KR20120054705A - Connecting details and connecting method of uhpc precast slab using steel bar in tapered recess - Google Patents

Abstract

PURPOSE: A connection structure of an UHPC precast floor plate and a construction method using reinforcing bar joints into tapered recessed parts are provided to optimally integrate UHPC floor plates and a girder by connecting both UHPC floor plates and the girder with reinforcing bars. CONSTITUTION: A connection structure of an UHPC precast floor plate comprises recessed parts(11) and reinforcing bars(3). The recessed parts are formed on the top surface of the end of one UHPC floor plate(1a) facing the other UHPC floor plate(1b), and are traversely recessed from the top surface of the UHPC floor plate starting from the top surface of the end. The recessed parts are formed in a longitudinal direction of a girder(2). The reinforcing bars are projected from the end of the other UHPC floor plate. If both UHPC floor plates are arranged on both sides of the girder, the other end of the reinforcing bars is positioned in the recessed part and concrete(5) is placed on the upper part of the girder between both UHPC floor plates.

Description

Connecting Details and Connecting Method of UHPC Precast Slab Using Steel Bar in Tapered Recess}

The present invention relates to a structure for connecting the ultra-high strength concrete precast slab integrally installed on both sides from the upper side of the girder, and a construction method thereof. Specifically, ultra high-performance concrete containing fiber and having a compressive strength of 150 MPa or more (Ultra High) Performance concrete), that is, a floor plate (hereinafter, abbreviated as "UHPC floor plate") manufactured by using a precast method, is disposed on both sides of the upper surface of the girder, where the shear connecting member protrudes from the upper surface. The present invention relates to a structure and a connection construction method of integrally combining UHPC bottom plates and girders on both sides and simultaneously connecting the UHPC bottom plates on both sides.

In the case of using a UHPC floor plate made of fiber and having a compressive strength of 150 MPa or more, that is, a UHPC floor plate manufactured by a precast method using UHPC, a bridge is important. Robust integral connection between and UHPC bottom plate and solid integral composite between girders.

Regardless of the material of the girder, such as concrete or steel, the shear connector is present on the upper part of the girder, and the UHPC bottom plate must be completely integrated and connected while the UHPC bottom plate is placed on both sides of the upper part of the girder. In addition, the two sides of the UHPC deck and girders must also be fully integrated and synthesized. In particular, since the girder portion is the portion where the parent moment acts, the tensile force is concentrated on the upper surface portion of the UHPC bottom plate, a solid connection must be made between the two UHPC bottom plate in a form that can sufficiently support the tensile force.

In the case of the UHPC bottom plate, since it is made of precast so as to have a compressive strength of 150 MPa or more, the thickness of the UHPC bottom plate is very thin compared to the bottom plate made of ordinary concrete. However, in the related art, the connection method by the loop joint or the lap joint applied to general concrete has been applied as it is without considering the inherent characteristics of the UHPC bottom plate. UHPC requires high temperature curing due to its material characteristics, and in the case of loop joints or overlapping joints as in the prior art, the field casting range becomes wider, and thus the high temperature curing range becomes excessively wide, resulting in excessively high curing costs. In addition, high temperature curing is not made properly, causing the problem of insufficient strength expression at the connecting portion.

Therefore, in order to solve this problem, it is urgent to develop a connection structure and a connection construction method considering the unique characteristics of the UHPC sole plate.

The present invention was developed in order to satisfy the above needs, specifically, the girder in which the shear connector is projected on the upper surface, installed over the UHPC bottom plate, and the UHPC bottom plate at the same time made a firm connection between the UHPC bottom plate It is possible to apply to UHPC bottom plate which is thin and needs high temperature curing while making solid integral synthesis between plate and girder, and to make the connection between UHPC bottom plate and synthesis with girder simple and efficient. An object of the present invention is to provide a connection structure of a structure and a construction method thereof.

