KR20200075584A - Prestressed concrete girder and bridge construction method thereof - Google Patents

Abstract

A prestressed concrete girder of the present invention comprises: an upper tension member (210) which is buried in an upper region of a girder (100) and is installed in a longitudinal direction of the girder (100); a fixation steel beam (110) embedded in the girder (100) to fix the upper tension member (210); a lower tension member (220) installed in a lower region of the girder (100); and a hollow member (130) embedded in the girder (100). The fixation steel beam (110) includes: an upper flange (111) having an upper surface exposed to an upper surface of the girder (100); a web (112) formed at a lower side of the upper flange (111); a lower flange (113) coupled to a lower surface of the web (112); and fixation plates (114) coupled to front and rear ends of the upper flange (111), the web (112), and the lower flange (113), respectively. Both ends of the upper tension member (210) are respectively fixed to the fixation plates (114) formed in front and rear of the fixation steel beam (110) wherein, as shown in FIG. 1, in the fixation steel beam (110), the upper tension member (210) is fixed and the lower tension member (220) is installed. The upper tension member (210) is installed on the fixation steel beam (110) having a structure as shown in FIG. 2. According to the present invention, in the upper part of a girder, embedded is an upper tension member which can introduce compressive force to a lower region of the girder after coupling of a bottom plate and the girder.

Description

Bridge structure using prestressed concrete girder{PRESTRESSED CONCRETE GIRDER AND BRIDGE CONSTRUCTION METHOD THEREOF}

The present invention relates to the construction field, and more particularly, to a prestressed concrete girder and a bridge structure using the same.

The girder bridge has a construction sequence of pouring concrete to form a bottom plate on the top of the girder after mounting the girder. After curing the concrete, it is integrated with the bottom plate and the girder to resist vehicle loads and other loads.

Prestressed concrete girder is widely applied to girder bridges with the advantage of being able to form a long span while lowering the mold height.

The prestressed concrete girder is designed to introduce a compressive force to the shear surface. When a tensile force is generated by a common load, an additional load should be introduced using a reinforcing steel wire or steel bar outside the girder.

However, since the mold height of the girder is low, there is a problem that it is difficult to install a stranded wire or a steel bar.

The present invention has been derived to solve the above problems, and after the bottom plate and the girder are synthesized, a tension member capable of introducing additional compressive force to the lower region of the girder is installed.

To solve the above problems, the prestressed concrete girder of the present invention is embedded in the upper region of the girder 100, the upper tension member 210 is installed along the longitudinal direction of the girder 100; A fixing steel type 110 embedded in the girder 100 to fix the upper tension member 210; A lower tension member 220 installed in a lower region of the girder 100; Including, but; the hollow member 130 embedded in the inner side of the girder 100; the fixing steel type 110, the upper flange 111 is exposed to the upper surface of the upper surface of the girder 100; Abdomen 112 formed on the lower side of the upper flange 111; A lower flange 113 coupled to the lower surface of the abdomen 112; The upper flange 111, the abdomen 112, the fixing plate 114 coupled to the front and rear ends of the lower flange 113, respectively; includes, both ends of the upper tension member 210, the fixing steel type 110 ) Are fixed to the fixing plates 114 formed at the front and rear of each.

On the front surface of the fixing plate 114 formed in the front of the fixing plate 114, a protrusion 114a protruding forward is formed so that the upper tension member 210 penetrates, and the upper tension member 210 is the It is preferable to settle at the protrusion 114a.

The fixing steel type 110 includes a work measurement wear type 110a installed in one area of the girder 100 and a work measurement wear type 110b installed in the other area, and the work measurement wear type 110a and the other side A block-out part 300 is formed at at least one of the front or rear of the fixing steel type 110b, and one side 313 of the one side block-out part 310 formed in the one-piece measuring type 110a is the girder. It is preferable that the other side surface 324 of the other block-out part 320 formed in the other edge-mounting type 110b is formed to extend to the other edge region of the girder 100. .

The one side block-out part 310 includes an upper surface 311; Lower surface 312; The one side 313; The other side 314; Front 315; Including, but; rear 316, the one side 313 is formed in a position spaced inwardly from one side of the girder 100, the top surface 311 is from the top surface of the girder 100 It is formed at a position spaced downward, and the area S1 between the one side 313 and one side of the girder 100 and the area S2 between the top surface 311 and the top surface of the girder 100 are the It is preferable to be filled with concrete (C) poured to form the girder 100.

