KR102144400B1 - Psc girder for precast slab and construction method thereof - Google Patents

Abstract

The present invention relates to a PSC girder for a precast slab and a bridge constructing method using the same, wherein the bridge constructing method allows a shear connecting material of the PSC girder to be received in a shear pocket formed on the precast slab regardless of construction and manufacture errors and increases manufacturing efficiency of the PSC girder to enable quick and economical bridge construction. The PSC girder for a precast slab includes: an upper surface groove formed on an upper surface of a concrete girder part; and a shear pocket housing including a housing for a pocket, of which a lower end is inserted into the upper surface groove and which is extended in a longitudinal direction so that an inner space (S) is formed on the upper surface of the concrete girder part so that an upper side of the inserted lower end is exposed, and a shear bolt inserted downwards into the inner space (S) to be connected to a jig for a housing, of which the upper surface is exposed to the bottom of the upper surface groove.

Description

PSC girder for precast slab and bridge construction method using it {PSC GIRDER FOR PRECAST SLAB AND CONSTRUCTION METHOD THEREOF}

The present invention relates to a PSC girder for precast slab and a bridge construction method using the same. More specifically, the PSC girder's shear connector is accommodated in the shear pocket formed on the precast slab regardless of construction and manufacturing errors, while improving the manufacturing efficiency of the PSC girder, enabling faster and economical bridge construction. It relates to a girder and a bridge construction method using the same.

1A is a diagram showing an exemplary construction of a conventional precast slab and a PSC girder.

The PSC girder 1 has a reinforcing bar assembly 4 and 5 laid inside, and is manufactured so that prestress is introduced using a PC tensioning material not shown.

Accordingly, the PSC girder (1) is mounted on the bridge substructure in a manner in which both ends are supported in the axle direction (longitudinal direction), and the slab (10) is integrated on the upper surface of the PSC girder (1) to construct a girder bridge, etc. It will be constructed.

This slab 10 is usually constructed separately from the construction of the PSC girder (1).

Therefore, after the PSC girder (1) is mounted, the slab is constructed.However, the slab formwork is separately installed and the slab concrete is poured into the concrete slab method, but recently, the precast slab (10) is pre-fabricated. , A precast slab method that is integrated on the upper surface of the girder is introduced.

Specifically, the precast slab 10 is extended in the transverse direction, but the shear pocket 13 is attached to the precast slab 10 in order to combine the precast slab 10 and the PSC girder 1 It can be seen that it is formed in advance.

The shear pocket 13 is formed to penetrate the precast slab 10 for receiving the shear connector for the girder, such as vertical bolts having a fixed lower end so as to protrude from the upper surface of the PSC girder (1).

However, in protruding and extending the shear connector 2 to the upper surface of the PSC girder 1, the shear pocket 13 has a limited position and size due to manufacturing errors and construction errors. There was a problem that the shear connector could not be accommodated.

Accordingly, FIG. 1A shows that an anchor bolt is used as the shear connector 2, but a plurality of shear sleeves 6 are embedded in the upper surface of the PSC girder 1, and the shear sleeve 6 exposed to the shear pocket 13 is It can be seen that the method of fastening the anchor bolt 2 is adopted.

At this time, the shear sleeve 6 is a vertical pipe member with a threaded portion formed on the inner surface thereof, which is a shear connector, which is to secure a function as a shear connector by sufficiently rotating and fastening the anchor bolt under the upper surface of the PSC girder 1. .

However, in order to make the PSC girder (1) so that the upper surface of the PSC girder (1) is embedded in the upper surface of the PSC girder (1) in advance, the shear sleeve (6) in the form of a vertical pipe member is placed on the inner upper part of the form for the PSC girder (1). With 6) set vertically, concrete must be poured inside the formwork for PSC girder (1).

However, since the reinforcing bar assembly (4, 5) is placed inside the formwork for the PSC girder (1) in advance, there is a problem that the shear sleeve (6) cannot be set to the desired position and quality control is not performed, The position error of the shear sleeve 6 inevitably occurs.

In addition, in order to set the shear sleeve 6, in the case of FIG. 1A, after installing the bending channel 7 in the reinforcing bar assembly 4, 5, the shear sleeve 6 is installed through the bending channel 7 You can see that it is using the method.

However, there is a limit to be placed in a number of bending channels (7) reinforcement assembly (4, 5), and it is assumed that the location of the bending channel (7) is formed in the original position during the manufacturing and mounting process of the PSC girder (1). There is a case that cannot be done.

That is, after the PSC girder (1) is manufactured in a factory, the camber is formed in a way that the central part is curved upward in the concrete curing process, and the PSC girder (1) manufactured with a long extension length is a bending channel (7) on the upper surface. There are many cases where the position of the over shear sleeve 8 is not formed in the correct position.

In addition, since the construction load of the PSC girder (1) is generated during transport and installation after fabrication, there are many cases of early microscopic cracks.If such cracks are advanced, corrosion of the bending channel (7) may be caused. Considering the manufacturing error that occurs in the manufacturing process of the girder (1), several limitations arise.

Figure 1b shows another construction example of the conventional precast slab and PSC girder.

