KR101211332B1 - Connecting Structure between Pre-Stressed Concrete Girder and Precast Panel - Google Patents

Abstract

The present invention, the shear connector formed on the upper portion of the PSC girder; A connection groove formed along a contact portion with the PSC girder on a bottom surface of the precast bottom plate and having a shear connector on the PSC girder; A pour hole formed to be connected to a connection groove at an upper surface of the precast bottom plate; It is embedded inside the precast deck to reinforce the overall strength and partly includes rebar exposed through the connecting groove, and after the plurality of precast decks are placed in succession on the PSC girder, the mortar is poured through The mortar moves through the coupling grooves and is filled and cured to provide a PSC girder and precast bottom plate connection structure where the PSC girder and the precast bottom plate are connected by shear connectors and rebars. According to the connection structure of the PSC girder and the precast bottom plate according to the present invention, the connection groove is formed along the precast bottom plate, and the PSC girder and the precast floor are arranged evenly on the PSC girder according to the connection groove. There is an effect that the stress is evenly distributed in the connecting portion of the plate. In addition, when the mortar is filled through the pouring hole by forming the connecting groove in the precast deck, the mortar moves through the connecting groove and the mortar is filled so that the precast deck and the PSC girder are connected to each other. The work time for the connection of the work is shortened and the work productivity is improved.

Description

Connecting Structure between Pre-Stressed Concrete Girder and Precast Panel}

The present invention relates to a pre-stressed concrete girder (Pre-Stressed Concrete Girder) and a precast panel connection structure, more specifically, after placing the precast bottom plate on the PSC girder by PSC girder The present invention relates to a connection structure between a PSC girder and a precast sole plate to complete the connection between the and the precast sole plate.

Conventionally, in order to make the floor plate of the bridge to form the formwork, reinforce the reinforcement to the formwork, and then cast concrete, and completed the bottom plate through a long-term curing process. However, such a conventional bridge deck construction method requires a lot of professional construction personnel, especially in areas with a lot of traffic, such as downtown, there was a problem such as a huge indirect loss due to the traffic congestion caused by the construction.

In order to improve the problems caused by the field construction, the proposed method is a construction method using a precast deck. Precast decking is completed through the process of manufacturing steel formwork in advance at the factory, reinforcing steel bars in the formwork, pouring concrete, steaming and demolding.

1 is a view showing a connection structure between the PSC girder and the precast bottom plate according to the prior art.

Referring to the drawings, the PSC girders 2, in which the shear connector 3 is exposed at regular intervals, are arranged in parallel, and the precast bottom plate 1 is disposed above the PSC girders 2, respectively. At this time, a plurality of connecting holes 5 are formed on both sides of the precast bottom plate 1 at regular intervals, and when the precast bottom plate 1 is disposed on the PSC girder 2, the shear connecting material 3 Is inserted into the connecting hole (5). Subsequently, after placing the mortar supply device 6 directly above the connecting hole 5, and supplying the mortar through the mortar supply device 6, the mortar fills the connecting hole 5 and then hardens, thereby precasting the mortar. The connection of the bottom plate 1 and the PSC girder 2 is completed.

However, according to the connection structure of the conventional PSC girder 2 and the precast bottom plate 1 as described above, the shear connector 3 is not evenly disposed along the PSC girder 2 and concentrates only on the connection hole 5. Since the position is located, there is a problem that the stress is concentrated on the connection of the bottom plate 1 and the shear connector 3 when the external force is applied.

In addition, when arranging the precast bottom plate 1 on the PSC girder 2 and performing a connection work, the mortar supply apparatus 6 is located in the upper part of each connection hole 5, and is formed in multiple numbers. Mortar must be filled in each of the connecting holes (5). For this reason, it takes a long working time, there is a disadvantage that the work productivity is lowered.

The present invention has been made to solve the above problems, to provide a PSC girder and precast bottom plate connecting structure that can improve the structural stability by the stress is evenly distributed in the connection between the PSC girder and the precast bottom plate. Its purpose is to.

Another object is to provide a PSC girder and precast bottom plate connection structure that can improve work productivity by shortening the working time for connecting the PSC girder and the precast bottom plate.

The present invention provides a structure for connecting a precast bottom plate disposed on a plurality of PSC girders, comprising: a shear connector formed on an upper portion of the PSC girder; A connection groove formed along a contact portion with the PSC girder on a bottom surface of the precast deck and having a shear connector on the PSC girder; A pour hole formed to be connected to the connection groove from an upper surface of the precast bottom plate; The reinforcement hole is embedded in the inner side of the precast bottom plate to reinforce the overall strength and part of the reinforcing bar exposed through the connecting groove, after the plurality of precast bottom plate is continuously disposed on the PSC girder, When the mortar is poured through the mortar is moved through the connecting groove is filled and then hardened so that the PSC girder and the precast bottom plate connecting structure is connected to the PSC girder and the precast bottom plate by the shear connector and the reinforcing bar to provide.

