KR102563620B1 - Half Precast Concrete continuous slab and construction method of the same - Google Patents

Abstract

The present invention can extend and install a single full PC continuous slab as long as the length of the cantilever through the block-out portion without the influence of the shear connector on the branch side of the girder, and introduce tension into the PS steel through the block-out portion to cross-section of the negative moment section. (bending, shearing, resistance) reinforcement can be increased, and construction on site is simple, so it provides a full PC continuous slab reinforced with support parts that shortens the construction period and has excellent work safety, and its construction method.
The full PC continuous slab according to a preferred embodiment of the present invention is a full PC continuous slab installed on a plurality of girders side by side, and has a cantilever length that protrudes further by a certain amount from the support of the outermost girder at a certain width and both ends, respectively. , A PC floor plate made of concrete with a block-out part formed so that the shear connector protruding on the top of the girder can be inserted through the thickness direction at each position corresponding to the support part of each girder; Lower PS steels arranged and buried in the longitudinal direction at regular intervals in the width direction at the bottom of the PC floor plate to introduce compressive stress into the concrete cross section; It is characterized in that it includes; block-out part reinforcing material that is located in each block-out part and at the same time, the lower part is buried in the PC bottom plate to reinforce the block-out part.

Description

Full PC continuous slab reinforced with support and its construction method {Half Precast Concrete continuous slab and construction method of the same}

The present invention relates to a full PC continuous slab used for constructing a concrete floor plate and a construction method thereof, and in particular, a single full PC continuous slab is extended by the length of a cantilever through a blockout portion without the influence of a shear connector on the support side of a girder. and can be installed by introducing tension into the PS steel through the block-out part, thereby increasing the cross-section (bending, shearing, resistance) reinforcement of the negative moment section. It relates to a full PC continuous slab with additional reinforcement and a construction method thereof.

In general, a girder bridge is constructed by placing a girder on an abutment and a pier, and then pouring concrete on the upper surface of the girder to construct a floor plate. In order to pour concrete like this, a formwork must be used, and in this case, the installation and disassembly of the formwork takes a long time, and a fall accident may occur due to the worker's carelessness. do. However, even when PC slab is applied, air delay and safety of workers cannot be solved because a separate cantilever part shoring and formwork must be installed for the construction of both end cantilever parts (both ends of the bridge deck). Therefore, there is a need for a PC slab and a construction method capable of constructing an end cantilever portion without requiring a separate formwork.

As a background technology of the present invention, Korea Patent Registration No. 10-0728106 (Patent Document 1) proposes a 'cantilever part installation structure and construction method of a bridge deck'. This allows the final bridge deck cantilever part to be constructed by binding the panel formwork composed of the panel support plate and reinforcing ribs to the support fixing means previously fixed to the upper surface of the bridge girder, so that the cantilever part of the bridge deck cantilever without separate formwork and shoring. This is to make it easy to construct. However, even in this case, it is difficult to shorten the construction period because a separate panel formwork must be installed, and there is a safety disadvantage because it requires a high-altitude work to fix the panel formwork to the upper surface of the bridge girder.

As another technology that is the background of the present invention, Korea Patent Registration No. 10-1883413 (Patent Document 2), a 'supporting bracket installation structure' has been proposed. This can be quickly and easily installed on the girder to support the formwork for casting the deck of the bridge, but can reduce the safety accident rate of workers and the construction period if it is not dismantled after installation, and can be dismantled if necessary. It can be simplified and lightened at the same time, and the steel material is welded to meet the structural stability that can stably transmit the load to the girder while minimizing its own weight. However, even in this case, it is necessary to install a support plate and a formwork, which not only reduces work safety, but also makes it difficult to shorten the construction period.

Korea Patent Registration No. 10-0728106 Korea Patent Registration No. 10-1883413

The present invention can extend and install a single full PC continuous slab as long as the length of the cantilever through the block-out portion without the influence of the shear connector on the branch side of the girder, and introduce tension into the PS steel through the block-out portion to cross-section of the negative moment section. The purpose is to provide a full PC continuous slab and its construction method, in which reinforcement (bending, shear, resistance) can be increased, and on-site construction is simple, shortening the period and having excellent work safety.