That is, the use of the shear sleeve (6) is the same, but a plurality of these shear sleeves (6) are installed using a reinforcement grating (12), and are exposed to the shear pocket (13) among the plurality of shear sleeves (6). It can be seen that the shear bolt 31 is fastened to the one that is being used.

At this time, it can be seen that the shear bolt 31 is formed integrally with the reinforcing bar grating 12 so that it is arranged to be supported on the upper surface of the reinforcing bar assembly 11 of the PSC girder 10.

However, this method has a limitation that it may be somewhat inefficient because a significant amount of shear sleeve 6 must be integrally installed on the reinforcement grating 12,

After the PSC girder (1) is manufactured in factories, etc., the camber must be formed in a way that the central part is curved upward in the concrete curing process.

PSC girder (1) is a precise PSC girder to combine shear bolts with precast slab 40 and PSC girders using shear sleeves, considering that construction loads are generated during transport and installation after fabrication. It can be seen that the construction of girders must be premised.

In addition, PSC girders (1) have to be manufactured in various cross-sectional shapes depending on the height and length of span. Because the cross-section and height of PSC girders (1) are different for each bridge, it is possible because the cost of manufacturing the formwork is required. When the PSC girder (1) is simply manufactured, transported, and mounted in large quantities, there is a problem that it is difficult to control the transverse distortion or camber occurrence due to the introduced prestress, so quality control in the manufacturing, transportation and installation process There is a limit in that it is not easy to solve the problem.

Republic of Korea Patent No. 10-1957932 (Name of invention: girder and bridge construction method using girder, publication date: March 14, 2019) Korean Patent No. 10-0535157 (Name of invention: connection structure between precast deck and prestressed concrete girder and connection construction method thereof, publication date: December 7, 2005)

Accordingly, the present invention simplifies the cross section of the PSC girder and secures the economic feasibility of operating the steel form, and mounts it on the substructure of the bridge, but does not increase the height of the cross section of the PSC girder and minimizes the lateral spacing. Precast slab that is effective for quality control and construction management by mounting it on a bridge so that it can be constructed, and effectively resists initial cracks caused by camber and construction loads occurring in the manufacturing, transportation, and installation process of PSC girders. It is a technical task to solve the provision of PSC girder for use and a bridge construction method using the same.

In addition, the present invention improves the synthesis effect of the precast slab and the PSC girder by more effectively absorbing the construction and manufacturing errors that occur in accommodating the shear bolt in the shear pocket of the precast slab. It is a technical task to solve the provision of PSC girder for precast slab and bridge construction method using the same.

The PSC girder for precast slab of the present invention for achieving the above object,

Upper groove formed on the upper surface of the concrete girder: And a pocket housing extended in the longitudinal direction so that an inner space (S) is formed on the upper surface of the concrete girder so that the lower end is inserted into the upper groove and exposed above the inserted lower end; And A shear pocket housing including; and a shear pocket housing including; a shear bolt inserted downward into the inner space S and connected to a first connection nut located under a housing jig with an upper surface exposed on the bottom surface of the upper groove. By separating the bolt from the housing jig, the pocket housing is disassembled from the concrete girder part, and the separated shear bolt is reconnected to the first connection nut located under the housing jig exposed to the upper groove. It is formed on the upper surface, and the housing jig is installed at a constant length in the area where the shear pocket is located or continuous over the entire extended length of the PSC girder, and the upper surface is buried inside the PSC girder so that it is exposed to the upper surface groove of the PSC girder. As a horizontal plate to be installed, a shear bolt hole is formed so that the lower shear connector and the shear bolt are connected by the first and second connection nuts, and a number of transverse spacers are installed at the bottom, so that the upper surface of the rebar assembly of the PSC girder The lower end of the shear bolt is connected to the upper part of the first connection nut located under the housing jig, and the upper end of the lower shear connector penetrates into the horizontal plate jig of the housing jig around the first connection nut. It is finally connected by a second connection nut, and the lower shear connector is formed to be set to be buried at regular intervals in the longitudinal direction of the PSC girder in the form of vertical bolts on the upper edge of the PSC girder, and the lower shear connector and the second connection nut The shear bolts connected by are staggered to serve as shear connectors of the PSC girder by the housing jig.

Bridge construction method using the PSC girder for precast slab of the present invention for achieving the above object,

(a) Upper groove formed on the upper surface of the concrete girder: and for pockets formed longitudinally so that an inner space (S) is formed on the upper surface of the concrete girder so that the lower end is inserted into the upper groove and exposed above the inserted lower end. housing; And a shear bolt inserted downward into the inner space (S) and connected to a housing jig with an upper surface exposed on the bottom surface of the upper surface groove; and a shear pocket housing including a PSC girder for precast slab comprising: ; (b) mounting a PSC girder for a precast slab provided to support both ends of the bridge substructure; (c) separating the shear bolt from the housing jig to disassemble the pocket housing so that the upper groove is exposed on the concrete girder; And (d) reconnecting the separated shear bolt to the first connection nut located under the housing jig exposed to the upper groove so that the shear connector is formed on the upper surface of the concrete girder; including, the (a) The housing jig of step) is installed with a constant length in the area where the shear pocket is located or continuous over the entire extended length of the PSC girder, and the upper surface is a horizontal plate installed to be buried inside the PSC girder so as to be exposed to the upper surface groove of the PSC girder. As a shear bolt hole is formed, the lower shear connector and the shear bolt are connected by the first and second connection nuts, and a number of transverse spacers are spaced apart from each other and are supported on the upper surface of the rebar assembly of the PSC girder. The lower end of the shear bolt is connected to the upper part of the first connection nut located under the housing jig, and the upper end of the lower shear connector penetrates through the horizontal plate jig of the housing jig around the first connection nut. The lower shear connector is formed to be set to be buried at regular intervals in the longitudinal direction of the PSC girder in the form of vertical bolts on the upper edge of the PSC girder, and the lower shear connector is connected by the second connecting nut. A method of constructing PSC girders for precast slabs in which bolts are staggered to act as shear connectors of PSC girders by housing jigs.

