KR20200075585A - 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 (300) embedded in the upper region of 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 (400) embedded in the girder (100). The girder (100) is a segmented girder including a central segment portion (110), one segment portion (120), and the other segment portion (130). The fixation steel beam (300) is installed on the central segment portion (110), the one segment portion (120), and the other segment portion (130) in common. The present invention is the prestressed concrete girder, in which the central segment portion (110), the one segment portion (120), and the other segment portion (130) are manufactured in a segmented state and coupled, as shown in FIG. 1 wherein the fixation steel beam (300) is coupled to an upper side of the central segment portion (110) as shown in FIG. 4. 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 on the lower surface of the girder due to the shared load, an additional load must be introduced by installing a reinforcing steel wire or steel bar on the outside of the girder.

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

In addition, in the case of a long long bridge, there has been a problem in that it is difficult to carry the girder.

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.

In addition, the girder is manufactured in a segmented state and transported, so it is easy to transport by taking a structure to assemble before mounting.

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; In order to fix the upper tension member 210, the fixing steel type 300 embedded in the upper region in the girder 100; A lower tension member 220 installed in a lower region of the girder 100; Including; a hollow member 400 embedded in the inner side of the girder 100; the girder 100 includes a central segment 110; One-sided segment 120; It is a segment girder including; the other side segment portion 130, the fixing steel type 300 is commonly installed in the central segment portion 110, one side segment portion 120, the other side segment portion 130.

The fixing steel type 300 is coupled to the upper portion of the central segment portion 110, and the front portion 300f and the rear portion 300b of the fixing steel type 300 are forward and backward of the central segment portion 110. Is installed so as to protrude respectively, and the front portion 300f and the rear portion 300b are inserted into the upper surfaces of the one side segment portion 120 and the other side segment portion 130, and the other side segment groove portion 121 and the other side segment are inserted. It is preferable that the sub-grooves 131 are respectively formed.

The front portion 300f and the rear portion 300b of the fixing steel type 300 are respectively fitted to the one-sided segment groove portion 111 and the other-side segment groove portion 131, and the one-side segment groove portion ( 121) and the other side segment groove portion 131 is filled with concrete (C) so that the front portion 300f and the rear portion 300b are combined with the one side segment portion 120 and the other side segment portion 130 It is desirable to be.

The fixing steel type 300 includes an upper flange 310 on which an upper surface is exposed on the upper surface of the girder 100; The abdomen 320 formed below the upper flange 310; A lower flange 330 coupled to the lower surface of the abdomen 320; The upper flange 310, the abdomen 320, the fixing plate 340 coupled to the front and rear ends of the lower flange 330, respectively; including, but, both ends of the upper tension member 210 is the fixing steel type (300 ) Is preferably fixed to the fixing plate 340 formed on the front and rear of each.

On the front surface of the fixing plate 340 formed in front of the fixing steel type 300, a protruding portion 341 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 341.

The fixing steel type 300 includes a work measurement wear type 300a installed in one region of the girder 100 and a work measurement wear type 300b installed in another region, and the work measurement wear type 300a and the other side A block-out portion 500 is formed in at least one of the front or rear of the fixing steel type 300b, and one side 513 of the one side block-out portion 510 formed in the one-piece measuring type 300a is the girder. It is preferable that the other side surface 524 of the other block-out portion 520 formed in the other side of the stiffening type 300b is formed to extend to the other edge region of the girder 100. .

The one side block-out part 510 has an upper surface 511; Lower surface 512; The one side 513; The other side 514; Front 515; Including, but; rear 516, the one side 513 is formed in a position spaced inwardly from one side of the girder 100, the upper surface 511 is from the top surface of the girder 100 It is formed at a position spaced apart from the lower side, the lateral region (S1) between the one side 513 and one side of the girder 100 and the upper region (S2) between the upper surface 511 and the upper surface of the girder 100 ) Is preferably filled by the concrete (C) that is poured to form the girder 100.

The block-out portion 500 is preferably formed by styrofoam 600 when pouring the concrete (C) for forming the girder 100.

It is preferable that the front end of the upper flange 310 is coupled with a shear connecting material 800 protruding upward, and the front end 320 is coupled with the shear connecting material 800 along the side.