The full PC continuous slab according to a preferred embodiment of the present invention is a full PC continuous slab installed on a plurality of girders side by side, and has a cantilever length that protrudes further by a certain amount from the support of the outermost girder at a certain width and both ends, respectively. , A PC floor plate made of concrete with a block-out part formed so that the shear connector protruding on the top of the girder can be inserted through the thickness direction at each position corresponding to the support part of each girder; Lower PS steels arranged and buried in the longitudinal direction at regular intervals in the width direction at the bottom of the PC floor plate to introduce compressive stress into the concrete cross section; A block-out part reinforcing member that is located in the block-out part and has a lower part embedded in the PC bottom plate to reinforce the block-out part at the same time, and the block-out part reinforcing material is a pair of lower anchoring plates embedded and fixed in the PC bottom plate , It consists of a block-out part reinforcement bridge protruding upward from the lower anchoring plate at a certain height and connected to the lower anchoring plate, and an upper anchoring plate synthesized with cast-in-place concrete by horizontally connecting the top of the block-out part reinforcement bridge. The blockout reinforcement members are connected to each other through a pair of lower steel bars and a pair of upper steel bars, and to increase the bending capacity of the negative moment section of the full PC continuous slab, the lower PS steel materials are connected to each pair of lower steel bars and upper bars. It is characterized in that tension is introduced after being bent through the steel bar.

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In addition, the lower PS steel is characterized in that tension is made after being mounted through a rolling cap that is rotatably inserted into a pair of lower steel rods and a pair of upper steel rods.

In addition, the block-out part reinforcement bridge is characterized in that a trapezoidal side opening is formed to increase the composite force with the cast-in-place concrete.

The full PC continuous slab according to another preferred embodiment of the present invention is a full PC continuous slab installed on a plurality of side-by-side girders, wherein a certain width and both ends each have a cantilever length that protrudes further by a certain amount from the branch of the outermost girder. A PC floor plate made of concrete with a blockout portion formed so that the shear connector protruding on the top of the girder can be inserted through the thickness direction at each position corresponding to the support part of each girder; Lower PS steels arranged and buried in the longitudinal direction at regular intervals in the width direction at the bottom of the PC floor plate to introduce compressive stress into the concrete cross section; A block-out part reinforcing member that is located in the block-out part and has a lower part embedded in the PC bottom plate to reinforce the block-out part at the same time, and the block-out part reinforcing material is a pair of lower anchoring plates embedded and fixed in the PC bottom plate , It is composed of a block-out part reinforcement bridge protruding upward from the lower anchoring plate at a certain height and connected to the lower anchoring plate, and an upper anchoring plate synthesized with cast-in-place concrete by connecting the top of the block-out part reinforcement bridge horizontally. The sub-reinforcement member is bonded to the side of the block-out part reinforcing bridge, and a guide tube for bending PS steel is installed. It is characterized in that tension is introduced after being inserted into the conversion guide tube and bent.

In addition, bolt boxes are installed in a plurality of places along the long sides of both sides of the upper surface of the PC bottom plate, and a plurality of height adjustment bolts protruding upward are fixedly installed in the bolt box, so that the connection between adjacent full PC continuous slabs and the height It is characterized in that the adjustment is made by assembling the joint steel to the height adjustment bolt installed on one side of the full PC continuous slab and the height adjustment bolt installed on the other side of the full PC continuous slab, and then tightening and adjusting the nut.

In addition, the lower PS steel is installed with a non-attached section with concrete in the parent moment section, and is placed and buried in the longitudinal direction at regular intervals in the width direction on the upper part of the PC floor plate to introduce compressive stress to the concrete cross section. The upper PS steel is installed, and the upper PS steel is characterized in that it is installed with a non-adherent section with concrete in the positive moment section.

On the other hand, in the method of constructing a concrete floor plate of a bridge using a full PC continuous slab reinforced with support parts according to the present invention, after lifting the full PC continuous slab to the top of the girder, the shear connector protruding from the top of the girder is a block Placing a full PC continuous slab on the support part of the girder so that it is located on the outer part; burying the shear connector and the block-out reinforcing material by pouring and filling the in-situ concrete in the block-out part of the PC floor plate; and interconnecting adjacent full PC continuous slabs each time the lifting and placing of the full PC continuous slab is repeated.

Here, if connection and height adjustment between adjacent full PC continuous slabs is required, joint steel is assembled to a height adjustment bolt installed in the bolt box of one full PC continuous slab and a height adjustment bolt installed in the bolt box of the other full PC continuous slab. It is characterized in that it is made by fastening the nut after.

