KR101452178B1 - Semi-integral abutment bridge using precast parapet and the construction therefor - Google Patents

Abstract

The present invention relates to a semi-integral bridge using a precast parapet which can be built relatively easily compared to a parapet and integrally connects a connection slab and a parapet to ensure efficient maintenance of the bridge and a construction method thereof. The construction method includes the steps of: installing an L-shaped precast parapet to be supported by a bridge bearing installed on a bridge shift constructed on a trenched foundation; mounting an end of a girder on a mounting groove formed on a horizontal plate of the L-shaped precast parapet; and forming a horizontal end beam by pouring precast parapet concrete onto the L-shaped precast parapet, which serves as a mold, to integrate the end units of the girder in the horizontal direction.

Description

TECHNICAL FIELD [0001] The present invention relates to a twisted-pair bridge using a precast alternate chest wall,

The present invention relates to a half-body bridge using a precast alternate chest wall and a construction method thereof. More specifically, it is possible to construct the alternate chest wall more easily in a half-girder bridge, but also to connect the connecting slab and the alternate chest wall integrally so that a half-length bridge using the precast alternate chest wall effective for maintenance of the bridge and its construction method .

FIG. 1 shows a construction work of a conventional half-body bridge.

The half-body bridge is constructed such that the bridge support 20 is installed on the upper surface of the bridge 30 before the bridge girder 10 is mounted between the turns 40 and the alternate chest wall 30 is supported by the bridge support 20 , And the girder (10) is placed between the alternate chest walls (30) after backfill (A) is performed on the back surface of the completed alternate chest wall (30).

The installation of the connecting slab (50) on the upper back surface of the alternate chest wall (30) so as to be in direct contact with the girder (10) eliminates the installation of the expansion joint to overcome the difficulty of maintenance due to the installation of the expansion joint This is a bridge construction method.

At this time, the girder 10 and the alternate chest wall 30 are reinforced (integrated) by pouring concrete using a formwork.

Conventionally, in the case of the conventional half - girder bridges, the workability is decreased and the air is delayed due to repetition of the construction by the on - site concrete in the steeping process with alternating chest wall and girder after alternating chest wall.

Also, since the connection slab is simply mounted on the upper part of the alternate chest wall backside, defects may occur in the connection part between the end of the connection slab and the girder, and there is room for improvement.

Therefore, the present invention is to utilize the advantage of a half-body bridge as it is, but it is possible to improve the workability in alternating chest wall and girder bridging, and to easily mount the girder on the alternate chest wall while the structural integrity of the connection slab and the alternate chest wall To provide a more efficient and economical half-body bridge using a precast chest wall and to provide a construction method thereof.

In order to achieve the above object,

First, an alternate chest wall is formed by pre-casting, but it is formed into L-shape to be formed in a form favorable to the settlement of the girder.

In this case, the horizontal plate of the alternating chest wall and the horizontal plate extending horizontally from the bottom of the vertical plate are formed into L-shape, and the horizontal plate is provided with a groove for girders. So that it can be seated.

If such a fixing groove is formed, it becomes very advantageous for the construction management of the girder in the construction of the four bridges in which the skew is formed (the bridge in which the girder installation direction and the alternate installation direction are not perpendicular to each other at a certain angle).

Further, the height of the vertical plate is lower than that of the upper surface of the girder, so that the connecting slab can be directly brought into contact with the girder when the upper portion of the girder is mounted on the precast chest wall.

Secondly, the connection reinforcing bars for connecting slabs are protruded on the upper surface of the vertical plate of the precast alternating chest wall formed lower than the upper surface of the girder, and when the concrete for the connecting slab is laid, So that the displacement due to temperature contraction and the like of the bridge can be absorbed at the same time so that the connection slab connection end and the end portion of the girder contact each other so as to prevent damage such as breakage.

Third, the precast alternate chest wall will cover the end of the girder when the girder is mounted, so that the concrete can be installed and the girder and the precast alternate chest wall can be tightened to complete the construction of the half-girder bridge.

The half-body bridge according to the present invention can reduce the number of bridges installed and efficiently secure the lateral gradient of the bridges by pre-fabricating the precast alternate chest wall and installing it on the alternate pedestal installed in advance in advance. . In addition, since the alternate chest wall itself is not made of cast-in-place concrete, it is possible to prevent the lowering of the workability and the air delay due to the alternate chest wall construction.

In addition, since the pre-cast alternate chest wall uses the pre-casting grooves, it is possible to quickly determine the position of the girders on the precast alternate chest wall, which can greatly improve the workability and workability in the construction of the quadruple bridges .