A bridge structure using a prestressed concrete girder according to an embodiment of the present invention includes the central segment part 110, the one side segment part 120, the other side segment part 130 to which the fixing steel type 300 is coupled. Segment girder production step to produce each; A girder manufacturing step of coupling the central segment part 110, the one side segment part 120, and the other segment part 130 with a fastening member 700; A tension force introducing step of tensioning the lower tension member 220 to introduce a tension force; A girder mounting step of mounting the girder 100 on a pier or a shift; Including the; bottom plate forming step of forming a bottom plate on the upper surface of the girder 100; including, in order to introduce a compressive force to the lower surface of the girder 100 among the bridge structure, the installed in the block-out unit 310 Block out portion removing step of removing the styrofoam 500; A release step of cutting the protrusion 341 formed on the fixing plate 340 to release the load introduced into the upper tension member 210; And charging the mortar in the block-out part 310.

In the girder manufacturing step, the fastening member 700 is installed in the cross-section corner of the girder 100, the central segment 110, the one side segment 120, the other side segment 130 It is commonly installed through, and is preferably settled after being tensioned by a single tension device.

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 side view of a prestressed concrete girder in which a central segment part, one side segment part, and the other segment part are combined according to an embodiment of the present invention.
Figure 2 is a perspective view of one side segment according to an embodiment of the present invention
Figure 3 is a perspective view of the other segment according to an embodiment of the present invention
Figure 4 is a perspective view of the central segment according to an embodiment of the present invention
Figure 5 is a side view of the central segment according to an embodiment of the present invention
6 is a perspective view of a prestressed concrete girder in which a central segment, one segment, and the other segment are joined by fastening members according to an embodiment of the present invention.
7 is a view showing that the lower tension member, the fixing steel type, the hollow member is installed according to an embodiment of the present invention
8 is a perspective view of a fixed steel front portion according to an embodiment of the present invention
9 is a partial perspective view showing that a protrusion is formed in a fixing plate according to an embodiment of the present invention.
10 is a view showing that the upper tension member is fixed to the protrusion according to an embodiment of the present invention
11 is a view showing that the block-out portion is formed according to an embodiment of the present invention
12 is a view showing that the shear connection material is coupled to the fixing steel according to an embodiment of the present invention
13 is a view showing that the block-out portion is formed in the front portion of the fixing steel according to an embodiment of the present invention
14 is a view showing a lateral region and an upper region according to an embodiment of the present invention
15 is a perspective view of a block-out part according to an embodiment of the present invention
16 is a view showing a display capable of confirming a lateral region according to an embodiment of the present invention is shown on the side of the girder
17 is a view showing that the upper tension member is released by cutting the protrusion according to an embodiment of the present invention.

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 fix the upper tension member 210, the fixing steel type 300 embedded in the upper region in the girder 100; A lower tension member 220 installed in a lower region of the girder 100; It includes; a hollow member 400 embedded in the inside of the girder 100; includes, the girder 100 includes a central segment 110; One-sided segment 120; It is a segment girder including; the other side segment 130, the fixing steel type 300 is commonly installed in the central segment 110, one side segment 120, the other segment 130.

The present invention is a prestressed concrete girder in which the central segment portion 110, one side segment portion 120, and the other side segment portion 130 are respectively manufactured in a segmented state and combined as shown in FIG.

At this time, the fixing steel type 300 is coupled to the upper side of the central segment 110 as shown in FIG. 4.

A fixing steel type 300 is coupled to an upper portion of the central segment 110, so that the front portion 300f and the rear portion 300b of the fixing steel 300 protrude in front and rear of the central segment 110, respectively. One side segment groove part 121 and the other segment groove part 131 in which the front part 300f and the rear part 300b are inserted are installed on the upper surfaces of the one side segment part 120 and the other side segment part 130, respectively. It is preferably formed.

In this case, the front portion 300f and the rear portion 300b of the fixing steel type 300 are inserted into the upper surfaces of the one side segment portion 120 and the other side segment portion 130, and the other side segment groove portion 121 and the other side segment portion are inserted. The grooves 131 are formed as shown in FIGS. 2 and 3.

The front portion 300f and the rear portion 300b of the fixing steel type 300 are respectively fitted to the one-sided segment groove portion 111 and the other-side segment groove portion 131, and the one-side segment groove portion 121 and the other segment portion It is preferable that the groove (131) is filled with concrete (C) so that the front portion (300f) and the rear portion (300b) are combined with the one side segment portion (120) and the other side segment portion (130).

After the front portion 300f and the rear portion 300b of the fixing steel type 300 are respectively fitted to the one-sided segment groove portion 111 and the other-side segment groove portion 131, the concrete C is one-sided segment groove portion ( 111) and by filling the other segmental groove portion 131, it is coupled to one side segment 120 and the other segment 130.