The PSC girder according to the present invention is not a method in which the cross-sectional height is increased to increase the bending stiffness and constructed as a minority mold, but the PSC girder is manufactured by simplifying the cross-section, but is manufactured with a low cross-sectional height, and the insufficient bending stiffness is a multi-cast method. In order to quickly and economically manufacture the PSC girder, it is possible to secure the convenience and speed of manufacture by using the formwork for the girder of the standardized cross section.

Accordingly, the PSC girder according to the present invention may have relatively large initial tensile cracks on the lower surface due to construction loads during manufacturing, transportation, and installation, transverse curvature in the prestress introduction process, and longitudinal linearity due to the introduction of camber. This can be solved through the shear pocket housing, and since some of the shear pocket housing is finally dismantled and can be reused, economical efficiency can also be secured.

In addition, the upper groove of the PSC girder secured by the shear pocket housing communicates with the shear pocket of the precast slab and is filled by a filler so that it is integrated. It is possible to improve the synthesis effect of the precast slab.

In addition, the present invention allows the lower end of the shear bolt to be fastened to the upper portion of the first connecting nut located under the housing jig exposed to the upper groove secured through the shear pocket housing, and fastened to the lower portion of the first connecting nut. By the lower shear connector, the shear bolt can sufficiently secure sufficient pull-out resistance performance by the lower shear connector.

In addition, the housing jig divides the shear bolt hole of the housing jig into the main and the auxiliary, even if it is difficult to set the desired position due to interference with the lower shear connector and the rebar assembly of the PSC girder so that the shear bolt can exhibit pull-out resistance. It is possible to increase the efficiency of the installation work of shear bolts in the shear pockets of the precast slab by allowing them to be easily fastened to the bottom of the housing jig.

In addition, because the shear pocket housings are all arranged on the upper surface of the PSC girder and serve as a compression stiffener, they are very effective in PSC girders that are manufactured so that the cross-sectional height is not large, and the gap between the pocket holes of the precast slab and the shear bolts You will play a role again.

1A and 1B are exemplary construction views of a conventional precast slab and PSC girder,
2A, 2B, and 2C are perspective views of the PSC girder for precast slab and the front pocket housing of the present invention;
Figure 2d is a combination configuration of the precast slab PSC girder and precast slab of the present invention,
Figures 3a and 3b is a flow chart of a bridge construction method using the PSC girder for precast slab of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless specifically stated to the contrary.

[PSC girder 100 for precast slab of the present invention]

2A, 2B, and 2C are perspective views showing the configuration of the PSC girder for precast slab and the front pocket housing of the present invention, and FIG. 2D is a diagram showing the combination of the PSC girder for precast slab and the precast slab of the present invention. .

The PSC girder 100 of the present invention has a reinforcing bar assembly (not shown) and a PC wire and a concrete girder unit 110 formed of an upper flange, a abdomen, and a lower flange as an I-shaped cross section, for example, as shown in FIG. 2A. It is a prestressed concrete girder manufactured such that the same tension member 120 is disposed so that the prestress is introduced in the longitudinal direction.

In general, conventional PSC girders are mounted so that both ends are supported on the upper surface of the lower structure (400, abutment, piers, etc.) of the bridge structure, and have various cross-sectional heights depending on the span length and bridge height, and both ends are It is also formed into a sphere with a square cross section.

Therefore, since the I-shaped section in the longitudinal direction is often manufactured in the form of a variable section, the steel formwork needs to be changed or newly manufactured every time the PSC girder is manufactured, which causes an increase in the cost for the PSC girder.

Accordingly, in the present invention, a plurality of PSC girders are manufactured in a standard cross section (standardized) using the same formwork and tension member, and they are mounted on the lower structure of the bridge structure, but the required bending stiffness is adjusted by adjusting the number of installations, This is because lowering the manufacturing cost of PSC girders is more economical than installing 1-2 more PSC girders.

Accordingly, the bridge structure on which the PSC girder of the present invention is mounted is suitable for a short span ramen bridge that can be constructed by synthesizing with a precast slab after passing through the PSC girder in a simple support type without a long span.

Accordingly, the PSC girder in the present invention is not large in cross section, but is mass-produced to the required length using the same steel formwork, and after installation, the PSC girder for precast slab is integrated with the precast slab 300 to be constructed. It will be referred to as (100, PSC girder).

At this time, the PSC girder 100 is, in the end, simplified production in order to secure economical efficiency, and the problem is that in the production, transportation and construction process, as time elapses after demolding, the tension of the tension member is twisted in the longitudinal and transverse directions due to drying and contraction. , Initial cracking, and damage in the construction process may occur.