In addition, since the connection slab and the precast alternate chest wall are structurally integrated, it is possible to move the bridge in response to the displacement of the bridge due to temperature or the like, so that the connection slab connection end and the end of the girder do not contact each other, So that it becomes very advantageous for maintenance.

FIG. 1 is a perspective view of a conventional half-
FIG. 2A is a sectional view of a half-body bridge construction using a precast alternate chest wall of the present invention,
Fig. 2b is a structural perspective view of the precast alternating chest wall, girder and connecting slab of the present invention,
Figs. 2c and 2d are cross-sectional views of connecting portions of a half-body bridge and a connecting slab using a precast alternate chest wall of the present invention,
Figs. 3a, 3b, 3c and 3d are construction sequence diagrams of the precast alternating chest wall, girder and connecting slab of the present invention. Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Half-body bridge 100 using precast alternate chest wall 120 of the present invention]

FIG. 2A is a sectional view of a half-body bridge construction using a precast alternate chest wall of the present invention,

Fig. 2b is a structural perspective view of the precast alternating chest wall, girder and connecting slab of the present invention,

Figs. 2c and 2d illustrate cross-sectional views of connections between a half-body bridge and a connecting slab using a precast alternate chest wall of the present invention.

The half-sheath bridge 100 using the precast alternate chest wall 120 according to the present invention includes the bridge substructure 110 including the alternation as shown in FIGS. 2A and 2B, the precast alternate chest wall 120, the girder 130, An end robo 140, and a connection slab 150. [

First, the bridge substructure 110 includes the concept of alternation and bridge as shown in FIG. 2A and FIG. 2B, but the bridge 111 is referred to in the semi-integral bridge.

Generally, such an alternation (111) is made of a cast concrete using an unillustrated form, etc. The alternation can be constructed using a pile, and a space for constructing the alternation (111) And the back surface of the alternate backing can be backed up again.

The alternation 111 is a reinforced concrete structure formed so as to extend in the transverse direction. On the upper surface, a bridge support 112 is installed to support a precast alternate chest wall 120 described later.

There is no limitation on the number of the bridge supports 112 and the girder 130 mounted on the precast alternate chest wall 120 is allowed to allow the girder 130 without being constrained when the longitudinal displacement occurs due to temperature, The precast alternating chest wall 120 and the girder 130 are actuated together by the displacement of the girder, and the backcasting is installed on the backside of the precast alternating chest wall 120 with no backing so that the backing does not constrain such displacement.

2A and 2B, the precast alternate chest wall 120 is formed in an L-shaped cross-section as a whole, and is formed so as to extend horizontally from the upper portion of the vertical plate 121 and the lower portion of the vertical plate And the horizontal plate 122 is formed to include the flat plate 122.

The height of the vertical plate 121 may be determined to be lower than the height of the upper surface of the fixed girder 130. The horizontal plate 122 may have an extended length sufficient to allow the end of the girder 130 to be seated. .

At this time, as shown in FIG. 2B and FIG. 3D, a shear connection member 125 is further formed to be embedded in the alternate chest wall concrete C2 placed on the vertical plate of the L-type precast chest wall 120 and the surface of the horizontal plate, It is preferable that the composite performance of the end transverse portion 140 and the L-type precast chest wall 120 by the concrete C1 for the connection slab can be improved as described above.

At this time, the upper surface of the horizontal plate 122 is formed in consideration of the shape of the end portion as shown in FIG. 2B so that the end portion of the girder 130 can be seated and mounted.

The end of the girder 130 is seated in the mounting groove 123 and the precast alternating chest wall 120 and the girder 130 are strengthened by the installation of the concrete C2 for the alternate chest wall.

This precast alternate chest wall 120 can be installed in a manner such that the girder 130 is placed in the mounting groove 123 regardless of the extension direction of the precast alternate chest wall 120. Therefore, .

Accordingly, it can be seen that the end of the girder can be installed in the mounting groove 123 formed on the horizontal plate of the L-type precast chest wall regardless of the direction of extension of the L-type precast alternate chest wall.

As shown in FIGS. 2A and 2B, on the upper surface of the vertical plate of the precast alternate chest wall 120, a connecting reinforcing bar 124 for securing structural integrity with a connecting slab 150 described later is extended from the inside, So that the connecting reinforcing bars 124 extend into the connecting slabs 150 when the connecting slabs 150 are installed.

2E, the horizontal plate 122 is horizontally formed upwardly from the bottom of the vertical plate 121, and the extended portion of the vertical plate 121 is supported by a pad so as to slide on the upper surface of the vertical plate 121, Installation can be made possible.