According to the full PC continuous slab reinforced with support parts and its construction method of the present invention, the full PC continuous slab can be installed by extending as much as the length of the cantilever by being installed on the girder through the blockout part without obstruction of the shear connector installed on the support part of the girder. can

In addition, the block-out part reinforcing material is installed in the block-out part to strengthen the shear resistance of the full PC continuous slab.

In addition, tension can be introduced into the PS steel through the block-out part, so the section (bending, shear, resistance) reinforcement of the parent moment section can be increased. As the floor plate is installed, construction on site becomes easy and installation of formwork is unnecessary, reducing the construction period and providing excellent work safety.

In addition, the upper and lower PS steels, which are buried in the PC bottom plate and introduce compressive stress to the cross section, are installed with non-adherent sections at different locations to reduce stress generation, thereby improving the yield strength of the bending moment.

The following drawings attached to this specification illustrate a preferred embodiment of the present invention, and together with the detailed description of the present invention serve to further understand the technical idea of the present invention, the present invention is limited to those described in the accompanying drawings. It should not be construed as limiting.
1A is a state diagram in which a full PC continuous slab according to an embodiment of the present invention is lifted and mounted on a girder.
Figure 1b is an example of the upper PS steel is additionally installed in the full PC continuous slab of Figure 1a.
2 is a plan view of FIG. 1A and is an exemplary view of a partial section;
Figure 3a is a longitudinal cross-sectional view of the block-out part side of a full PC continuous slab of one form according to the present invention.
Figure 3b is a three-dimensional installation state diagram of the block-out part reinforcement shown in Figure 3a.
Figure 4a is a longitudinal cross-sectional view of the block-out part side of another type of full PC continuous slab according to the present invention.
Figure 4b is a state in which the PS steel material is placed in tension on the block-out portion reinforcement shown in Figure 4a.
Figure 5 is an exemplary view showing various forms of the block-out part reinforcement shown in Figure 4b.
Figure 6 is a state diagram in which the PS steel is inserted into the PS steel bending guide tube bonded to the block-out part reinforcement according to the present invention.
Figure 7a is a plan view of the joint between full PC continuous slabs according to the present invention.
7b and 7c are state diagrams before and after height adjustment showing a state in which the connection between full PC continuous slabs according to the present invention is made through joint steel and height adjustment bolts.
8a is a state diagram in which the cast-in-place concrete is filled in the block abutment after the full PC continuous slab according to an embodiment of the present invention is mounted on the girder.
Figure 8b is an enlarged view of the block-out portion reinforcement portion shown in Figure 8a.
Figure 9 is an example of the upper PS steel is additionally installed in the full PC continuous slab of Figure 8a.
10a and 10b are for showing the attachment and non-attachment sections of the upper and lower PS steel materials applied to the full PC continuous slab according to an embodiment of the present invention, (a) is a longitudinal cross-sectional view of the bridge deck, (b) is Moment diagram, (C) shows the upper PS steel wire arrangement, (D) shows the lower PS steel wire arrangement.

Below, the present invention will be described in detail with reference to the embodiments presented in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

The full PC continuous slab 100 according to this embodiment is installed on a plurality of girders 10 parallel to each other as shown in FIGS. 1 and 2. In this embodiment, two girders 10 are arranged side by side, but one or more girders may be additionally arranged between them.

The full PC continuous slab 100 has a certain width W and a cantilever length L1 whose both ends protrude by a certain amount from the support portion of the outermost girder 10, respectively. Therefore, the full length (L) of the full PC continuous slab 100 is made the same as the width (L) of the bridge including the cantilever length (L1). In addition, the full PC continuous slab 100 is penetrated in the thickness direction at each position corresponding to the support portion of each girder 10 and has a blockout portion so that the shear connector 12 protruding from the top of the girder 10 can be inserted. 112 is formed and made of concrete. The blockout part 112 provides a sufficient space to accommodate the shear connector 12 . Therefore, as shown in FIG. 8, the cast-in-place concrete 190 is filled in the block-out part 112 during the construction process of the upper plate of the bridge. The shear connector 12 may be, for example, a T shape or a Π shape.

A lower PS steel member 120 is installed in the bottom of the PC floor plate 110, which is arranged and buried in the longitudinal direction at regular intervals in the width direction and introduces compressive stress to the concrete cross section. The lower PS steel material 120 may be a PS steel wire, a steel bar, or a stranded wire. When the lower PS steel material 120 passes through the blockout portion 112, it may be continuously installed through the blockout portion reinforcing member 130 as shown in FIGS. 4 to 6.

