KR20130090462A - Continuous bridge using confined member and construction method thereof - Google Patents

Abstract

The present invention for forming a continuous bridge, a plurality of steel girders 10 installed for each section; A pair of lower anchorages 110 installed at a lower position than the city center so that the lower tension member 210 installed in the longitudinal direction of the continuous bridge is fixed within the area corresponding to one section of the continuous bridge among the plurality of steel girders 10; A plurality of confining concretes 20 each formed on an upper portion of the plurality of steel girders 10 as an area corresponding to one section of the continuous bridge; The both ends are fixed to the plurality of restraint concrete 20, the restraining member 300 is installed to restrain the plurality of restraint concrete 20 inward; by presenting a continuous bridge using a restraining member, comprising: Even when prestressing force is applied to the bridge, it is possible to prevent the generation of harmful stress in the point section.

Description

Continuous bridge using constraining member and its construction method {CONTINUOUS BRIDGE USING CONFINED MEMBER AND CONSTRUCTION METHOD THEREOF}

The present invention relates to civil engineering, and more particularly, to a continuous bridge and a construction method thereof.

In the method of constructing a long bridge with a whole length, a simple bridge method (FIG. 1) in which girders 10 are installed in each section and a continuous bridge system in which a single girder 20 is installed across all sections ( 2 types of FIG. 2) can be mentioned.

When the external force is applied, the former has a positive moment (+) for each girder 10 as a correction structure, whereas the latter generates a positive moment (+) and a parent moment (-) as an indeterminate structure. The design moment is advantageous because the latter is small.

However, when the prestressing force is applied to the tension side (bottom of the girder) for the structural efficiency of the bridge, the parent moment (-) is generated as a whole, and in the case of the inner section between the positive moment (+) section, the upper prestress. The moment due to the force and the external force is canceled, but in the case of the point section that is the parent moment (-), the above prestress force and the moment due to the external force further increase the parent moment (-) to generate a rather harmful stress.

The present invention is derived to solve the above problems, even when applying a prestress force to the continuous bridge, continuous bridge using a restraining member to prevent the generation of harmful stress in the point section and its construction method Its purpose is to present.

In order to solve the above problems, the present invention is a plurality of steel girders (10) installed for each section for the formation of a continuous bridge; A pair of lower anchorages installed in a lower position than the city center in the region corresponding to one section of the continuous bridge among the plurality of steel girders 10 to fix the lower tension member 210 installed in the longitudinal direction of the continuous bridge ( 110); A plurality of confining concretes 20 formed in an upper portion of the plurality of steel girders 10 in an area corresponding to one section of the continuous bridge; Both ends are fixed to the plurality of restraint concrete 20, the restraining member 300 is installed to restrain the plurality of restraint concrete 20 inward; proposes a continuous bridge using a restraining member comprising a. .

The restraining member 300 includes one side strand 310a having one end embedded in the restraining concrete 20a of one side of the plurality of restraining concrete 20; The other side strand 310b having one end embedded in the restraint concrete 20b of the other restraint concrete 20; It is preferable to include a; fixing member 320 for simultaneously fixing the other end of the one side of the strand (310a) and the other end of the other side of the strand (310b).

One end of the one side strand 310a or the other side strand 310b is preferably buried in the restrained concrete 20 in a state where the twist is released.

The fixing member 320 is one side wedge member (321a) coupled to the other end of the one side strand (310a); Another wedge member (321b) coupled to the other end of the other strand (310b); One side insertion hole 322a into which the one side strand 310a and one side wedge member 321a are inserted, and the other side insertion hole 322b into which the other side strand 310b and the other side wedge member 321b are inserted in parallel to each other. It is preferable to include a main body 323 formed.

In one side insertion hole 322a, the one side trimmed portion in which the one side wedge member 321a is mounted, and the other side trimmed portion in which the other wedge member 321b is mounted in the other insertion hole 322b are spaced apart from each other in opposite directions. It is preferably formed in.

It is preferable that the slab concrete 30 is placed on top of the restraint concrete 20 of the plurality of steel girders 10 so that the restraining member 300 is embedded.

The present invention is a method of constructing a continuous bridge using the restraint member, by fixing the lower tension member 210 to the lower anchorage 110 of the plurality of steel girders (10) mounted on the alternating or pier, applying a prestress force A prestressing force applying step; A confining concrete forming step of forming the confining concrete 20 on an upper portion of the plurality of steel girders 10 and installing the confining member 300; A prestress force removing step of removing the prestress force; Slab concrete placing step of placing the slab concrete 30 on top of the constraint concrete 20 of the plurality of steel girders 10 so that the constraint member 300 is embedded; The construction method of the continuous bridge using is presented together.

