KR101172442B1 - Construction method for girder using confined concrete - Google Patents

Abstract

PURPOSE: A construction method of a bridge using confined concrete is provided to prevent a steel girder from becoming deformed by confining an upper flange using confined concrete. CONSTITUTION: A construction method of a bridge using confined concrete is as follows. Confined concrete is placed on the tops of steel girders(10). Tensile strength is generated on the top of the steel girders, and compressive strength is generated on the bottoms of the steel girders by applying pre-stress to the steel girders. A form is installed on the top of the confined concrete, and slab concrete(30) is placed thereon. After the slab concrete is cured, the applied pre-stress is removed.

Description

Bridge construction method by confined concrete {CONSTRUCTION METHOD FOR GIRDER USING CONFINED CONCRETE}

The present invention relates to the field of construction, and more particularly, to a construction method of a bridge.

As a bridge construction method, a method of applying prestressing force to steel girders and then placing slab concrete on top of steel girders has been developed.
Here, the prestressing force applied to the steel girder is a very large force, causing harmful deformation including torsion in the steel girder.

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In order to prevent this, the weak part of the steel girder 10 should be reinforced with the reinforcing structure 11 or the thickness of the steel girder should be increased (FIG. 1).

However, this method has a problem that the construction cost very high.

Conventional techniques related to a method for applying prestressing force to steel girders include prestressed reinforced concrete girders and construction methods thereof (Korean Patent Registration No. 10-0926969, 2009.11.17), and methods of manufacturing prestressed concrete girders (Korean patent registration number). 10-0982668, 2010.09.10).

The present invention was derived to solve the above problems, the bridge construction method by restrained concrete to restrain the upper flange of the steel girder with restrained concrete, so that no harmful deformation occurs in the steel girder even when prestressing force is applied To present the purpose is to.

In order to solve the above problems, the present invention is confined concrete forming step of forming a confined concrete 20 on top of the steel girder 10; Prestressing force is applied to the steel girder 10 on which the confined concrete 20 is formed, thereby generating tensile stress in the upper portion of the steel girder 10 and generating compressive stress in the lower portion of the steel girder 10. Prestressing force applying step; Slab concrete placing step of installing the formwork on top of the confined concrete 20 and the slab concrete 30; It proposes a bridge construction method by restrained concrete, including; prestressing force removing step of removing the prestressing force after curing of the slab concrete (30).

Before the confining concrete forming step, a pre-stress force is applied to the steel girder 10 to generate a tensile stress on the upper portion of the steel girder 10 and generate a compressive stress on the lower portion of the steel girder 10. It is preferable to further include a; pre-stress force applying step.

The prestress force is preferably such that the stress generated by the working load acting on the steel girder 10 and the stress generated by the prestress force are substantially equal.

Preferably, the prestress force is greater than the preceding prestress force.

In the confining concrete forming step, it is preferable to use cast-in-place concrete or precast concrete as the confining concrete 20.

In the confining concrete forming step, it is preferable to form the confining concrete 20 so that the upper flange of the steel girder 10 is embedded in the confining concrete 20.

In the slab concrete pouring step, it is preferable to pour the slab concrete 30 so that the confined concrete 20 is embedded in the slab concrete 30.

The prestressing force applying step may include installing a pair of tension member fixing holes 110 at intervals in a longitudinal direction at a lower portion of the steel girder 10; And tensioning the tension member 100 to fix both ends to the pair of tension member anchorages 110.

The prestressing force applying step may include installing a tension member support 111 inside the pair of tension member anchorages 110; Tensioning the tension member 100 to fix both ends to the pair of tension member anchorages 110, such that a central portion of the tension member 100 is supported by the tension member support 111 to be bent and disposed; It is preferable.

After the prestressing force removing step, the auxiliary structure installation step of installing the auxiliary structure on the bridge on which the steel girder 10 is installed; preferably further comprises a.

The present invention proposes a bridge construction method using restrained concrete to restrain the upper flange of the steel girder with restrained concrete so that no harmful deformation occurs in the steel girder even when a prestress force is applied.

Figure 1 below shows an embodiment of the manufacturing method according to the present invention,
1 is a cross-sectional view of a conventional steel girders.
Figure 2 is a side view of the confined concrete forming step.
3 is a side view of the first embodiment of the prestress applying step;
Figure 4 is a side view of the slab concrete pouring step.
5 is a side view of the second embodiment of the prestress application step;
6 is a side view of a steel girder acting on the working load.
7 is a side view of a state in which a bridge is installed by restraint concrete;
8 is a sectional view of a steel girder on which slab concrete is poured.
9 is a cross-sectional view of the steel box girder in which slab concrete is poured.
Figure 10 is a side view of one embodiment of the tension member installation process.