2C, the vertical plate and the girder end face of the L-type precast chest wall are spaced apart from each other so that the L-type precast chest wall 120 and the connecting slab 150 are structurally integrated with each other, It is also possible to form the connecting slab by using the concrete C1 for the connecting slab so that the upper portion of the connecting reinforcing bar 124 extending from the connecting slab is embedded so that the bottom end of the connecting slab contacts the bottom end of the vertical plate .

Further, as shown in FIG. 2B, the horizontal plate 122 of the L-shaped precast chest wall is further provided with a transverse prism 126 to introduce the prestress in the transverse direction, thereby optimizing the cross section of the L-shaped precast chest wall 120 The weight can be minimized, thereby making it possible to improve the workability.

2B, both ends of the girder 130 are fixed to the mounting grooves 123 of the horizontal plate 122 of the precast alternate chest wall 120, as shown in FIG. Thus, stable and accurate loading of the girder 130 is possible.

These girders are mounted on the precast alternate chest wall 120 and then both end portions are integrally formed with the precast alternate chest wall 120 and the alternate chest wall concrete C2 by molding the precast alternate chest wall 120 as shown in FIG. .

The alternate chest wall concrete C2 serves as an end robo 140 connecting the ends of the girder 130 in the lateral direction.

Further, the girder 130 may be formed to have a stepped edge formed on the bottom surface of both legs, so that the bottom surface of the step may be seated in the mounting groove 123, so that the girder 130 may be advantageous for embroidering.

2b and Fig. 2c, a connecting rod 131 protruding horizontally is further formed on the end surface of the girder 130 so that a connecting hole 131 formed on the vertical plate 121 of the precast chest wall 120, The connecting rod 131 is inserted into the front wall 127 and the connecting rod 131 is fastened to the vertical wall 121 of the precast chest wall 120 with a fastening nut so that sufficient structural integrity can be secured.

2B and 2C, the connection slab 150 is formed in a horizontal plate shape so that its bottom surface is in contact with the upper surface of the vertical plate of the precast chest wall 120 and the upper surface thereof is the same as the upper surface of the girder 130, Concrete (C1) is applied.

At the end of the connecting slab 150, the connecting reinforcing bars 124 of the precast alternating chest wall 120 extend into the connecting slab 150 to be completed.

If a displacement occurs in the longitudinal direction due to the temperature contraction of the girder 130 during the common operation, the ends of the girder and the connected connection slabs 150 are displaced together. In order not to confine such displacements, So that the uncompacted backfill G1 is formed on the backside of the cast alternate chest wall 120. [

The longitudinal thickness of the uncompacted backfill G1 is adjusted according to the amount of displacement. In addition, the backside of the uncompacted backfill G1 is constructed such that the backfill G2 is formed so as to support the connecting slab 150. [

[Method of constructing the half-piece bridge 100 using the precast alternate chest wall 120 of the present invention]

Figs. 3a, 3b, 3c and 3d are construction sequence diagrams of the precast alternating chest wall, girder and connecting slab of the present invention. Fig.

First, as shown in FIG. 3A, when a bridge is constructed, a bridge substructure 110 such as an alternate pier is constructed. In the case of a multi-span bridge, a pier may be installed between the two alternations. The present invention will be described based on the case where only the two alternations 111 are installed.

Such an alternation 111 may be constructed as a reinforced concrete structure composed of a bottom plate and a trunk portion, and is applied to the upper surface of the ground by using an unillustrated formwork.

A plurality of bridge supports 112 are installed on the upper surface of the bridge 111, and the bridge 111 is backfilled on the bridge 111 and then compaction is performed.

Next, as shown in FIG. 3B, the precast bridging chest wall 120 is mounted on the bridges of the alternating upper surface so that the bottom surface of the horizontal plate 122 is supported. Thus, the backcasting bridge chest wall 120 is subjected to the unloading backlash G1.

Next, as shown in FIG. 3C, the girder 130 is mounted in a mounting groove 123 formed in the horizontal plate 122 of the precast bridge chest wall 120, It is seen that a large number of transversely spaced horizontal plates are formed on the horizontal plate of the chest wall 120.

As described above, the connecting rod 131, which is embedded in the end surface of the girder 130 and protruded horizontally, is inserted into the fastening hole formed in the vertical plate 121, and the connecting rod 131 is fastened to the precast chest wall (121) of the base plate (120).

Next, as shown in FIG. 3D, the end portion of the girder 130 is formed into a shape of the precast bridge chest wall 120 to form the end robo 140, which is constructed using the concrete for the alternate chest wall C2. So that the end portion of the girder 130 and the precast alternate chest wall 120 are tightened by the end transverse portion 140.