When the concrete (C) is poured to form the girder 100, the block-out part 300 is preferably formed by installing a styrofoam 500 to form the block-out part 300.

It is preferred that the upper flange 111 is coupled with a shear connector 400 protruding upwardly, and the shear connector 400 is coupled to the abdomen 112 along the side.

A bridge structure using a prestressed concrete girder according to an embodiment of the present invention includes a girder production step of manufacturing the girder 100; A girder mounting step of mounting the girder 100 on a pier or a shift; Including, but; forming a bottom plate on the upper surface of the girder 100; including, to introduce a compressive force to the lower surface of the girder 100 among the bridge common, the styrofoam installed in the block-out unit 310 Block out portion removing step of removing (500); A release step of cutting the protrusion 114a formed on the fixing plate 114 to release the load introduced into the upper tension member 210; And charging the mortar in the block-out part 310.

In the girder production step, the region S1 between the one side and the region S2 between the upper surfaces are preferably filled by the concrete C.

The step of removing the block-out portion is preferably to break the concrete wall (C-1) cured by being filled in the region (S1) between the one side and remove the styrofoam 500.

It is preferable that the outer surface of the region S1 between the one side is marked with the recognition that the region S1 is between the one side.

In the present invention, an upper tension member capable of introducing a compressive force to the lower region of the girder after the combination of the bottom plate and the girder is embedded in the upper girder.

Since the upper tension member has a structure in which the compressive force introduced at the time of girder fabrication is released through the block-out part, the compressive force can be introduced into the lower region of the girder without installing additional steel wires or bars.

1 is a detailed perspective view of a front part of a prestressed concrete girder according to an embodiment of the present invention
Figure 2 is a perspective view of one side end of the fixing steel according to an embodiment of the present invention
Figure 3 is a perspective view showing that the upper tension member is fixed to the fixing steel type according to an embodiment of the present invention
Figure 4 is a side view showing that the upper tension member is fixed to the fixing steel type according to an embodiment of the present invention
Figure 5 is a cross-sectional view showing that the fixing steel type is installed on the prestressed concrete girder according to an embodiment of the present invention, the block-out portion is formed
6 is a view showing that the shear connection material is coupled to the fixing steel type according to an embodiment of the present invention
7 is a view showing that the lower tension member according to an embodiment of the present invention is installed
8 is a view showing a lateral region and an upper region according to an embodiment of the present invention
9 is a perspective view of a block-out part according to an embodiment of the present invention
10 is a view showing that the upper tension member is released by cutting the protrusion according to an embodiment of the present invention
FIG. 11 is a view showing that a display capable of confirming a lateral region according to an embodiment of the present invention is shown on the side of a girder.

An embodiment of a bridge structure using a prestressed concrete girder according to the present invention will be described in detail with reference to the accompanying drawings, and in describing with reference to the accompanying drawings, identical or corresponding components are given the same drawing numbers In this regard, redundant description will be omitted.

In addition, terms such as first and second used hereinafter are only identification symbols for distinguishing the same or corresponding components, and the same or corresponding components are limited by terms such as first and second. no.

In addition, the combination does not mean only a case in which a physical contact is directly made between the respective components in a contact relationship between the components, and different components are interposed between the respective components, so that the components are in different components. Use it as a comprehensive concept until each contact is made.

Hereinafter, a bridge structure using a prestressed concrete girder will be described in detail with reference to the accompanying drawings.

The prestressed concrete girder of the present invention is embedded in the upper region of the girder 100, the upper tension member 210 is installed along the longitudinal direction of the girder 100; In order to settle the upper tension member 210, the fixing steel type 110 embedded in the girder 100; A lower tension member 220 installed in a lower region of the girder 100; Including, but; a hollow member 130 embedded in the inner side of the girder 100; the fixing steel type 110 includes an upper flange 111 on which an upper surface is exposed on the upper surface of the girder 100; Abdomen 112 formed on the lower side of the upper flange 111; A lower flange 113 coupled to the lower surface of the abdomen 112; The upper flange 111, the abdomen 112, the fixing plate 114 coupled to the front and rear ends of the lower flange 113, respectively; includes, both ends of the upper tension member 210, the front of the fixing steel 110 And a fixing plate 114 formed at the rear.