Accordingly, shear for installing a shear connector installed to penetrate the shear pocket 310 formed in the precast slab 300 while preventing in advance crack, warping, buckling, cracking, and damage in the manufacturing, transportation and construction process The pocket housing 200 is used.

At this time, after the shear bolt 240 is installed on the upper surface of the PSC girder 100 while the pocket housing 230 constituting the shear pocket housing 200 is disassembled, the shear pocket of the final precast slab 300 ( 310) is mounted on the upper surface of the PSC girder 100 to accommodate the shear bolt 240, and the filler 320 is filled in the shear pocket 310 so that the shear bolt 240 is buried to complete the bridge.

The PSC girder 100 includes a concrete girder unit 110 including an upper flange, an abdomen and a lower flange, as shown in FIGS. 2A, 2B, 2C, and 2D, and a tension member 120 for introducing prestress is a neutral axis It can be seen that both ends of the concrete girder unit 110 are placed in the lower part and are manufactured in a form fixed after tension on both end surfaces, etc., and a reinforcing bar assembly (not shown) is arranged inside, and in the case of FIG. 2A, I It can be seen that the concrete girder part 110 of the type cross section is shown.

Accordingly, compression cracking may occur at the upper edge of the neutral axis of the concrete girder part 110 of which the cross-sectional height is not large, and damage may occur due to impact during the stacking process, and the shear pocket 310 of the precast slab 300 Since the inserted shear connector must also be formed on the upper surface of the concrete girder part 110, the present invention is solved by installing a shear pocket housing 200 on the upper surface of the concrete girder part 110.

Accordingly, the shear pocket housing 200 is manufactured in a state in which the lower portion is inserted into the upper surface of the PSC girder 100 as shown in FIGS. 2A, 2B, 2C, and 2D, and is disassembled after mounting to enable reuse. , And a lower shear connector 210, a housing jig 220, a pocket housing 230, and a shear bolt 240.

At this time, the lower shear connector 210 and the housing jig 220 are permanently buried when the PSC girder 100 is manufactured, and the pocket housing 230 is disassembled when the precast slab 300 is constructed and reused. The bolt 240 serves as a shear connector for integration of the precast slab 300 and the PSC girder 100 using the housing jig 220 together with the lower shear connector 210.

Accordingly, the lower shear connector 210 is buried at regular intervals in the longitudinal direction of the PSC girder 100 in the form of vertical bolts on the upper surface of the PSC girder 100, as shown in FIGS. 2A, 2B, 2C, and 2D. It can be seen that it is formed to be set as possible.

As described above, referring to FIG. 2D, the upper surface of the housing jig 220 to be described later is exposed in the upper surface groove 130 formed on the upper surface of the steel mold of the PSC girder 100.

Accordingly, referring to FIG. 2C, the lower shear connector 210 is fastened to and supported by the first connection nut 221 located under the housing jig 220 exposed to the bottom of the upper groove 130. , It serves as a shear connector together with a shear bolt 240 that penetrates through the housing jig 220 and is fastened to the lower end of the first connection nut 221.

That is, in the lower shear connector 210, for example, a vertical bolt portion extending upward from the upper surface of the lower head portion is formed, and the upper end of the vertical bolt portion is formed by a screw portion, so that the first connection nut 221 located under the housing jig 220 It will be installed to be fastened to.

At this time, there is a case in which the shear bolt 240 and the lower shear connector 210 cannot be connected in a vertical line to each other by using the first connecting nut 221 as a coupler based on the housing jig 220.

That is, as shown in Figure 2c, because the shear bolt 240 must be accommodated in the shear pocket 310 of the precast slab 300, the installation position is determined, and the position of the lower shear connector 210 is also determined based on this. The lower shear connector 210 is connected to the first connecting nut 221 when the lower shear connector 210 is interfered with the position by the reinforcing bar assembly placed inside the PSC girder 100. There occurs a case where the and shear bolt 240 cannot be connected to each other in a vertical line.

This is a kind of manufacturing error, and in this case, the housing jig 220 is installed with a second connection nut 221b on the upper surface of the pocket housing 230 through the pocket housing 230 and the housing jig 220. And, the shear bolt 240 penetrates through the housing jig 220 so that the lower end is fastened to the lower first connection nut 221 to be connected.

Since the lower shear connector 210 is set as a vertical bolt inside the PSC girder 100, it also serves as a compression stiffener at the upper edge of the PSC girder 100.

Next, the housing jig 220 is a first connection nut 221, a horizontal plate jig 222, a shear bolt hole 223, a horizontal spacer, as shown in FIGS. 2A, 2B, 2C, and 2D. As including 224, the lower portion is to be connected to the lower shear connector 210, the upper portion serves as an intermediate member so that the shear bolt 240 is connected.

Accordingly, the first connection nut 221 is positioned under the horizontal plate jig 222 as shown in FIGS. 2B, 2C, and 2D to serve as a coupler connecting the shear bolt 240 and the lower shear connector 210 to each other. Will do.