The block-out part reinforcing materials 130 are respectively located in the block-out part 112 and at the same time, the lower part is buried in the PC bottom plate 110 to reinforce the corresponding block-out part 112. In this way, the blockout part reinforcing material 130 should have a structure capable of not only reinforcing the blockout part 112 but also avoiding the interference of the shear connector 12 on the girder 10 side and installing the lower PS steel material 120 if necessary.

To this end, the blockout part reinforcement 130 protrudes upward at a certain height from the pair of lower anchoring plates 131 and 131 buried and fixed in the PC bottom plate 110 as shown in FIGS. 3A and 3B and the lower anchoring plates 131 and 131 It consists of a block-out part reinforcement bridge 132 connected to the lower anchoring plates 131 and 131 and an upper anchoring plate 133 synthesized with cast-in-place concrete by connecting the top of the block-out part reinforcement bridge 132 horizontally. The block-out reinforcing member 130 may be manufactured by cutting H-beam, for example, to have such a configuration.

Preferably, a trapezoidal side opening 132a is formed in the block-out part reinforcing bridge 132 to increase the composite force with the cast-in-place concrete. The shape of the block-out reinforcing bridge 132 and the side opening 132a may be various trapezoidal shapes as shown in FIG. 5 .

On the other hand, the full PC continuous slab 100 of the present invention may appear in two cross-sectional shapes in a state where the blockout portion 112 and the blockout portion reinforcing member 130 are installed. That is, in the full PC continuous slab 100, the lower PS steel material 120 passing through the blockout part 112 is installed without being constrained to the blockout part reinforcing member 130 as shown in FIG. 3A, or the lower PS steel material as shown in FIG. 4A (120) can be bent using the block-out part reinforcement 130 to increase the bending resistance of the negative moment section of the full PC continuous slab 100.

Here, when the lower PS steel material 120 is bent through the block-out reinforcement member 130, a pair of lower steel bars 142 and 142 between the block-out reinforcement members 130 and 130 facing each other, as shown in FIGS. 4A and 4B. and a pair of upper steel bars 144 and 144 are connected, and a strand or PS steel wire, which is the lower PS steel material 120 to be buried in the PC bottom plate 110, through each pair of lower steel bars 142 and upper steel bars 144 It is possible to increase the bending resistance of the negative moment section of the full PC continuous slab 100 by allowing tension to be introduced after being bent.

At this time, the lower PS steel 120 may be tensioned after being mounted through the rolling cap 143 rotatably inserted into the pair of lower steel bars 142 and 142 and the pair of upper steel bars 144 and 144 respectively. In this case, the strand 114 can be tensioned without friction using the rolling cap 143.

On the other hand, as shown in FIG. 6, a PS steel bending guide tube 136 bonded to the side of the block-out reinforcing bridge 132 of the block-out reinforcing member 130 is installed, and the strand to be buried in the PC bottom plate 110 ( 120) is inserted into the guide tube 136 for changing the direction of the strand, and after being bent, it is possible to increase the bending resistance of the moment section of the full PC continuous slab 100 by introducing a tension force.

As such, the present invention, when the lower PS steel material 120 is not applied to the full PC continuous slab 100 having the blockout portion 112, reinforces the blockout portion 112 through the blockout portion reinforcing material 130. When realized, and the lower PS steel material 120 is applied to the full PC continuous slab 100, prestress can be introduced through the bending arrangement of the lower PS steel material 120 to the blockout portion reinforcement 130.

On the other hand, for the joint between the adjacent full PC continuous slabs 100 and 100, as shown in FIG. 7, bolt boxes 150 are installed in a plurality of places along the long sides of both sides of the upper surface of the PC bottom plate 110, and the bolt boxes ( 150) may be configured by fixing a plurality of height adjustment bolts 160 protruding upward.

Therefore, as shown in FIGS. 7b and 7c, when connecting adjacent full PC continuous slabs (100 and 100), the height adjustment bolt 160 installed on one side full PC continuous slab 100 and the other side full PC continuous slab 100 installed After assembling the joint steel 170 to the height adjusting bolt 160, the height can be adjusted by tightening and adjusting the nut 162. The joint steel 170 may have an I or ┻ shape.

On the other hand, as shown in FIGS. 10A and 10B, the lower PS steel 120 is a PS steel wire, and is installed with a concrete and non-attached non-attached section in the parent moment section, and is installed at the top of the PC floor plate 110 in the width direction. An upper PS steel material (120a) is installed, which is arranged and buried in the longitudinal direction at intervals to introduce compressive stress to the concrete cross section, but the upper PS steel material (120a) is a PS steel wire, and is non-attached to concrete in the positive moment section. can be installed with

Here, the non-attached section of the lower PS steel member 120 means the support point section and the cantilever section of each girder 10.