The PSC girder and the precast bottom plate connection structure may further include a confirmation hole formed as the connection groove on the upper surface of the precast bottom plate to observe a mortar casting state.

Furthermore, the PSC girder and the precast bottom plate connecting structure may further include reinforcing jaws protruding from both sides of the connecting groove.

In addition, it may further include a sealing member disposed between the reinforcing jaw and the PSC girder.

The present invention as described above, by forming a connection groove along the precast bottom plate, by placing a plurality of shear connection material evenly along the connection groove on the PSC girder, the stress is evenly distributed on the connection portion of the PSC girder and the precast bottom plate. It is effective.

In addition, when the mortar is filled through the pouring hole by forming the connecting groove in the precast deck, the mortar moves through the connecting groove and the mortar is filled so that the precast deck and the PSC girder are connected to each other. The working time for the connection of the machine is shortened, thus improving the work productivity.

1 is a view showing a connection structure of a PSC girder and a precast bottom plate according to the prior art,
2 is a perspective view showing the configuration of a precast deck used in a PSC girder and a precast deck structure according to a first embodiment of the present invention;
3 is a view showing the arrangement of the precast deck by the girder and the precast bottom plate connecting structure according to the first embodiment of the present invention,
4 is a sectional view taken along line AA of FIG. 3;
5 is a perspective view showing the configuration of another example of a precast deck used in the PSC girder and the precast deck construction according to the first embodiment of the present invention;
6 is a perspective view showing the configuration of a precast deck used in a PSC girder and a precast deck construction according to a second embodiment of the present invention;
FIG. 7 is a view illustrating an arrangement state of a precast deck used in a PSC girder and a precast deck construction according to a second embodiment of the present invention; FIG.
FIG. 8 is a sectional view taken along line BB of FIG. 6.

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

First Embodiment

Figure 2 is a perspective view showing the configuration of the precast deck used in the PSC girder and the precast bottom plate connecting structure according to the first embodiment of the present invention, Figure 3 is a girder and pre- according to the first embodiment of the present invention It is a figure which shows the arrangement state of a precast sole plate by a cast sole plate connection structure, and FIG. 4 is sectional drawing of the AA line of FIG.

2 to 4, the PSC girder and the precast bottom plate connecting structure according to the present invention include a precast bottom plate 110, a connection groove 120, a pour hole 130, and a reinforcing bar 102. .

First, the PSC girder (Pre-Stressed Concrete Girder) (2) is a structure made of concrete to receive the load of the bridge deck, it is a known component used for existing bridge work, etc., a detailed description thereof will be omitted. However, the shape of the PSC girder 2 shown in the drawings is illustrative, and various other shapes are possible, and the shape of the PSC girder 2 should not be interpreted as unduly limiting the scope of the present invention.

On the upper portion of the PSC girder 2, a plurality of shear connecting members 3 for securing the connection with the precast bottom plate 110, which will be described later, are arranged at regular intervals. And in the accompanying drawings, the shear connector 3 is a '∩' shape, but is not limited to this form, it can be formed in other forms by the user's choice.

On the PSC girder 2, a plurality of precast bottom plates 110 made of reinforced concrete are continuously arranged in a plurality. The precast bottom plate 110 is formed in a flat plate shape, and includes a plurality of reinforcing bars arranged in parallel with the upper surface for strength reinforcement.

The reinforcing bars 102 for the connection between the precast bottom plate 110 and the shear connector 3 are bent some of the reinforcing bars that are basically embedded in the precast bottom plate 110 through the connecting groove 120. Alternatively, apart from the rebar, alternatively, the bent rebar may be embedded in the precast bottom plate 110 to be exposed through the connection groove 120. Wherein the reinforcing bar 102 exposed through the connecting groove 120 may be located between the shear connector 3 when the precast bottom plate 110 is disposed, the positional relationship between the two limits the scope of the present invention It is not.

The connection groove 120 is formed on the bottom of the precast bottom plate 110.

The connection groove 120 is a mortar is carried through the pour hole 130 to be described later to allow the PSC girder 2 and the precast bottom plate 110 is connected. Since the PSC girder 2 is disposed below the precast bottom plate 110 for stable support of the precast bottom plate 110, the connection groove 120 is precast to facilitate the connection with the PSC girder 2. The bottom plate 110 is formed along a contact portion with the PSC girder 2. The depth of the connection groove 120 is formed such that the shear connector 3 is located inward, and the upper end of the shear connector 3 does not contact the bottom surface of the connection groove 120. The width of the connection groove 120 is formed to be narrower than the upper width of the PSC girder 2, to facilitate the connection with the PSC girder (2).