That is, the screw portion formed on the upper end of the lower shear connector 210 is directly coupled to the first connection nut 221 located under the horizontal plate jig 222,

The lower end of the shear bolt 240 passes through the horizontal plate jig 222 and is fastened together with the first connection nut 221 so that the lower shear connector 210 and the shear bolt 240 are connected to the first connection nut 221. As a result, it is connected in a vertical line up and down to serve as a shear connector as a coupler.

In this case, as described above, a case in which the lower shear connector 210 cannot be directly connected to the first connection nut 221 located under the horizontal plate jig 222 may occur.

This can be said to be a case where the installation of the lower shear connector 210 cannot be set at a predetermined position due to the reinforcing bar assembly of the PSC girder 100 and corresponds to a kind of manufacturing error.

Accordingly, the present invention is set to a position where the lower shear connector 210 can be installed, as shown in FIG. 2C, and then passes through the horizontal plate jig 222 and finally on the upper surface of the horizontal plate jig 222 (precast slab after mounting the bridge substructure. Before installation) It is fixed by the second connection nut (221b).

At this time, since the installation position of the shear bolt 240 must be inserted into the shear pocket 310 of the precast slab 300, it is difficult to change.

Accordingly, the lower end of the shear bolt 240 passes through the horizontal plate jig 222 and is fastened to the first connection nut 221 located under the horizontal plate jig 222.

At this time, the lower shear connector 210 penetrates the horizontal plate jig 222 upward and is fixed to the upper surface of the horizontal plate jig 222 by a final second connection nut 221b.

To this end, a plurality of shear bolt holes 223 are formed in the horizontal plate jig 222 so that the lower shear connector 210 and the shear bolt 240 can pass through and be fastened.

Next, the horizontal plate jig 222 is a number installed so as to be buried inside the PSC girder 100 so that the upper surface is exposed to the upper surface groove 130 of the PSC girder 100 as shown in FIGS. 2B, 2C and 2D. As a flat plate, it serves as a compression stiffener, and a shear bolt hole 223 is formed so that the lower shear connecting member 210 and the shear bolt 240 are formed by the first connecting nut 221 and the second connecting nut 221b. It is also the part that connects.

This horizontal plate jig 222 is a continuous or shear pocket 310 over the entire extended length of the PSC girder 100 so that the shear bolt 240 is accommodated and set in the shear pocket 310 of the precast slab 300 You can install it in a certain length at the location where it is located.

Based on this horizontal plate jig 222, as shown in FIG. 2B, the shear bolt 240 and the lower shear connector 210 are set in a straight line in the first connection nut 221 located under the horizontal plate jig 222 ,

The shear bolt 240 is connected to the first connection nut 221 located under the horizontal plate jig 222, and the lower shear connector 210 passes through the final horizontal plate jig 222 to the top surface of the horizontal plate jig 222 But set to be finally connected by the second connection nut (221b),

The lower shear connector 210 and the shear bolt 240 are set as close to each other as possible so that the shear bolts 240 connected by the lower shear connector 210 and the second connection nut 221b are set to be alternately set.

Next, the shear bolt hole 223 is formed to penetrate the horizontal plate jig 222 as shown in FIGS. 2B, 2C and 2D, and the lower shear connector 210 and the shear bolt 240 are fastened to be connected. It acts as a through hole that allows it to be made.

Accordingly, the lower shear bolt hole 223 is basically formed at the portion where the first connection nut 221 is formed so that the shear bolts 240 can be set to be alternately set on a vertical line, and the first connection nut 221 It is formed as a main to communicate,

The shear bolt holes 223 adjacent to the shear bolt hole 223 are formed as an aid to absorb the change in the setting position of the lower shear connector 210 due to manufacturing errors.

Next, the transverse spacer 224 is positioned so that the upper surface of the housing jig 220 is exposed to the upper surface groove on the upper surface of the rebar assembly of the PSC girder 100, as shown in FIGS. 2B, 2C and 2D. It is to prevent a positional change due to concrete pouring while setting, and is formed so as not to block the shear bolt hole 223 while allowing a plurality of horizontal plate jig 222 to be spaced apart and integrated into the bottom surface.

Since the horizontal plate jig 222 is in the form of a horizontal plate, the transverse spacer 224 may be installed so as to be spaced apart from a plurality of longitudinal spacers extending a certain length in the transverse direction using reinforcing bars.

As a result, the transverse spacer 224 mainly serves to prevent transverse cracks, breakages, warping, and buckling on the upper surface of the PSC girder 100.

Next, the pocket housing 230, as shown in Figs. 2A, 2B, 2C, and 2D, compressive cracks, warps, and upper edges of the upper edge of the neutral axis in the manufacturing process of the PSC girder 100 having a small cross-sectional height. It is installed in a state where the lower end is embedded in the upper surface of the concrete girder unit 110 to resist buckling, damage in the process of placing, transporting, and mounting the PSC girder 100.

According to FIG. 2A, the pocket housing 230 is formed of a U-shaped cross-section member with an open upper portion in a cross-section of the upper beam, so that the upper surface of the housing jig 220 is supported on the upper surface of the steel formwork when the concrete girder part 110 is manufactured. By placing, the lower end is buried in the upper edge of the PSC girder 100, and the lower upper part is formed by pouring concrete inside the steel mold in a state set to be exposed to the outside.