In this way, the lower PS steel member 120 and the upper PS steel member 120a are installed with a non-attached section, so that the bending moment is reduced and the shear capacity is improved.

The construction method of the full PC continuous slab 100 configured as described above will be described.

First, after lifting the full PC continuous slab 100 to the upper part of the girder 10 as shown in FIG. The full PC continuous slab 100 is placed at the support portion of (10).

Then, as shown in FIG. 8A, the on-site concrete 190 is poured and filled in the blockout part 112 of the PC floor plate 110 to bury the shear connector 12 and the blockout part reinforcing material 130.

In this way, the cast-in-place concrete 190 is filled in the block-out portion 112, and the girder 10 side shear connector 12 is combined with the cast-in-place concrete 190 and connected to the block-out portion reinforcing member 130.

Thereafter, each time the lifting and mounting of the full PC continuous slab 100 is repeated, the adjacent full PC continuous slabs 100 and 100 are interconnected. At this time, as shown in FIGS. 7b and 7c, the height adjustment bolt 160 installed in the bolt box 150 of the full PC continuous slab 100 on one side and the height adjustment bolt installed on the bolt box 150 of the other full PC continuous slab 100 After assembling the joint steel 170 in 160, the nut 162 is fastened to connect and adjust the height between the adjacent full PC continuous slabs 100 and 100.

In this way, according to the present invention, the full PC continuous slab 100 has a length corresponding to the width of the bridge and is not affected by the shear connector 12 through the blockout portion 112 at the support portion of the girder 10. It can be mounted on the girder 10, and the block-out part 112 is reinforced by the block-out part reinforcing material 130, so that the cross-sectional force (bending, shear) at the support part of the full PC continuous slab 100 is increased. .

In addition, when trying to introduce tension into the full PC continuous slab 100 through the lower PS steel material 120, the upper and lower steel bars 143 and 142 or PS with the strand 114 installed in the block-out reinforcement 130 By using the steel bending guide tube 136 to bend and place the tension force, the tension force is introduced to the upper end of the parent moment of the full PC continuous slab 100, and the cross-sectional rigidity is further improved.

In addition, in the case of constructing the deck of the bridge through the full PC continuous slab 100, the present invention does not require the construction of a separate PC cantilever or the installation and reinforcement of a cantilever formwork at the site, as in the prior art. and the air is shortened.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and variations without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by these variations and modifications, but is limited only by the claims appended below.

100: Full PC continuous slab
110: PC bottom plate
130: blockout part reinforcement
131: lower fixing plate
132: blockout part reinforcement bridge
132a: side opening
133: upper fixing plate
136: guide pipe for bending PS steel
142: lower steel bar
143: rolling cap
144: upper steel bar
150: bolt box
160: bolt for height adjustment
170: joint steel

Claims (10)