In order to achieve the above object, in the present invention, the precast method using ultra-high performance concrete having fibers and compressive strength of 150 MPa or more on each side of the upper flange of the girder in the transverse direction perpendicular to the longitudinal direction of the girder The girder and the UHPC bottom plate are integrally coupled to each other while the end surfaces of the UHPC bottom plate are formed so as to span each other, and the end faces of the UHPC bottom plate face each other with the shear connecting member protruding from the girder. In the upper surface of the end facing the other UHPC bottom plate from one side of the UHPC bottom plate, the concave portion recessed from the top surface of the UHPC bottom plate in the transverse direction starting from the top of the end surface spaced in the longitudinal direction of the girder It is formed with a plurality; An end surface of the other side UHPC bottom plate is provided with a connecting reinforcing bar; The other end of the connecting rebar is located in a recess formed in the one side UHPC bottom plate when both side UHPC bottom plates are disposed across both transverse sides of the girder; The upper part of the girder between the two UHPC bottom plates is filled with concrete; UHPC is filled in the recess of one side of the UHPC bottom plate has a structure in which the other end of the connecting reinforcing bar located in the recess is embedded in the UHPC, the UHPC bottom plate and the girders of both sides are integrally and firmly connected. The connection structure of the UHPC bottom plate and the girder, and the connection construction method are provided.

According to the present invention, both sides of the UHPC bottom plate and the girder are integrally connected by the reinforcing bar, and the effect of enabling the optimized integral synthesis between the UHPC bottom plate and the girder is achieved.

Particularly, in the present invention, the recess formed on the UHPC bottom plate may have a tapered shape. The tapered shape of the recess prevents the end of the connecting reinforcing bar from being separated from the UHPC bottom plate, thereby making a stronger connection. do.

Therefore, according to the present invention, the shear connector is installed over the UHPC bottom plate to the girder protruding from the upper surface, while the girder and the UHPC bottom plate can be firmly integrated and connected, it can be applied to a thin UHPC bottom plate, The connection can be done easily and efficiently.

1 is a schematic cross-sectional perspective view in the longitudinal direction of a girder showing a connection structure according to a first embodiment of the present invention.
FIG. 2 is a schematic plan view of the circle A portion of FIG. 1.
FIG. 3 is a schematic cross-sectional view of a portion BB of FIG. 1.
4 is a schematic perspective view of an example of the UHPC bottom plate viewed from the bottom surface direction.
5 is a cross-sectional perspective view corresponding to FIG. 1, which is a schematic cross-sectional perspective view in the longitudinal direction of a girder showing a connection structure according to a second embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, this is described as one embodiment, whereby the technical spirit of the present invention and its core configuration and operation are not limited.

1 shows a schematic cross-sectional perspective view in the longitudinal direction of a girder 2 showing a connection structure according to a first embodiment of the invention, and FIG. 2 shows a schematic plan view of the circle A portion of FIG. 1. 3 is a schematic cross-sectional view of the portion BB of FIG. 1. 4 is a schematic perspective view of an example of the UHPC bottom plate viewed from the bottom surface direction. For reference, in the embodiment illustrated in the drawings, the girder 2 is illustrated as a steel I beam, but the type of the girder 2 is not limited thereto, and the connection structure and connection construction method of the present invention also apply to concrete girder in addition to the steel girder. This applies. In addition, the girder 2 may be a bridge mold arranged in the axial direction, but may also be a horizontal beam arranged in the axial direction perpendicular to the axial direction.

In the connection structure according to the present invention, the ends of the UHPC bottom plates 1a and 1b are disposed on both sides of the upper flange 22 of the girder 2 in the transverse direction perpendicular to the longitudinal direction of the girder 2, End faces 110 of both UHPC bottom plates 1a and 1b face each other with the shear connector 21 protruding from the girder 2 therebetween.

1 to 3, recesses 11 are formed in one UHPC bottom plate 1a of the two UHPC bottom plates 1a and 1b to be connected to each other. That is, the upper surface of the end portion facing from the one side UHPC bottom plate 1a to the other side UHPC bottom plate 1b, starting at the top of the end surface 110 and transversely in a predetermined length in one side UHPC bottom plate 1a The recessed part 11 recessed from the upper surface of () is formed.

2 and 3, the concave portion 11 preferably has a tapered shape in which the width of the concave portion 11 increases in the transverse direction from the end surface 110 in a plan view. Do. In addition, the width of the recess 11 preferably has a tapered shape that becomes larger as the width of the UHPC bottom plate becomes deeper from the upper surface of the UHPC bottom plate.