That is, the pocket housing 230 serves to form the upper groove 130 while the lower end is buried in the upper edge of the PSC girder 100, while the concrete is not poured in the inner space S, so the shear bolt 240 It can be seen that the lower end of) serves as a housing to be fastened to the first and second connection nuts 221 and 221b located on the housing jig 220.

In addition, the pocket housing 230 itself serves to compress and reinforce the upper edge of the concrete girder unit 110 together with the lower shear connector 210 and the housing jig 220, and after curing the concrete girder unit 110 It plays a role of controlling cracks, etc. and controlling damage during transportation.

This pocket housing 230 is formed to extend in the longitudinal direction while having a certain length so as to be formed corresponding to the position of the shear pocket 310 of the precast slab 300. It can be formed so as to be spaced apart from each other in succession or multiple over.

In addition, when the pocket housing 230 is separated from the upper surface of the concrete girder part 110, the upper surface groove 130 is naturally formed, and the upper surface of the horizontal board jig 222 constituting the housing jig 220 described above is exposed as it is. .

Accordingly, the lower end of the shear bolt 240 is fastened to the exposed first and second connection nuts 221 and 221b of the housing jig 220, and the shear bolt 240 and the lower portion are connected through the housing jig 220 as a medium. The shear connector 210 is to be able to serve as a shear connector that is continuous up and down with each other.

To this end, a plurality of bolt holes are formed in the bottom plate portion of the pocket housing 230 so that the shear bolt 240 can pass therethrough.

As a result, the pocket housing 230 is disassembled prior to installation of the pre-task slab 300 and fixed to the concrete girder unit 110 by shear bolts 240 or lower shear connector 210 before mounting so that it can be reused. However, before construction of the precast slab 300, the shear bolt 240 and the second connection nut 221b are separated, and the pocket housing 230 is disassembled from the concrete girder unit 110 and reused.

That is, in a state in which the shear bolt 240 penetrates the horizontal plate jig 222 and is connected to the first connection nut 221 under the horizontal plate jig 222, the shear bolt 240 is removed from the first connection nut 221. When separated, the pocket housing 230 can be easily disassembled,

The upper end of the lower shear connector 210 passes through the horizontal plate jig 222 and the pocket housing 230 and is connected by a second connection nut 221b on the upper surface of the pocket housing 230,

When the lower end of the shear bolt 240 penetrates the horizontal plate jig 222 and is fastened to the first connection nut 221 under the horizontal plate jig 222, loosen the second connection nut 221b, When the shear bolt 240 is also separated from the first connection nut 221, the pocket housing 230 can be simply disassembled.

Next, the shear bolt 240 is located at the bottom of the upper surface groove 130 and the housing jig 220 exposed by disassembling the pocket housing 230 as shown in FIGS. 2A, 2B, 2C, and 2D. By being fastened and fixed to the first connection nut 221, it is accommodated in the shear pocket 310 of the precast slab 300, and the precast slab 300 and the precast slab 300 by the filler 320 filled in the shear pocket 310 The PSC girder 100 plays a role of being synthesized with each other.

For example, a bolt part is formed below the bolt head at the top, and a screw part is formed at the lower end, so that the first connection nut located under the housing jig 220 passes through the shear bolt hole 223 of the housing jig 220 ( It is formed by being fastened to 221).

As a result, the shear bolt 240 of the present invention plays a role as a shear connector extending to the reinforcing bar assembly inside the concrete girder part 110 of the PSC girder 100, even when using a material having an extension length connecting to the housing jig 220. You can do it.

These shear bolts 240 may be installed to accommodate the required number of shear pockets 310. At this time, when the shear bolt 240 is installed in the pocket housing 230, a spacer 241 installed so that the shear bolt 240 is in contact with the pocket housing 230 is further installed to enable a stable setting. It is desirable.

At this time, when the shear bolt 240 is separated from the first connection nut 221, the pocket housing 230 can be separated, and the lower shear connector 210 is formed with the horizontal plate jig 222 and the pocket housing 230. In a state connected to the first connection nut 221 from the upper surface of the pocket housing 230 through the pocket housing 230, when the first connection nut 221 is loosened and the shear bolt 240 is also separated, the pocket housing 230 Dismantling becomes possible.

Next, the precast slab 300 is formed in the form of a rectangular panel so that a plurality of shear pockets 310 penetrate through the precast slab 300, and the shear bolt 240 is filled by filling the filler 320 into the shear pocket 310 To be buried, but to be filled in the upper groove 130 so that the filler 320 filled in the upper groove serves as a shear key to sufficiently secure the composite performance of the precast slab 300 and the PSC girder 100 Is done.

The shear pocket 310 may be formed in a size to sufficiently accommodate the shear bolt 240, and the filler 320 may be made of non-shrink mortar.

As a result, the PSC girder 100 is mounted on the bridge substructure, and the precast slab 300 and the PSC girder 100 are combined on the upper surface of the PSC girder 100 to complete the final bridge.

[Bridge construction method using PSC girder 100 for precast slab of the present invention]

Figures 3a and 3b shows a flow chart of a bridge construction method using the PSC girder 100 for precast slab of the present invention.