The fixing steel type 300 includes an upper flange 310 on which an upper surface is exposed on the upper surface of the girder 100; The abdomen 320 formed below the upper flange 310; A lower flange 330 coupled to the lower surface of the abdomen 320; The upper flange 310, the abdomen 320, the fixing plate 340 coupled to the front and rear ends of the lower flange 330, respectively; including, but both ends of the upper tension member 210, the front of the fixing steel type 300 It is preferable to be fixed to each of the fixing plate 340 formed at the rear.

On the front surface of the fixing plate 340 formed in front of the fixing steel type 300, a protrusion 341 protruding forward is formed so that the upper tension member 210 penetrates, and the upper tension member 210 is formed from the protrusion 341. It is desirable to settle.

The front surface of the fixing plate 340 of the fixing steel type 300 is formed with protrusions 341 as shown in FIGS. 8, 9 and 10, and protrusions 341 are formed to facilitate the release of the upper tension member 210.

The settled steel type 300 includes a work measurement wear type 300a installed in one area of the girder 100 and another measurement wear type 300b installed in the other area, and a work measurement wear type 300a and another measurement wear type 300b. ) At least one of the front or rear of the block-out portion 500 is formed, one side 513 of the one side block-out portion 510 formed in the one-piece mounting type (300a) is one side edge of the girder 100 It is preferable that the other side surface 524 of the other block-out portion 520 formed to extend to the area and formed in the other measurement attaching type 300b is extended to the other edge area of the girder 100.

One block-out portion 510 has an upper surface 511; Lower surface 512; One side 513; The other side 514; Front 515; Including, but; rear 516, one side 513 is formed in a position spaced inwardly from one side of the girder 100, the upper surface 511 is spaced downward from the upper surface of the girder 100 It is formed in the position, the lateral region (S1) between the one side surface 513 and the one side surface of the girder 100 and the upper surface area (S2) between the top surface of the upper surface 511 and the girder 100, the girder 100 It is preferably filled with concrete (C) that is poured to form.

As shown in FIGS. 11 and 13, a block-out part 310 is formed at the front or rear of the fixing steel 300, as shown in FIG. 14, the lateral region S1 and the upper region S2 are formed of concrete walls.

The lateral region of the lateral region S1 and the upper region S2 formed of the concrete wall may be removed for release of the upper tension member 210.

The block-out part 500 is preferably formed by styrofoam 600 when pouring concrete (C) to form the girder 100.

The styrofoam 600 installed to form the block-out part 500 is removed together when the lateral region S1 is removed to release the upper tension member 210.

It is preferred that the upper flange 310 is coupled with a shear connector 800 projecting upward, and the abdominal 320 with a shear connector 800 coupled along the side.

In the fixing steel type 300, a shear connection material 800 for improving the bonding strength with the floor plate concrete may be formed as shown in FIG.

The bridge structure using the prestressed concrete girder according to an embodiment of the present invention is a segment for producing a central segment part 110, one side segment part 120, and the other side segment part 130 to which the fixing steel type 300 is coupled, respectively. Girder production stage; Girder manufacturing step of coupling the central segment 110, one side segment 120, the other segment 130 to the fastening member 700; A tension force introduction step of introducing a tension force by tensioning the lower tension member 220; 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, styrofoam 500 installed in the block-out unit 310 to introduce a compressive force to the lower surface of the girder 100 among the bridge structure common Block-out unit removing step of removing the; A release step of cutting the protrusion 341 formed in the fixing plate 340 to release the load introduced into the upper tension member 210; It includes; charging the mortar to the block-out unit 310.

The fastening member 700 is installed and tensioned in the girder manufacturing step, as shown in FIG. 6, and is installed at four corners of the cross section of the girder 100.

The fastening member 700 is installed to be commonly penetrated through the central segment part 110, one side segment part 120, and the other side segment part 130, and is tensioned by a single tension device, so that the central segment part 110, one side segment part (120), the other segment 130 is bound.

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.