Thus, the tapered shape ("first taper shape") in which the width | variety expands as the recessed part 11 goes to a lateral direction, and the tapered shape ("second taper shape") in which the width | variety expands deeper from the surface inside In this case, when the connecting reinforcing bar 3 is disposed in the concave part 11 as described later, the effect that the pullout resistance of the connecting reinforcing bar 3 is greatly increased by the shape of the concave part 11 is exerted. Although only one of the first tapered shape and the second tapered shape may be embodied simultaneously in the concave portion 11, it is more preferable that both of the two tapered shapes are embodied in the concave portion 11 simultaneously. The shape of the recess 11 as described above is, for example, a state in which a mold corresponding to the shape of the recess 11 is manufactured and placed in a removable material (for example, styrofoam) when the UHPC bottom plate is manufactured. After the UHPC is poured in, and the curing of the UHPC is completed by scraping off the mold can be formed in the recess 11 as described above in the UHPC bottom plate.

In the first embodiment shown in Figures 1 to 3, such a recess 11 is formed in a plurality of intervals in the width direction of the one side UHPC bottom plate, that is, the longitudinal direction of the girder (2).

On the other hand, in the first embodiment shown in Figures 1 to 3, the end surface 110 of the UHPC bottom plate (1b) of the other side is provided with a connecting reinforcement (3) in a protruding state. That is, one end of the connecting reinforcing bar 3 is integrally coupled to the other side of the UHPC bottom plate 1b, and the other end of the connecting reinforcing bar 3 protrudes in the direction of the one side of the UHPC bottom plate 1a to the girder 2. Extends across the top of the.

Therefore, when the UHPC bottom plates 1a and 1b on both sides are disposed to extend across both sides of the girder 2 in a state where the end faces 110 face each other, the other end of the connecting reinforcing bar 3 is the one side UHPC bottom plate ( It is located in the recessed part 11 formed in 1a).

In the present invention, between the UHPC bottom plates 1a and 1b on both sides, while the UHPC bottom plates 1a and 1b on both sides are disposed across the transverse both sides of the girder 2 facing the end faces 110 from each other. The upper part of the girder 2 is filled with concrete 5 such as non-contraction concrete or general concrete. That is, the UHPC bottom plates 1a and 1b on both sides are disposed across the transverse both sides of the girder 2 in a state where the end faces 110 face each other, and the connecting reinforcement 3 moves the girder 2 in the transverse direction. The other end of the connecting reinforcing bar (3) is located in the recess 11 formed in the one side UHPC bottom plate (1a), and the upper part of the girder (2) between the two side UHPC bottom plates (1a, 1b) (5) is poured out and filled.

Meanwhile, in the recess 11 of one side UHPC bottom plate 1a, the UHPC 4 is filled in the field so that the other end of the connecting rebar 3 positioned in the recess 11 is embedded in the UHPC 4. do. UHPC requires high temperature curing due to the nature of the material. In the present invention, since the UHPC 4 is placed in the site only in the recess 11, after the UHPC 4 is poured into the recess 11 so that the connecting reinforcing bar 3 is embedded as described above, the recess 11 The upper surface of the UHPC (4) placed in the upper surface of the heating pad to dissipate heat by electricity or other methods to maintain the high temperature state necessary for curing the UHPC. That is, in the present invention, since the in-site casting range of the UHPC is limited to the size of the concave portion 11, high temperature curing is performed on the UHPC 4 that is easily placed on the concave portion 11 using a heating pad or the like. You can do it. Therefore, it is easy to implement the coupling between the connecting reinforcing bar (3) and the UHPC (4) by on-site casting of the UHPC (4), but only a small cost is required to cure the UHPC, the construction economy is good, the strength of the site-poured UHPC Although the expression is excellent, the effect of being able to maintain the quality (high intensity, etc.) of UHPC at a high level, even if the UHPC is poured in the field.

As such, when the UHPC 4 placed in the recess 11 and the concrete 5 on the girder 2 are completely cured, the UHPC bottom plates 1a and 1b on both sides are connected by the connecting bars 3. At the same time as the integral connection is made between the two UHPC bottom plates (1a, 1b) and the girder (2).

In particular, the other end of the connecting reinforcement (3) is not only embedded in the UHPC (4) placed in the concave portion 11 is integrated, but the concave portion (11) is tapered in the width extending in the transverse direction (" 1 taper shape ") and tapered shape (" second taper shape ") that extends in width from the surface to the inside thereof simultaneously or in any one of them, so that the pulling force is applied to the other end of the connecting bar 3 Even if it acts, the pullout resistance becomes larger due to the first taper shape, such that the other end of the connecting reinforcing bar 3 is not pulled out in the transverse direction from the UHPC bottom plate 1a on one side.