The present invention is a method of constructing a continuous bridge using the restraint member, by fixing the lower tension member 210 to the lower anchorage 110 of the plurality of steel girders (10) mounted on the alternating or pier, applying a prestress force A prestressing force applying step; The restraint concrete 20 is formed on the upper part of the plurality of steel girders 10, but one end of the one stranded wire 310a is buried in the restraint concrete 20a of one side, and the restraint concrete 20b of the other side. ) Is a confined concrete forming step to bury one end of the other strand (310b); A fixing member 320 fixing step of tensioning the other end of the one side strand 310a to the fixing member 320 and fixing the other end of the other strand 2310b to the fixing member 320; A prestress force removing step of removing the prestress force; Slab concrete placing step of placing the slab concrete 30 on top of the constraint concrete 20 of the plurality of steel girders 10 so that the constraint member 300 is embedded; The construction method of the continuous bridge using is presented together.

The present invention proposes a continuous bridge using a restraint member and a construction method thereof that can prevent generation of harmful stress in a point section even when a prestressing force is applied to the continuous bridge.

1 is a block diagram of a conventional simple bridge.
2 is a block diagram of a conventional continuous bridge.
3 or less shows an embodiment of the present invention,
3, 6, and 7 is a process chart of the construction method of the continuous bridge.
4 is a side view associated with the restraining member.
5 is a cross-sectional view of the restraining member.

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

As shown in Figure 3 below, the continuous bridge according to the present invention is basically, a plurality of steel girders (10) installed for each section to form a continuous bridge; A pair of lower anchorages 110 installed at a lower position than the city center so that the lower tension member 210 installed in the longitudinal direction of the continuous bridge is fixed within the area corresponding to one section of the continuous bridge among the plurality of steel girders 10; A plurality of confining concretes 20 each formed on an upper portion of the plurality of steel girders 10 as an area corresponding to one section of the continuous bridge; Both ends are fixed to the plurality of restraint concrete 20, the restraining member 300 is installed to restrain the plurality of restraint concrete 20 inward; is configured to include.

The continuous bridge can be constructed by the following process.

The lower tension member 210 is fixed to the lower anchorage 110 of the plurality of steel girders 10 mounted on the alternating or pier, and a prestress force is applied (FIG. 3).

Constrained concrete 20 is formed on the upper portion of the plurality of steel girders 10, the restraining member 300 is installed.

In this case, both ends of the restraining member 300 are fixed to the restraining concrete 20a and 20b of both sides, thereby restraining the plurality of restraining concrete 20 inwards (FIG. 4).

The prestress force is removed (FIG. 6).

In order to embed the restraining member 300, the slab concrete 30 is poured on the top of the restraining concrete 20 of the plurality of steel girders 10 (FIG. 7).

As such, when a prestress force is applied to the lower part of the girder 10, the upper part of the girder 10 is restrained by the restraint concrete 20, and then the prestress force is removed again, the upper part of the girder 10 is tensioned. The stress is maintained in a state where the lower part of the girder 10 is maintained in a state where the compressive stress is generated.

Since the stress of the girder 10 is offset from the stress caused by external force, such as a future working load, there is an effect that can increase the structural efficiency.

In addition, since the prestress force is not applied over the entire area of the girder 10, but the prestress force is applied only to the lower area (the area between the respective points) of each girder 10, the parent section (-) is additionally applied to the point section. Does not occur, thereby minimizing the occurrence of harmful stresses.

Furthermore, the restraining member 300 restrains the restraining concretes 20a and 20b on both sides inwardly, which generates a positive moment (+) in the point section, and thus, the parent moment (-) generated in the point section by the external force. To offset, there is an effect that can further increase the structural efficiency.

The restraining member 300 may be any structure that restrains the restraint concretes 20a and 20b inwards, but one end of the plurality of restraint concretes 20 having one end embedded in the restraint concrete 20a. ; The other side strand 310b having one end embedded in the restraint concrete 20b of the other restraint concrete 20; It is preferable to take a configuration including a; fixing member 320 for fixing the other end of the one side of the strand (310a) and the other end of the other side of the strand (310b) at the same time (Figs. 4, 5).

In this case, construction by the following process is possible.

Constrained concrete 20 is formed on the upper portion of the plurality of steel girders 10, one end of one strand of the strand (310a) is buried in the restrained concrete (20a) of one side, the other strands ( One end of 310b) is buried.

The other end of one of the strands 310a is tensioned and fixed to the fixing member 320, and the other end of the other strands 310b is tensioned and fixed to the fixing member 320.

That is, while restraining the constrained concrete (20a, 20b) on both sides, the tension lines (310a, 310b) on both sides to take a method of fixing to the fixing member 320, the positive moment (+) by the application of prestress force Can be more effective.

One end of one of the strands (310a) or the other of the strands (310b) is embedded in the confined concrete 20, when the twist of the end is buried is added, the advantage that can be obtained better adhesion with the concrete.

The fixing member 320 may be any structure as long as it can fix one side strand 310a in a tensioned state, but one side wedge member 321a coupled to the other end of one strand 310a; The other side wedge member 321b coupled to the other end of the other side strand 310b; The main body formed with one side insertion hole 322a into which one side strand 310a and one side wedge member 321a are inserted, and the other side insertion hole 322b into which the other side strand 310b and the other side wedge member 321b are inserted in parallel. In the case of the configuration including the (323); there is an advantage that excellent structural stability can be obtained (Fig. 5).