Next, as shown in FIG. 3E, a backfill G2 compaction is applied to the backside G1 of the uncompacted backfill G1, and the connecting slab 150 is constructed as the concrete C1 for the connecting slab. At this time, the connection reinforcing bars 124 extending from the precast bridge chest wall 120 are embedded into the connection slabs 150 so that the connection slabs 150 and the precast bridge chest walls 120 are integrated with each other, And the upper surface of the girder 130 are made to coincide with each other to complete the construction of the half-body bridge of the present invention.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Half-day bridges
110: Bridge infrastructure
111: Shift 112: Bridge support
120: L-type precast alternate chest wall
121: vertical plate 122: horizontal plate
123: mounting groove 124: connecting reinforcing bar
125: shear connection member 126: transverse tension member
130: girder 131: connecting rod
140: end robo 150: connecting slab
C1: Concrete for connection slab
C2: Concrete for alternative chest wall
G1: Uncompensated backfill G2: Backfilled

Claims (11)

(a) An L-shaped precast chest wall 120 is installed to be supported on the upper surface of the bridge substructure 110 installed on the ground,
(b) an end of the girder 130 is seated on the horizontal plate 122 of the L-type precast chest wall 120,
(c) Concrete C2 for an alternate chest wall which makes the ends of the L-shaped precast chest wall 120 shaped and integrated with the end portions of the loaded girders 130 in the transverse direction is placed to form the end robo 140 A method of constructing a half - body bridge using precast alternating chest walls comprising: a. The method according to claim 1,
The L-type precast chest wall 120 of step (a)
And a horizontal plate (122) formed to extend horizontally upward from a lower portion of the vertical plate, wherein the vertical plate (121) having a fastening hole (127) A shear connector 125 is formed so as to be embedded in the sheath C2,
A connecting rod 131 formed on the end surface of the girder 130 is inserted into the fastening groove 127 formed in the vertical plate of the L precursor chest wall 120 to fasten the connecting rod 131 to the back surface of the vertical plate. A Method for the Construction of a Semi - Circular Bridge Using a Cast Chest Wall. delete The method according to claim 1,
The L-type precast alternate chest wall 120 is formed to include a vertical plate 121 and a horizontal plate 122. The height of the vertical plate 121 corresponds to the height of the upper portion of the girder 130 So that the bottom surface of the connecting slab 150 is brought into contact with the upper surface of the vertical plate 121 so that the upper surface of the girder 130 and the upper surface of the connecting slab 150 coincide with each other. How to construct a half - body bridge. 5. The method of claim 4,
The upper portion of the connecting reinforcing bar 124 extending from the upper surface of the vertical plate 121 of the L-type precast chest wall 120 is embedded so that the L-type precast chest wall 120 and the connecting slab 150 are structurally integrated with each other. The bridge slab 150 is formed by using the concrete C1 for the connection slab so that the end surface of the connection slab 150 is in contact with the upper end surface of the girder 130. The half- Construction method. 5. The method of claim 4,
The end plate 121 of the L-shaped precast chest wall 120 and the end surface of the girder 130 are spaced apart from each other such that the L-type precast chest wall 120 and the connecting slab 150 are structurally integrated with each other, The connecting slab 150 is formed by using the concrete C1 for the connecting slab so that the upper portion of the connecting reinforcing bar 124 extending from the spaced space is embedded so that the end face of the connecting slab 150 A method of constructing a half - body bridge using a precast alternate chest wall contacting the upper end surface. The method according to claim 1,
The girder 130 is a PSC girder which is provided with a girder groove 123 formed in the horizontal plate 122 of the L-shaped precast chest wall 120 regardless of the direction in which the L-type precast alternate chest wall 120 extends in the transverse direction. A method of constructing a half - body bridge using a precast alternate chest wall. The method according to claim 1,
The method of claim 1, wherein the girder (130) is further provided with a stepped ridge in the bottom of each leg so that the bottom surface of the step is seated in the mounting groove (123). The method according to claim 1,
In the step (a), the back side of the L-type precast chest wall is provided with a compaction back chest, and a precast alternate chest wall (G1) is formed on the upper side of the compaction back- A Method of Construction of a Semi - Circular Bridge Using. The method according to claim 1,
A method of constructing a half-body bridge using a precast alternate chest wall using a transverse tensional material (126) further provided on the horizontal plate (122) of the L-type precast chest wall (120) to introduce a prestress in a transverse direction. A half-body bridge using precast alternate chest walls constructed by the method of the present invention using the precast alternate chest wall.

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