In addition, even if a force acts on the connecting rebar 3 in a direction perpendicular to the UHPC bottom plate, the second taper shape has a large resistance force in a direction perpendicular to the other end of the connecting rebar 3 due to the second taper shape. The other end is not pulled out in the vertical direction from the UHPC bottom plate (1a) of the one side or the like does not occur. Thus, according to the present invention, it is possible to realize an optimized integrated composition between the two UHPC bottom plates (1a, 1b) and the girder (2) as well as a solid connection between the two UHPC bottom plates (1a, 1b).

In addition, in the present invention, since both sides can be mounted to face the UHPC bottom plates (1a, 1b) and the UHPC can be placed on-site, the construction process is simple and easy.

5 is a cross-sectional perspective view corresponding to FIG. 1, which is a schematic cross-sectional perspective view in the longitudinal direction of the girder 2 showing a connection structure according to a second embodiment of the present invention.

In the first embodiment described above, the concave portion 11 is formed only on the UHPC bottom plate 1a on one side, but the UHPC on the one side of the UHPC bottom plate 1b on the other side as in the second embodiment shown in FIG. The concave portion 11 may be formed in the same form as the concave portion 11 formed on the UHPC bottom plate 1a on one side at a position opposite to the concave portion 11 formed on the bottom plate 1a.

In the case of this second embodiment, one end of the connecting reinforcement 3 is disposed in the recess 11 formed in the other side UHPC bottom plate 1b in the manner described above, and the UHPC 4 cast in the recess 11. Embedded in the other side UHPC bottom plate (1b) and integrally coupled.

The coupling between the other side UHPC bottom plate 1b and one side of the connecting reinforcing bar 3 by the recess 11 and the UHPC 4 is such that the other side UHPC bottom plate 1b is mounted on the girder 2. It may be done beforehand. However, after both UHPC bottom plates 1a and 1b are mounted on the girder 2, both ends of the connecting bars 3 are placed in the recesses 11 of the two UHPC bottom plates 1a and 1b, respectively. The UHPC 4 may be poured into the recess 11 so that both ends of the connecting rebar 3 may be coupled to the UHPC bottom plates 1a and 1b, respectively.

That is, the two UHPC bottom plates 1a and 1b are mounted so as to face each other on the girder 2 and then connected over the recesses 11 at opposite positions of the opposing two UHPC bottom plates 1a and 1b. The reinforcing bars 3 are arranged in the girder 2 transverse direction so that both ends of the connecting bars 3 are placed in the recesses 11 of the two UHPC bottom plates 1a and 1b, respectively, and the UHPC in the recesses 11. (4) is filled so that both ends of the connecting reinforcement (3) is embedded in the UHPC (4) and combined. In the above description, although the UHPC 4 is poured into the recess 11 after the connecting rebar 3 is disposed, the connecting rebar 3 may be disposed after the UHPC 4 is poured.

In the case of the second embodiment as described above, similarly to the first embodiment, the heat of the upper portion of the recess 11 for curing the UHPC 4 placed in the recess 11 formed in the UHPC bottom plates 1a and 1b. Local high temperature curing using pad laying can be used. Therefore, as mentioned above, it is possible to obtain the effect of improving the quality of on-site placing UHPC and reducing the high temperature curing cost.

When the UHPC 4 and the concrete 5 on the girder 2 are completely hardened in the recess 11, both UHPC bottom plates 1a and 1b and the girder 2 are connected to the connecting reinforcement 3. By the tapered shape of the recess 11 to prevent the end of the connecting reinforcing bar 3 from being separated from the UHPC bottom plates 1a and 1b, and the UHPC bottom plates 1a, The effect of being able to implement an optimized integrally coupled connection between 1b) and girder 2 is exerted.