Here, as the one side wedge member 321a and the other side wedge member 321b, a cone member or the like used for fixing a normal strand can be used.

The main body 323 is to be formed by a solid material capable of withstanding the above prestress force, one side of the wedge member is mounted on one side of the wedge member 321a in one insertion hole (322a), and the other side of the wedge in the other insertion hole (322b) It is preferable in view of structural stability that the other trims on which the member 321b is mounted are formed in opposite directions at a distance from each other (FIG. 5).

Slab concrete 30 is placed on the upper part of the confined concrete 20 of the plurality of steel girder 10, the upper member 300 is advantageous in terms of strength and durability to be embedded in the slab concrete (30). .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

10: steel girder 20,20a, 20b: restrained concrete
30: slab concrete 110: lower anchorage
210: lower tension member 300: restraining member
310a, 310b: stranded wire 320: fixed member
321a, 321b: wedge member 322a, 322b: insertion hole
323 main body

Claims (8)

In order to form a continuous bridge, a plurality of steel girders 10 installed in each section;
A pair of lower anchorages installed in a lower position than the city center in the region corresponding to one section of the continuous bridge among the plurality of steel girders 10 to fix the lower tension member 210 installed in the longitudinal direction of the continuous bridge ( 110);
A plurality of confining concretes 20 formed in an upper portion of the plurality of steel girders 10 in an area corresponding to one section of the continuous bridge;
Both ends are fixed to the plurality of restraint concrete 20, the restraining member 300 installed to restrain the plurality of restraint concrete 20 inward;
Continuous bridge using a restraining member comprising a. The method of claim 1,
The restraining member 300 is
One side of the plurality of strands (310a) of one end embedded in the restrained concrete (20a) of the plurality of restrained concrete (20);
The other side strand 310b having one end embedded in the restraint concrete 20b of the other restraint concrete 20;
A fixing member 320 for simultaneously fixing the other end of the one side strand 310a and the other end of the other side strand 310b;
Continuous bridge using a restraining member comprising a. The method of claim 2,
One end of the one side strand (310a) or the other side of the strand (310b) continuous bridge using a restraining member, characterized in that the buried in the restrained concrete (20). The method of claim 2,
The fixing member 320 is
One side wedge member 321a coupled to the other end of the one side strand 310a;
Another wedge member (321b) coupled to the other end of the other strand (310b);
One side insertion hole 322a into which the one side strand 310a and one side wedge member 321a are inserted, and the other side insertion hole 322b into which the other side strand 310b and the other side wedge member 321b are inserted in parallel to each other. Formed body 323;
Continuous bridge using a restraining member comprising a. 5. The method of claim 4,
In one side insertion hole 322a, the one side trimmed portion in which the one side wedge member 321a is mounted, and the other side trimmed portion in which the other wedge member 321b is mounted in the other insertion hole 322b are spaced apart from each other in opposite directions. Continuous bridge using a restraining member, characterized in that formed in. The method of claim 1,
Slab concrete 30 placed on top of the restraint concrete 20 of the plurality of steel girders 10 so that the restraining member 300 is embedded;
Continuous bridge using a restraining member, characterized in that it further comprises. As a method of constructing a continuous bridge using the restraint member according to any one of claims 1 to 5,
A prestressing force applying step of applying the prestressing force by fixing the lower tension member 210 to the lower fixing unit 110 of the plurality of steel girders 10 mounted on an alternating or pier;
A confining concrete forming step of forming the confining concrete 20 on an upper portion of the plurality of steel girders 10 and installing the confining member 300;
A prestress force removing step of removing the prestress force;
Slab concrete placing step of placing the slab concrete 30 on top of the confining concrete 20 of the plurality of steel girders 10 so that the restraining member 300 is embedded;
Construction method of a continuous bridge using a restraining member comprising a. As a method of constructing a continuous bridge using the restraint member according to any one of claims 2 to 5,
A prestressing force applying step of applying the prestressing force by fixing the lower tension member 210 to the lower fixing unit 110 of the plurality of steel girders 10 mounted on an alternating or pier;
The restraint concrete 20 is formed on the upper part of the plurality of steel girders 10, but one end of the one stranded wire 310a is buried in the restraint concrete 20a of one side, and the restraint concrete 20b of the other side. ) Is a confined concrete forming step to bury one end of the other strand (310b);
A fixing member 320 fixing step of tensioning the other end of the one side strand 310a to the fixing member 320 and fixing the other end of the other strand 2310b to the fixing member 320;
A prestress force removing step of removing the prestress force;
Slab concrete placing step of placing the slab concrete 30 on top of the confining concrete 20 of the plurality of steel girders 10 so that the restraining member 300 is embedded;
Construction method of a continuous bridge using a restraining member comprising a.

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