The bridge construction method using the PSC girder 100 for precast slab is to mount the precast PSC girder 100 for precast slab manufactured in advance on the bridge substructure 400, and the shear pocket 310 of the precast slab 300 ), the shear bolt 240 of the PSC girder 100 for precast slab is accommodated, and then the filler 320 is completed by filling the shear pocket 310 so that the shear bolt 240 is buried.

First, as shown in FIG. 3A, a pre-fabricated PSC girder 100 for precast slab is provided. The PSC girder 100 for precast slab has both ends between the alternating portions 410 of the bridge substructure 400. It is made to have a longitudinal extension length enough to be supported.

In addition, the bottom of the concrete girder part 110 is buried in the upper groove 130 on the upper surface, and the pocket housing 230 exposed to the outside at the top of the buried part is provided with the shear bolt 240 and the shear bolt 240 It is fixed by the second connection nut (221b).

The shear bolt 240 is connected and installed to the first connection nut 221 located under the housing jig 220 through a bolt hole formed in the bottom plate portion of the pocket housing 230,

The lower shear connector 210 is fastened to the lower end of the first connection nut 221 or penetrates the horizontal plate jig 222 and the pocket housing 230 of the housing jig 220 to the upper surface of the pocket housing 230. It is connected and installed by the first connection nut 221 in.

Accordingly, the housing jig 220, the lower shear connector 210, and the pocket housing 230 are integrated with the PSC girder 100 until they are installed to prevent cracks and damage that may occur during manufacturing, transportation and construction. You can do it.

At this time, the bridge estuary structure 400 includes both abutment parts 410, and when looking at the bridge structure based on a ramen bridge, the PSC girder 100 of the present invention is formed between the upper surfaces of both abutment parts 410 in the longitudinal direction. It should be extended, but it can be seen that many are mounted in the transverse direction.

As previously discussed, the PSC girder 100 for precast slab is, in the end, simplified production to secure economical efficiency, so the cross-sectional height is not large, so it is possible to secure workability in production, transportation and construction, and many are transversely It can be seen that it was installed separately.

In addition, as shown in FIG. 2B, a precast slab 300 is provided, which serves as a slab of a bridge in the form of a rectangular panel. That is, the shear bolt 240 formed on the upper surface of the mounted precast slab PSC girder 100 is installed in a manner such that it is accommodated in the shear pocket 310 of the precast slab 300.

These precast slabs 300 are installed as a top plate of a bridge by installing a plurality of them.

To this end, the pocket housing 230 in which the lower end is embedded in the upper surface of the PSC girder 100 is disassembled.

That is, the shear bolt 240 is separated from the first connection nut 221 and the lower shear connector 210 is also separated from the second connection nut 221b so that the upper surface groove 130 and the upper surface of the horizontal plate jig 222 After allowing this to be exposed,

The separated shear bolt 240 is again connected to the first connection nut 221 under the horizontal plate jig 222 to reinstall the shear bolt 240.

Next, as shown in FIG. 3B, the filler 320 is filled in the shear pocket 310 so that the shear bolt 240 is buried, but the filler 320 is filled in the upper groove 130 by filling the upper groove 130 as well. It can be seen that the bridge is completed by playing the role of shear key. Accordingly, the precast slab 300 may be installed in a full deck method or a half deck method.

The above description of the present invention is for illustrative purposes only, and those of ordinary skill in the art to which the present invention pertains will be able to understand that other specific forms can be easily modified without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form.

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

100: PSC girder for precast slab
110: concrete girder 120: tension member
130: upper groove 200: shear pocket housing
210: lower shear connector 220: housing jig
221: first connection nut 221b: second connection nut
222: horizontal board jig
223: shear bolt hole 224: transverse spacer
230: pocket housing 240: shear bolt
300: precast slab 310: shear pocket
320: filler 400: bridge substructure
410: both shifts S: internal space of pocket housing

Claims (10)