In this case, as shown in Figure 1, the upper tension member 210 is fixed to the fixing steel type 110, and the lower tension member 220 is installed.

The upper tension member 210 is installed in the fixing steel type 110 having a structure as shown in FIG. 2.

The front of the fixing plate 114 formed in the front of the fixing plate 114 is formed with a protrusion 114a protruding forward so that the upper tension member 210 penetrates, and the upper tension member 210 is formed from the protrusion 114a. It is advisable to settle.

A protrusion 114a is formed on the front surface of the fixing plate 114 of the fixing steel type 110 as shown in FIG. 3, and the protrusion 114a is formed to facilitate the release of the upper tension member 210.

The fixing steel type 110 includes a one-measurement mounting type 110a installed in one area of the girder 100 and a second-measurement mounting type 110b installed in the other area, and one-measurement mounting type 110a and another measurement-bonding type 110b ) At least one of the front or rear of the block-out portion 300 is formed, one side surface 313 of the one side block-out portion 310 formed in the one-piece mounting type 110a is one side edge of the girder 100 It is preferable that the other side surface 324 of the other side block-out part 320 formed to extend to the area and formed in the other measurement attaching type 110b is extended to the other edge area of the girder 100.

One side block-out unit 310 has an upper surface 311; Lower surface 312; One side 313; The other side 314; Front 315; Including, but; rear 316; one side 313 is formed in a position spaced inwardly from one side of the girder 100, the upper surface 311 is spaced downward from the upper surface of the girder 100 Formed in position, the region S1 between one side 313 and one side of the girder 100 and the region S2 between the top surface 311 and the top surface of the girder 100 are poured to form the girder 100 It is preferably filled by the concrete (C).

As shown in FIG. 8, the block-out part 310 is closed by an upper surface and a side surface by an area S1 between one side and an area S2 between the upper surfaces.

The block-out part 300 is preferably formed by installing a styrofoam 500 to form the block-out part 300 when pouring concrete (C) for forming the girder 100.

In this case, the block-out portion 300 is formed by the styrofoam 500, and is formed to release the upper tension member 210.

That is, after breaking the region (S1) between one side formed to have a thickness of 2 ~ 8am, and removing the styrofoam 500, cut the protrusion (114a) formed on the front of the fixing plate 114 to cut the upper tension member (210) Release.

It is preferable that the upper flange 111 is coupled with a shear connector 400 protruding upward, and the abdominal 112 has a shear connector 400 coupled along the side.

As shown in FIG. 6, the front end connecting member 400 may be installed on the top and side surfaces of the fixing steel type 110.

In addition, in some cases, the lower end of the fixing steel 110 may be formed with a shear connector 400 protruding downward.

A bridge structure using a prestressed concrete girder according to an embodiment of the present invention is a girder production step of manufacturing the girder 100; Girder mounting step of mounting the girder 100 on a pier or a shift; Including; a bottom plate forming step of forming a bottom plate on the upper surface of the girder 100; including, to introduce a compressive force to the lower surface of the girder 100 among the bridge common, styrofoam 500 installed in the block-out portion 310 Removing the block-out portion to remove; A release step of cutting the protrusion 114a formed in the fixing plate 114 to release the load introduced into the upper tension member 210; It includes; charging the mortar to the block-out unit 310.

The biggest feature of the present invention is that it is easy to introduce additional compressive stress on the lower surface of a common girder.

That is, when the protrusion 114a formed in the fixing steel type 110 is removed to release the load introduced into the upper tension member 210, the tensile force introduced into the upper tension member 210 is released and the compressive force is introduced into the lower surface of the girder. .

Through this, without a separate external device, it is possible to introduce a compressive force on the lower surface of the girder.

In the girder manufacturing step, the region S1 between one side and the region S2 between the upper surfaces are preferably filled by concrete C.

The step of removing the block-out portion is preferably performed by breaking the concrete wall (C-1) cured by filling the region S1 between one side and removing the styrofoam 500.

It is preferable that the outer surface of the region S1 between one side is marked with the recognition that the region S1 is between one side.

As shown in FIG. 11, the blockout portion can be easily grasped by displaying the indication of blockout in the region S1 between one side surface of the girder.