Reinforcing jaw 122 may protrude to a predetermined height on both sides of the connection groove 120. The reinforcing jaw 122 reinforces the overall strength of the precast bottom plate 110 is lowered by the formation of the connection groove (120).

The pour hole 130 is formed for placing mortar after the precast bottom plate 110 is disposed on the PSC girder 2, the precast bottom plate (filling by filling the mortar through the pour hole 130) 110) and the PSC girder (2) is connected.

The pour hole 130 is formed to penetrate toward the connecting groove 120 from the upper surface of the precast bottom plate 110. In the present embodiment, the pour hole 130 is formed in a circular shape, but may be formed in another shape (for example, square or hexagon). The diameter of the pour hole 130 is formed the same or smaller than the width of the connecting groove 120.

In the drawings of this embodiment, the pour hole 130 is shown as being formed on each side of each of the precast bottom plate 110, but may be formed in one or more for faster mortar casting. In addition, the pour hole 130, one or more of the precast bottom plate 110 of the plurality of precast bottom plate 110 is continuously disposed in consideration of the fluidity of the mortar flowing along the connecting groove 120, It can also be selectively formed only.

The use state of the first embodiment of the present invention will be described with reference to the accompanying drawings.

Referring to FIGS. 3 and 4, it can be seen that the precast bottom plate 110 is disposed above the PSC girder 2. At this time, the shear connector 3 is located inside the connection groove 120 of the precast bottom plate 110. In the figure, a single precast bottom plate 110 is disposed on the PSC girder 2, but this is for ease of description, and a plurality of precast bottom plates 110 are continuously disposed on the PSC girder 2. do.

In addition, in FIG. 3, only one side of the pour hole 130 is illustrated to facilitate understanding of the drawing.

When arranging the precast bottom plate 110, a sealing member 124 is disposed between the reinforcing jaw 122 and the PSC girder 2 to prevent leakage of mortar. The sealing member 124 is made of steel, but other materials may be used as long as it can prevent the leakage of mortar.

After the precast bottom plate 110 is disposed, the mortar supply device 6 is positioned directly on the pouring hole 130 formed at one side of the precast bottom plate 110.

The mortar supply device 6 discharges mortar to fill the pouring hole 130. Mortar filled through the pour hole 130 fills the pour ball 130, while moving along the space, that is, the connection groove 120, between the PSC girder 2 and the precast bottom plate 110. Fill 120 entirely.

The filled mortar hardens after a predetermined time, and the hardening of the mortar makes the reinforcing bar 102 and the shear connector 3 connect the PSC girder 2 and the precast bottom plate 110 as a whole.

Here, since the plurality of precast bottom plates 110 are continuously arranged on the PSC girder 2, when both ends of the connection grooves 120 of the precast bottom plates 110 which are continuously arranged are connected to each other, mortar Connection of the precast bottom plate 110 and the PSC girder 2 may be made by filling the mortar through one side of the pouring hole 130 without moving the feeder 6.

In addition, since the connection grooves 120 of the precast bottom plate 110 which are continuously arranged are connected to each other, the progress of pouring mortar in the connection grooves 120 is different from the other grooves on the connection grooves 120 connected to each other. It can be confirmed through the ball (130). In detail, when the mortar is filled through the pour hole 130 of the selected precast bottom plate 110, the pour holes 130 formed in the other precast bottom plate 110 adjacent to each other are continuously disposed. You can check the mortar filling status in real time.

On the other hand, Figure 5 is a perspective view showing the configuration of another example of the precast bottom plate used in the PSC girder and the precast bottom plate connecting structure according to the first embodiment of the present invention.

Referring to Figure 5, it can be seen that the confirmation hole 140 that can observe the progress of the filling mortar pour state on both sides of the filling hole 130 for filling the mortar is further formed. However, in the drawing, although the confirmation hole 140 is shown as being formed on both sides of the pouring hole 130, it can be configured to be formed only on one side as needed.

The confirmation hole 140 is formed vertically from the upper surface of the precast bottom plate 110a to the connection groove 120. The confirmation hole 140 may be formed in at least one or more numbers along the connection groove 120.

Meanwhile, the precast sole plate 110a as shown in FIG. 5 may be disposed and connected to the PSC girder 2 in the same manner as the precast sole plate 110 described above, and thus a detailed description thereof will be omitted. .

The worker observes the delivery state of the mortar through the connection groove 120 through the confirmation hole 140, it is possible to control the supply of mortar. That is, the worker may visually check the mortar moving through the connection groove 120 by the confirmation hole 140 to stop the supply of the mortar. In addition, in the case of filling up to the connection groove of the precast bottom plate 110a continuously arranged, the filling of the mortar may be confirmed through the confirmation hole 140.