The upper surface groove 130 formed on the upper surface of the concrete girder part 110: And
A pocket housing 230 extending in the longitudinal direction so that an inner space (S) is formed on the upper surface of the concrete girder unit 110 so that the lower end is inserted into the upper groove 130 and exposed above the inserted lower end; And A shear bolt 240 inserted downward into the inner space S and connected to the first connection nut 221 located under the housing jig 220 with the upper surface exposed on the bottom surface of the upper groove 130; Includes a shear pocket housing 200; including,
By separating the shear bolt 240 from the housing jig 220, the pocket housing 230 is disassembled from the concrete girder 110, and the separated shear bolt 240 is exposed to the upper groove 130 The shear connector is formed on the upper surface of the concrete girder part 110 by reconnecting to the first connection nut 221 located at the lower part of the jig 220,
The housing jig 220 is continuously installed over the entire extended length of the PSC girder 100 or at a portion where the shear pocket 310 is located, and the upper surface is the upper groove 130 of the PSC girder 100 As a horizontal plate installed so as to be buried inside the PSC girder 100 so as to be exposed to, a shear bolt hole 223 is formed so that the lower shear connector 210 and the shear bolt 240 are connected to the first connection nut 221, 2 It is connected by a connection nut (221b), and a plurality of transverse spacers 224 are installed spaced apart on the bottom surface to be supported and installed on the upper surface of the rebar assembly of the PSC girder,
The lower end of the shear bolt 240 is connected to the upper part of the first connection nut 221 located under the housing jig 220, and the horizontal plate jig of the housing jig 220 around the first connection nut 221 ( The upper end of the lower shear connector 210 passes through 222 and is finally connected by a second connection nut 221b, and the lower shear connector 210 has a plurality of PSCs in the form of vertical bolts on the upper edge of the PSC girder 100. It is formed to be set so as to be buried at regular intervals in the longitudinal direction of the girder 100, and the shear bolts 240 connected by the lower shear connector 210 and the second connection nut 221b are staggered to the housing jig 220 PSC girder for precast slab to act as a shear connector of the PSC girder 100 by this. The method of claim 1,
The upper surface groove 130,
The pocket housing 230 is pre-arranged at the top of the steel formwork used when the concrete girder part 110 is manufactured, and after concrete is poured into the formwork, the pocket housing 230 is dismantled and But to be formed on the upper surface of the girder portion 110,
A PSC girder for a precast slab so that the filler 320 filled in the shear pocket 310 and the upper groove 130 serves as a shear key for the precast slab 300 and the PSC girder 100. delete delete delete The method of claim 1,
The pocket housing 230,
It is formed of a U-shaped cross-section member with an open upper part in the upper part of the upper part of the girder part 110 so that it is disposed so as to be supported on the upper surface of the horizontal board jig 222 of the housing jig 220 on the upper part of the steel formwork, and the lower part is PSC It is buried in the upper surface of the girder 100 and formed by pouring concrete inside the steel formwork in a state in which the lower upper part is set to be exposed to the outside,
Since the concrete is not poured into the inner space (S), the lower end of the shear bolt 240 penetrates the bolt hole of the pocket housing 230 and the first connection nut 221 located under the housing jig 220 PSC girder for precast slab to be able to be fastened to. The method of claim 1,
The shear bolt 240,
The pocket housing 230 is disassembled and fastened to the exposed top groove 130 and the first connection nut 221 of the housing jig 220 to be fixed to the front pocket 310 of the precast slab 300. By allowing the precast slab 300 and the PSC girder 100 to be synthesized with each other by the filler 320 that is accommodated and filled in the shear pocket 310,
Shear bolt 240 is free to serve as a shear connector extending to the reinforcing bar assembly inside the concrete girder part 110 of the PSC girder 100, even if a material having an extension length connecting to the housing jig 220 is used. PSC girder for cast slab. (a) the upper surface groove 130 formed on the upper surface of the concrete girder unit 110: and the lower end is inserted into the upper surface groove 130, and the inside of the upper surface of the concrete girder unit 110 so as to be exposed above the inserted lower end A pocket housing 230 extending in the longitudinal direction to form a space S; And a shear bolt 240 connected to the housing jig 220, which is inserted downward into the inner space S and has an upper surface exposed on the bottom surface of the upper groove 130; a shear pocket housing 200 including; Providing a PSC girder 100 for a precast slab including;
(b) mounting a PSC girder 100 for a precast slab provided to support both ends of the bridge substructure 400;
(c) separating the shear bolt 240 from the housing jig 220 and dismantling the pocket housing 230 so that the upper groove 130 is exposed to the concrete girder portion 110; And
(d) The separated shear bolt 240 is reconnected to the first connection nut 221 located under the housing jig 220 exposed to the upper groove 130 so that the shear connector becomes the concrete girder part 110 Including; to be formed on the upper surface of the
The housing jig 220 of the step (a) is continuously installed over the entire extended length of the PSC girder 100 or at a portion where the shear pocket 310 is located, and the upper surface of the PSC girder 100 As a horizontal plate installed to be buried in the PSC girder 100 so as to be exposed to the upper groove 130, the shear bolt hole 223 is formed so that the lower shear connector 210 and the shear bolt 240 are connected to the first connection nut (221), connected by a second connection nut (221b), a plurality of transverse spacers 224 are installed spaced apart on the bottom surface to be supported and installed on the upper surface of the rebar assembly of the PSC girder,
The lower end of the shear bolt 240 is connected to the upper part of the first connection nut 221 located under the housing jig 220, and the horizontal plate jig of the housing jig 220 around the first connection nut 221 ( The upper end of the lower shear connector 210 passes through 222 and is finally connected by a second connection nut 221b, and the lower shear connector 210 is a plurality of PSCs in the form of vertical bolts on the upper edge of the PSC girder 100. It is formed to be set so as to be buried at regular intervals in the longitudinal direction of the girder 100, and the shear bolts 240 connected by the lower shear connector 210 and the second connection nut 221b are staggered so that the housing jig 220 PSC girder construction method for precast slab to serve as a shear connector of the PSC girder 100 by this. The method of claim 8,
After step (d),
The shear bolt 240 formed on the upper surface of the mounted precast slab PSC girder 100 is accommodated in the shear pocket 310 of the precast slab 300, so that the precast slab 300 is installed in a number of bridges. PSC girder construction method for precast slab to be installed as the top plate of The method of claim 8,
The bridge substructure 400 of the step (b) is used when constructing a ramen bridge including both abutments 410, and the PSC girder 100 for precast slab is not large in cross-sectional height, so it is manufactured, transported and PSC girder construction method for precast slab that is manufactured to secure workability in construction and installs a number of them in a horizontal direction apart.

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