C: Concrete C-1: Concrete wall
S1: Area between one side S2: Area between upper surface
100: girder 110: fixing steel type
110a: Daily measurement wear type 110b: Other measurement wear type
111: upper flange 112: abdomen
113: lower flange 114: settling plate
114a: protrusion 130: hollow member
210: upper tension member 220: lower tension member
300: block-out unit 310: one side block-out unit
311: Top 312: Bottom
313: One side 314: The other side
315: Front 320: Other block-out part
324: other side 400: shear connection material
500: Styrofoam

Claims (10)

An upper tension member 210 which is buried in the upper region of the girder 100 and is installed along the longitudinal direction of the girder 100;
A fixing steel type 110 embedded in the girder 100 to fix the upper tension member 210;
A lower tension member 220 installed in a lower region of the girder 100;
Including, but; a hollow member 130 embedded in the inside of the girder 100;
The fixing steel type 110 is
An upper flange 111 on which an upper surface is exposed on the upper surface of the girder 100;
Abdomen 112 formed on the lower side of the upper flange 111;
A lower flange 113 coupled to the lower surface of the abdomen 112;
Includes; the upper flange 111, the abdomen 112, the fixing plate 114 coupled to the front and rear ends of the lower flange 113, respectively;
Prestressed concrete girder, characterized in that both ends of the upper tension member 210 is fixed to the fixing plate 114 formed on the front and rear of the fixing steel type 110, respectively.
According to claim 1,
The front of the fixing plate 114 formed in the front of the fixing plate 114 is formed with a projection 114a protruding forward so that the upper tension member 210 penetrates,
The upper tension member 210 is a prestressed concrete girder, characterized in that fixed in the protrusion (114a).
According to claim 2,
The fixing steel type 110 is
It includes a work measurement wear type (110a) installed in one area of the girder (100) and another measurement wear type (110b) installed in the other area,
The block-out part 300 is formed at least in one of the front or rear of the one-measurement wearable type 110a and the other measurement-wearable wearable type 110b,
One side surface 313 of the one side block-out portion 310 formed in the one-piece measuring mounting type 110a is formed to extend to one edge region of the girder 100,
A prestressed concrete girder, characterized in that the other side surface 324 of the other side blockout portion 320 formed in the rudder measurement mounting type 110b is extended to the other edge region of the girder 100.
According to claim 3,
The one side block-out unit 310
Upper surface 311;
Lower surface 312;
The one side 313;
The other side 314;
Front 315;
Including the rear 316;
The one side 313 is formed at a position spaced inwardly from one side of the girder 100,
The upper surface 311 is formed at a position spaced downward from the upper surface of the girder 100,
The region S1 between the one side 313 and one side of the girder 100 and the region S2 between the top surface 311 and the top surface of the girder 100 are poured to form the girder 100 Prestressed concrete girder, characterized in that filled by the concrete (C).
According to claim 4,
The block-out part 300 is
The prestressed concrete girder characterized in that when the concrete (C) is placed to form the girder 100, a styrofoam 500 is installed to form a block-out part 300.
The method of claim 5,
On the upper surface of the upper flange 111, a shear connector 400 protruding upward is coupled,
Prestressed concrete girder, characterized in that the abdominal 112 is coupled to the shear connector 400 along the side.
A bridge structure using the prestressed concrete girder of claim 6,
Girder production step of manufacturing the girder 100;
A girder mounting step of mounting the girder 100 on a pier or a shift;
Including; bottom plate forming step of forming a bottom plate on the upper surface of the girder 100;
In order to introduce a compressive force to the lower surface of the girder (100) among the common bridge,
A block-out part removing step of removing the styrofoam 500 installed in the block-out part 310;
A release step of cutting the protrusion 114a formed on the fixing plate 114 to release the load introduced into the upper tension member 210;
Filling the mortar in the block-out portion 310; Bridge structure comprising a.
The method of claim 7,
In the above girder production step
The bridge structure, characterized in that the region (S1) between the one side and the region (S2) between the upper surface is filled by the concrete (C).
The method of claim 8,
Block out part removal step
A bridge structure characterized by breaking the concrete wall (C-1) filled in the region S1 between the one side and curing and removing the styrofoam 500.
The method of claim 9,
The bridge structure, characterized in that the outer surface of the region (S1) between the one side is marked to recognize that the region (S1) between the one side.

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