In the full PC continuous slab 100 installed on a plurality of girders 10 parallel to each other,
A certain width (W) and both ends each have a cantilever length (L1) that protrudes further by a certain amount from the support portion of the outermost girder (10), and is penetrated in the thickness direction at each position corresponding to the support portion of each girder (10) A PC bottom plate 110 made of concrete with a blockout part 112 formed so that the shear connector 12 protruding from the upper part of the girder 10 can be inserted;
A lower PS steel member 120 that is placed and buried in the longitudinal direction at regular intervals in the width direction at the bottom of the PC floor plate 110 to introduce compressive stress to the concrete cross section;
Block-out portion reinforcing materials 130 respectively located in the block-out portion 112 and at the same time buried in the lower part of the PC bottom plate 110 to reinforce the corresponding block-out portion 112; includes,
The block-out part reinforcing material 130 protrudes upward from a pair of lower anchoring plates 131 and 131 buried in the PC bottom plate 110 and the lower anchoring plates 131 and 131 at a certain height and is connected to the lower anchoring plates 131 and 131. It consists of a block-out part reinforcement bridge 132 and an upper anchoring plate 133 synthesized with cast-in-place concrete by connecting the top of the block-out part reinforcement bridge 132 horizontally,
Adjacent blockout reinforcements 130 and 130 are connected to each other through a pair of lower steel bars 142 and 142 and a pair of upper steel bars 144 and 144, and the bending resistance of the negative moment section of the full PC continuous slab 100 Full PC continuous slab reinforced with branch portion, characterized in that the tension force is introduced after the lower PS steel material 120 is bent through each pair of lower steel bar 142 and upper steel bar 144 to increase. delete delete According to claim 1,
The lower PS steel material 120 is mounted through a rolling cap 143 rotatably inserted into a pair of lower steel bars 142 and 142 and a pair of upper steel bars 144 and 144, respectively, and then the branch portion characterized in that tension is made. Reinforced full PC continuous slab. According to claim 1,
The block-out reinforcement bridge 132 is full PC continuous slab reinforced with support parts, characterized in that trapezoidal side openings 132a are formed to increase the composite force with cast-in-place concrete. In the full PC continuous slab 100 installed on a plurality of girders 10 parallel to each other,
A certain width (W) and both ends each have a cantilever length (L1) that protrudes further by a certain amount from the support portion of the outermost girder (10), and is penetrated in the thickness direction at each position corresponding to the support portion of each girder (10) A PC bottom plate 110 made of concrete with a blockout part 112 formed so that the shear connector 12 protruding from the upper part of the girder 10 can be inserted;
A lower PS steel member 120 that is placed and buried in the longitudinal direction at regular intervals in the width direction at the bottom of the PC floor plate 110 to introduce compressive stress to the concrete cross section;
Block-out portion reinforcing materials 130 respectively located in the block-out portion 112 and at the same time buried in the lower part of the PC bottom plate 110 to reinforce the corresponding block-out portion 112; includes,
The block-out part reinforcing material 130 protrudes upward from a pair of lower anchoring plates 131 and 131 buried in the PC bottom plate 110 and the lower anchoring plates 131 and 131 at a certain height and is connected to the lower anchoring plates 131 and 131. It consists of a block-out part reinforcement bridge 132 and an upper anchoring plate 133 synthesized with cast-in-place concrete by connecting the top of the block-out part reinforcement bridge 132 horizontally,
The block-out part reinforcing material 130 is bonded to the side of the block-out part reinforcement bridge 132, and a PS steel bending guide pipe 136 is installed, and PC bottom plate 110 to increase the bending resistance of the negative moment section ) Full PC continuous slab with reinforced support, characterized in that the lower PS steel material 120 buried in the moment section is inserted into the guide tube 136 for changing the direction of the strand and bent, and then tension is introduced. According to claim 1 or 6,
Bolt boxes 150 are installed in a plurality of places along the long sides of both sides of the upper surface of the PC bottom plate 110, and a plurality of height adjustment bolts 160 protruding upward are fixedly installed in the bolt box 150 , The connection and height adjustment between the adjacent full PC continuous slabs (100 and 100) is performed by the height adjustment bolt 160 installed on one side full PC continuous slab 100 and the height adjustment bolt 160 installed on the other full PC continuous slab 100. ) After assembling the joint steel 170, the nut 162 is tightened and adjusted to form a full PC continuous slab reinforced with support parts. According to claim 1 or 6,
The lower PS steel 120 is installed with a concrete and non-attached section in the parent moment section,
At the top of the PC bottom plate 110, an upper PS steel member 120a is installed, arranged and buried in the longitudinal direction at regular intervals in the width direction to introduce compressive stress into the concrete cross section, and the upper PS steel member 120a has a positive moment section. A full PC continuous slab reinforced with a support portion, characterized in that it is installed with a non-attached section attached to concrete. After lifting the full PC continuous slab 100 according to claim 1 or 6 to the upper part of the girder 10, the shear connector 12 protruding from the upper part of the girder 10 is a blockout part ( 112) to place the full PC continuous slab 100 on the supporting part of the girder 10;
burying the shear connector 12 and the blockout reinforcing material 130 by pouring and filling the blockout portion 112 of the PC floor plate 110 with in-situ concrete;
Each time the lifting and mounting of the full PC continuous slab (100) is repeated, interconnecting the adjacent full PC continuous slabs (100 and 100); Methods of constructing concrete decks of bridges. According to claim 9,
When connection and height adjustment between adjacent full PC continuous slabs (100 and 100) is required, the height adjustment bolt 160 installed in the bolt box 150 of the one full PC continuous slab 100 and the other full PC continuous slab (100) Concrete of a bridge using a full PC continuous slab reinforced with a support portion, characterized in that it is formed by assembling the joint steel 170 to the height adjustment bolt 160 installed in the bolt box 150 of ) and then fastening the nut 162 How to construct a floor plate.

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