1a, 1b: UHPC bottom plate
2: girder
3: connecting rebar
4: UHPC
5: concrete
11: concave

Claims (5)

Manufactured by precast method using ultra high-performance concrete containing fibers and having compressive strength of 150 MPa or more on both sides of the upper flange 22 of the girder 2 in the transverse direction perpendicular to the longitudinal direction of the girder 2 End faces 110 of the UHPC bottom plates 1a and 1b are disposed so that the end faces 110 of the two UHPC bottom plates 1a and 1b are interposed with the shear connector 21 protruding from the girder 2. In a state of facing each other, the integrated connection between the two UHPC bottom plates (1a, 1b), and the integrated composition between the girder (2) and the two UHPC bottom plates (1a, 1b),
On the upper surface of the end portion facing from the one side UHPC bottom plate 1a to the other side UHPC bottom plate 1b, it is recessed from the upper surface of the UHPC bottom plate 1a in the transverse direction, starting from the top of the end surface 110. A plurality of recesses 11 are formed at intervals in the longitudinal direction of the girder 2;
An end surface 110 of the UHPC bottom plate 1b of the other side is provided with the connecting reinforcing bars 3 protruding;
When both UHPC bottom plates 1a and 1b are disposed across the transverse both sides of the girder 2, the other end of the connecting reinforcing bar 3 is located in the recess 11 formed in the one side UHPC bottom plate 1a. There is;
Concrete 5 is poured into the upper part of the girder 2 between the two UHPC bottom plates 1a and 1b;
UHPC 4 is filled in the recess 11 of one side UHPC bottom plate 1a so that the other end of the connecting rebar 3 positioned in the recess 11 is embedded in the UHPC 4. , UHPC bottom plate (1a, 1b) and the girder (4) of the two sides, the connection structure of the UHPC bottom plate and the girder are integrally and firmly connected.
The method of claim 1,
The UHPC bottom plate 1b on the other side also has a UHPC bottom plate transversely starting from the top of the end surface 110 at a position opposite to the recess 11 formed in the one side UHPC bottom plate 1a. A plurality of recesses 11 recessed from the upper surface of 1a are formed at intervals in the longitudinal direction of the girder 2;
One end of the connecting reinforcing bar 3 is embedded in the recess 11 of the other UHPC bottom plate 1b and embedded in the UHPC 4 that is cast in the recess 11 and integrated with the other UHPC bottom plate 1b. Connection structure of the UHPC bottom plate and the girder, characterized in that coupled to.
The method according to claim 1 or 2,
The concave portion 11 is UHPC bottom plate and girder connection structure, characterized in that it has a tapered form in which the width of the concave portion 11 in the transverse direction from the end surface 110 when viewed in plan view.
The method according to claim 1 or 2,
The concave portion 11 is a UHPC bottom plate and the girder connection structure, characterized in that the width of the tapered form becomes larger as the deeper in the depth direction of the UHPC bottom plate from the upper surface of the UHPC bottom plate.
Manufactured by precast method using ultra high-performance concrete containing fibers and having compressive strength of 150 MPa or more on both sides of the upper flange 22 of the girder 2 in the transverse direction perpendicular to the longitudinal direction of the girder 2 The end faces 110 of the two UHPC bottom plates 1a and 1b are disposed so that the ends of the UHPC bottom plates 1a and 1b are disposed so that the shear connecting members 21 protruding from the girder 2 are disposed therebetween. In a state in which the girder 2 and the two side UHPC bottom plates (1a, 1b) are integrally coupled to each other,
On the upper surface of the end facing the other side UHPC bottom plate 1b from the one side UHPC bottom plate 1a, starting from the top of the end surface 110 and recessed concave from the upper surface of the UHPC bottom plate 1a in the transverse direction. A plurality of recesses 11 are formed at intervals in the longitudinal direction of the girder 2;
On the end surface 110, the other side UHPC bottom plate 1b, which is provided with the connecting reinforcing bars 3 protruding toward one side of the UHPC bottom plate 1a, and the one side of which the recess 11 is formed. Placing the UHPC bottom plate (1a) across both lateral sides of the girder (2), wherein the other end of the connecting reinforcement (3) is located in a recess (11) formed in the one side UHPC bottom plate (1a);
Pouring concrete (5) on top of the girder (2) between the two UHPC bottom plates (1a, 1b);
Fill the UHPC 4 in the recess 11 of the UHPC bottom plate 1a on which the other end of the connecting bar 3 is located, and install a heating pad on the upper surface of the UHPC 4 to heat the UHPC 4 at high temperature. The other end of the connecting reinforcement (3) is embedded in the UHPC (4) to be fixed and connected integrally between the UHPC bottom plates (1a, 1b) on both sides, and both UHPC bottom plates (1a, 1b) and girders (4) ) UHPC bottom plate and girder connection method characterized in that the solid integrally combined.

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