning the upper flange P is equal to 1 / 2, respectively.

The connecting steel material 40 is a kind of loop reinforcing steel which is embedded at a certain distance while keeping a predetermined distance between a plurality of the outer side of the wall part 10 and is installed in such a manner as to enclose a shear connection material joined on the upper flange P .

The deck plate 50 is a member that is partially embedded in the bottom plate 30 and protrudes upwardly. The deck plate 50 is welded to the corrugated steel plate with truss roots of a triangular, rectangular, In the longitudinal direction.

The precast concrete hatch block B2 according to the present invention having the above-described structure has a Z-shaped structure as a whole, the precast concrete hatch block B2 is installed on the upper part of the steel girder G, The precast concrete hunting block B2 is connected to the upper flange P of the steel girder G by a connecting steel material 40 so that concrete is poured and cured in that portion, (P) to form a complete precast concrete hunting block (B2), and a slab is formed by placing concrete in a deck plate (50) of the precast concrete hatch block (B2) It is noted that the hatch block B2 is of an asymmetric structure and can be suitably used mainly for inclined bottom plates.

Hereinafter, construction of the precast concrete hatch block B2 according to the present invention constructed as described above will be described.

41 is a sectional view showing a state in which an eighth embodiment of a precast concrete hatch block according to the present invention is installed on a steel material U girder.

As shown in this drawing, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention comprises the steps of: manufacturing a precast concrete hatch block B2; Mounting a steel girder (G) on alternating and piercing surfaces; Mounting a precast concrete hunting block (B2) on an upper flange (P) of the steel girder (G); Placing and curing concrete in the precast concrete hunting block B2 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B2; And pouring and curing concrete on the upper surface of the precast concrete hunting block B2 to form a slab.

That is, a method of constructing a bridge overhead structure using a precast concrete hatch block according to the present invention includes a step of constructing a precast concrete hunt block B2, a step of placing a steel girder G, a step of placing a precast concrete hunt block B2, A synthesis step of the upper flange P of the girder G and a precast concrete hunting block B2, and a slab forming step.

Here, the precast concrete hunting block B2 is manufactured by a wall unit 10 having a predetermined thickness and width at a factory or a site, and disposed opposite to each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30). The wall portion (10) is formed in a Z shape and is formed in a left and right asymmetric shape, A precast concrete hunting block B2 on which a cut-out portion 12 having a predetermined shape is formed is manufactured.

Subsequently, the step of mounting the steel girder (G) places the steel girder (G) on the pre-installed alternating and piercing angles.

Next, the pre-cast concrete hunting block B2 is placed on the upper flange P of the steel girder G, and the pre-cast concrete hunting block B2 is mounted.

The step of synthesizing the upper flange P and the precast concrete hunting block B2 of the steel girder G is performed by pouring and curing the concrete in the precast concrete hunting block B2 placed on the upper flange P The upper flange P of the steel girder G and the precast concrete hunting block B2 are combined.

Next, in the slab forming step, concrete is placed and cured in the deck plate 50 provided on the upper surface of the precast concrete hunting block B2 to form a slab.

10: wall part 12:
20: connecting steel 30: bottom plate
40: connecting steel 50: deck plate
B1: Precast concrete hunting block
B2: Precast concrete hunting block
G: Steel girder P: Upper flange

Claims (2)

A wall portion 10 having a predetermined thickness and width and disposed to face each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined part of the wall part 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30)
The wall portion 10 and the bottom plate 30 are integrally formed of an inverted U-shaped or Z-shaped reinforced concrete as a whole and are formed symmetrically or asymmetrically in the left and right directions. The cut-out portion 12 is formed for tightly coupling the wall portion 10 to the upper flange P of the steel girder G. The cross-sectional shape of the cut- The cut-out portion 12 is formed to have the same height as the thickness of the upper flange P and the width of the cut-out portion 12 spanning the upper flange P is equal to the width of the wall portion 10 / RTI >< RTI ID = 0.0 &
The connecting steel material 40 is a loop reinforcing steel which is embedded at a certain distance on the outer side of the wall part 10 while maintaining a predetermined distance therebetween and is installed in a form to enclose a shear connection member coupled on the upper flange P,
The deck plate (50) is a member that is embedded in the bottom plate (30) and protrudes upward. The deck plate (50) is welded to the corrugated steel plate with truss roots of triangular, Wherein the pre-cast concrete hammering block is welded. A wall section (10) having a predetermined thickness and width at a factory or a site and arranged to face each other; A bottom plate (30) integrally formed across the top of the wall part (10); A connecting steel material 40 which is embedded in a predetermined portion of the wall portion 10 while maintaining a predetermined distance therebetween; And a deck plate (50) protruding upward while a certain portion is embedded in the bottom plate (30). The wall portion (10) and the bottom plate (30) And the cutout portion 12 is formed on the upper flange P of the steel girder G so as to be in contact with the upper flange P of the steel girder G, Sectional shape of the cut-out portion 12 is formed in an L-shape and the height of the cut-out portion 12 is equal to the thickness of the upper flange P And the width of the cut-out portion 12 extending over the upper flange P is formed to be 1/2 of the width of the wall portion 10 and the connecting steel 40 is formed on the outer side of the wall portion 10 Is a loop reinforcing steel which is embedded in a certain portion of the steel reinforcing plate The deck plate 50 is a member which is embedded in the bottom plate 30 and protrudes upward. The truss roots of the triangular, square, and shaping shapes are welded on the corrugated steel plate And a precast concrete hatch block (B2) in which a cast iron muscle is welded in the longitudinal direction on the truss muscle;
Mounting a steel girder (G) on a pre-installed alternation and pier;
Mounting a precast concrete hunting block (B2) all over the upper flange (P) of the steel girder (G);
Placing and curing concrete in the precast concrete hunting block B2 to synthesize the upper flange P of the steel girder G and the precast concrete hunting block B2;
And forming a slab by pouring and curing concrete on the upper surface of the precast concrete hunting block (B2), and a method of constructing a bridge overhead structure using the precast concrete hunting block.

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