On the other hand, whether the formation of the confirmation hole 140 is optional, and as described above, without forming the confirmation hole 140 separately, the plural formed pour holes 130 may serve as the confirmation hole. .

Second Embodiment

6 is a perspective view showing the configuration of a precast deck used in a PSC girder and a precast deck structure according to a second embodiment of the present invention.

The same reference numerals are used for the same components as in the previous embodiment, and detailed description thereof will be omitted.

Referring to FIG. 6, the PSC girder and the precast bottom plate connecting structure according to the present invention include a precast bottom plate 110b, a connection groove 120, a pour hole 130, and reinforcing bars 102a.

Referring to FIG. 6, unlike the previous embodiment, it can be seen that the reinforcing jaw 122 (see FIG. 2) is not formed around the connection groove 120 formed as the lower surface of the precast bottom plate 110b. have.

In addition, referring to Figure 6, the reinforcing bar 102b of the precast bottom plate 110b is formed in a straight line parallel to the upper surface of the precast bottom plate 110, a portion of the exposed through the connection groove 120 Can be. Here, the reinforcing bar 102a is a part of the reinforcing bar that is basically embedded in the precast bottom plate 110b is exposed through the connection groove 120.

The reinforcing bars 102a exposed through the connection grooves 120 may be located between the shear connecting members 3 when the precast bottom plate 110b is disposed, but the positional relationship between the two limits the scope of the present invention. It is not.

The use state of the second embodiment of the present invention will be described with reference to the drawings.

FIG. 7 is a view illustrating an arrangement state of a precast bottom plate by a girder and a precast bottom plate connecting structure according to a second embodiment of the present invention, and FIG. 8 is a cross-sectional view of the line A-A of FIG. 7.

Referring to FIGS. 7 and 8, after the precast bottom plate 110b is disposed on the PSC girder 2, the upper portion of the pour hole 130 formed at one side of the precast bottom plate 110b is disposed. Position the mortar feeder 6.

Since the mortar is discharged through the mortar supply device 6 to fill the pour hole 130, the precast bottom plate 110b and the PSC girder 2a are the same as in the previous embodiment, and thus the detailed description thereof will be provided. Omit

In the second embodiment of the present invention, although not shown, at least one confirmation hole 140 (see FIG. 5) formed vertically from the upper surface of the precast bottom plate 110a to the connecting groove 120 is provided. Supply can be controlled. Detailed descriptions thereof will be omitted in order to avoid repeated descriptions.

According to the embodiments of the present invention as described above, when the mortar is poured through the pour hole 130 formed in the precast bottom plate (110, 110a, 110b), is formed on the bottom surface of the precast bottom plate (110, 110a, 110b) Mortar moves through the connecting groove 120 and fills the space between the PSC girder 2 and the precast deck plates 110, 110a, and 110b, and is thus bonded to each other, thus consuming time for selecting the concrete supply device. Has the effect of being reduced.

In addition, there is an effect that the stress is dispersed through a plurality of shear connection material 3 is evenly disposed along the connection groove 120 and the connection groove 120 formed in the precast bottom plate.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

2: PSC girder 102, 102a: rebar
110, 110a, 110b: precast deck
120: pour ball 122: reinforcement jaw
130: connector 140: confirmation hole

Claims (4)

In the structure in which the PSC girder and the reinforcing bar is placed in the formwork, concrete is poured, steam curing and demolding are completed to form a plurality of precast decks on the PSC girder and connected to each other.
A shear connector protruding from the upper portion of the PSC girder;
The shear connector may be positioned inward, and a portion of the rebar is exposed to facilitate connection with the shear connector and continuously formed along a contact portion with the PSC girder on the bottom of the precast deck. Connecting groove; And
A pour hole communicating with the connection groove from an upper surface of the precast bottom plate; / RTI >
After the plurality of precast bottom plates are continuously disposed on the PSC girder, when the mortar is poured through the pour hole, the mortar moves through the connecting groove and is filled and cured by the shear connector and the reinforcing bars. A PSC girder and a precast bottom plate connection structure to which the PSC girder and the precast bottom plate are connected. The method according to claim 1,
PSC girder and precast bottom plate connection structure further comprises a confirmation hole formed in the connecting groove on the upper surface of the precast bottom plate to observe the mortar casting state. The method according to claim 1,
PSC girder and precast bottom plate connection structure further comprising a reinforcing jaw each protruding from both sides of the connecting groove. The method according to claim 3,
PSC girder and precast bottom plate connection structure further comprising a sealing member disposed between the reinforcing jaw and the PSC girder.

Images