C: Concrete S1: Lateral area
S2: Upper area 100: Girder
110: central segment 120: one side segment
121: one side segment groove 130: the other segment segment
131: other segment groove 210: upper tension member
220: lower tension member 300: fixing steel type
300a: Daily measurement wear type 300b: Other measurement wear type
310: upper flange 320: abdomen
330: lower flange 340: fixing plate
341: protrusion 300f: front
300b: rear part 400: hollow member
500: block-out unit 510: one block-out unit
520: Other block-out part 600: Styrofoam
700: fastening member 800: shear connection material

Claims (13)

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;
In order to fix the upper tension member 210, the fixing steel type 300 embedded in the upper region in the girder 100;
A lower tension member 220 installed in a lower region of the girder 100;
Including; a hollow member 400 embedded in the inside of the girder 100;
The girder 100 is
Central segment 110;
One-sided segment 120;
It is a segment girder including the other segment (130);
The fixing steel type 300 is a prestressed concrete girder characterized in that it is commonly installed in the central segment 110, one side segment 120, the other segment 130.
According to claim 1,
The fixing steel type 300 is coupled to the upper portion of the central segment portion 110,
The front and rear parts 300f and 300b of the fixing steel type 300 are installed to protrude to the front and rear of the central segment part 110, respectively.
On the upper surfaces of the one side segment portion 120 and the other side segment portion 130, the front side portion 300f and the rear side portion 300b are inserted into one side segment groove portion 121 and the other side segment groove portion 131, respectively. Prestressed concrete girder, characterized in that formed.
According to claim 2,
The front portion 300f and the rear portion 300b of the fixing steel type 300 are
The one side segment groove part 111 and the other side segment groove part 131 is fitted, respectively,
The one side segment groove part 121 and the other side segment groove part 131 are filled with concrete (C) so that the front part 300f and the rear part 300b are the one side segment part 120 and the other segment part Prestressed concrete girder, characterized in that combined with the unit 130.
According to claim 3,
The fixing steel type 300 is
An upper flange 310 on which an upper surface is exposed on the upper surface of the girder 100;
The abdomen 320 formed below the upper flange 310;
A lower flange 330 coupled to the lower surface of the abdomen 320;
Includes; the upper flange 310, the abdomen 320, the fixing plate 340 coupled to the front and rear ends of the lower flange 330, respectively;
Prestressed concrete girder, characterized in that both ends of the upper tension member 210 is fixed to the fixing plate 340 formed on the front and rear of the fixing steel type 300, respectively.
According to claim 4,
On the front surface of the fixing plate 340 formed in front of the fixing steel type 300, a protrusion 341 protruding forward is formed to penetrate the upper tension member 210,
The upper tension member 210 is a prestressed concrete girder, characterized in that settled at the projection 341.
The method of claim 5,
The fixing steel type 300 is
It includes a work measurement wear type (300a) installed in one area of the girder (100) and another measurement wear type (300b) installed in the other area,
The block-out part 500 is formed at least in one of the front or rear of the one-measurement-wearing type 300a and the other measurement-wearing type-type 300b,
The one side surface 513 of the one side block-out portion 510 formed in the one-piece mounting type 300a is formed to extend to one side edge region of the girder 100,
A prestressed concrete girder, characterized in that the other side 524 of the other side block-out portion 520 formed in the rudder-sticking type 300b extends to the other edge region of the girder 100.
The method of claim 6,
The one side block-out portion 510
Upper surface 511;
Lower surface 512;
The one side 513;
The other side 514;
Front 515;
Including the rear 516;
The one side 513 is formed at a position spaced inward from one side of the girder 100,
The upper surface 511 is formed at a position spaced downward from the upper surface of the girder 100,
The lateral region S1 between the one side 513 and one side of the girder 100 and the upper region S2 between the top surface 511 and the top surface of the girder 100 form the girder 100. Prestressed concrete girder, characterized in that filled by the pouring concrete (C) to.
The method of claim 7,
The block-out part 500 is
Prestressed concrete girder, characterized in that formed by styrofoam (600) when pouring the concrete (C) to form the girder (100).
The method of claim 8,
On the upper surface of the upper flange 310, a shear connection material 800 protruding upward is coupled,
Prestressed concrete girder, characterized in that the front end 320 is coupled to the shear connecting material 800 along the side.
A bridge structure using the prestressed concrete girder of claim 9,
A segment girder manufacturing step of manufacturing the central segment part 110, the one side segment part 120, and the other segment part 130 to which the fixing steel type 300 is coupled;
A girder manufacturing step of coupling the central segment part 110, the one side segment part 120, and the other segment part 130 with a fastening member 700;
A tension force introducing step of tensioning the lower tension member 220 to introduce a tension force;
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 bridge structure common,
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 341 formed on the fixing plate 340 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 10,
In the above girder production step
The fastening member 700 is installed on the cross-section edge of the girder 100, and is commonly installed through the central segment 110, the one side segment 120, and the other segment 130. , A bridge structure characterized by being settled after being tensioned with a single tension device.
The method of claim 10,
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 10,
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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