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

As shown in Figure 2 below, the bridge construction method using the confined concrete according to the present invention relates to a pre-stressing (Pre-Stressing) method, it is configured by the following process.

First, the restraint concrete 20 is formed on the upper part of the steel girder 10 (FIG. 2).

Conventionally, when prestressing force is applied to the steel girders 10, other harmful deformations including torsions are caused to the steel girders 10.

In order to prevent this, it was necessary to install the reinforcing structure 11 made of steel or to increase the thickness of the steel girder 10 in the weak part of the steel girder 10 (Fig. 1).

However, in this process, the restraint concrete 20 restrains the upper flange of the steel girder 10 to prevent deformation of the steel girder 10.

Therefore, the above-mentioned preventive measures are unnecessary, so that the economic cost can be reduced and structural stability can be enhanced.

Next, a prestress force is applied to the steel girder 10 on which the restraint concrete 20 is formed (FIG. 3).

Due to the prestressing force, tensile stress is generated in the upper portion of the steel girder 10, and compressive stress is generated in the lower portion of the steel girder 10.

In this state, the formwork 1 is installed on the upper part of the confined concrete 20 and the slab concrete 30 is poured (FIG. 4).

At this time, the prestressing force is kept as it is.

In the case of going through such a process, since the first formed restraint concrete 20 restrains the poured slab concrete 30, the following two effects may be obtained.

First, the restraint force of the restraint concrete 20 prevents the initial deformation of the slab concrete 30, thereby improving structural stability.

In addition, since it is possible to cast by reducing the weight of the slab, it is possible to reduce the construction cost by reducing the copper bar and other temporary facilities.

The prestress force is removed after curing of the slab concrete 30.

If the prestress force is removed before curing of the slab concrete 30, harmful deformation occurs due to excessive compressive force due to elastic recovery of the steel girder 10.

In order to prevent this, by removing the prestress force after curing of the slab concrete 30, it is possible to increase the structural durability and stability.

Bridge construction method by the confined concrete according to the present invention can also be configured by the following process.

Prior to the confining concrete forming step, a preceding prestressing force is applied to the steel girders 10 to generate tensile stresses on the upper portions of the steel girders 10 and to generate compressive stresses on the lower portions of the steel girders 10 (FIG. 5).

In this state, the restraint concrete 20 is formed on the upper portion of the steel girder 10, and then the prestressing force is applied once more. Subsequent steps proceed through the above-described steps.

As described above, the first prestressing force is first applied to the upper part of the steel girder 10 a total of two times, and then the prestressing force is additionally applied as follows.

Since the upper portion of the steel girder 10 is in the tensile stress state by the pre-stress force, the deformation of the steel girder 10 by maintaining the tensile stress state, not compressive stress, even if the self-weight is generated by forming the confined concrete 20 Can be prevented.

The prestressing force is applied such that the stress generated by the working load acting on the steel girders 10 and the stress generated by the prestressing force are substantially the same (FIG. 6).

In this case, the working load is defined as a concept including an active load and a dead load acting on the steel girders 10.

When the working load is loaded on the upper part of the steel girder 10, the upper part of the steel girder acts simultaneously with the compressive stress and the above-mentioned tensile stress due to the working load, so that the virtually stress-free state can be approached. The effect is to increase stability.

In the case of applying the preceding prestress force and the prestress force, it is preferable to apply the prestress force larger than the preceding prestress force.

The reason for this is that when the restrained concrete 20 is poured in the state where the preliminary prestressing force is initially applied, harmful deformation may occur in the steel girder 10.

Therefore, it is preferable in terms of structural stability to apply a relatively small amount of preceding prestress force and to gradually apply a large amount of prestress force.

Constrained concrete 20 may use cast-in-place concrete or precast concrete.

This process can use precast concrete because the steel girders 10 can be installed as it is installed in the shift (1) or pier (2) (Fig. 7).

Constrained concrete 20 is preferably formed so that the upper flange of the steel girder 10 is embedded in the confined concrete (20).

The reason is that the upper flange of the steel girder 10 is completely embedded and restrained in the confined concrete 20, so that the role of the reinforcing material which prevents deformation of the steel girder 10 when the prestressing force is applied can be made more certain. Because there is.

Therefore, it is more effective in terms of structural stability.

In the slab concrete 30, it is preferable to pour the slab concrete 30 so that the confining concrete 20 is embedded in the slab concrete 30 (FIG. 8).

The advantage of this structure is that the restrained concrete 20 is completely embedded in the slab concrete 30, thereby restraining the initial deformation of the slab concrete 30 can be more surely prevent structural stability.

In addition, since the weight of the embedded slab concrete 30 can be reduced by the weight of the embedded confined concrete 20, the construction cost can be further reduced.

That is, the present invention, the bridge construction method by the confined concrete 20 can be similarly applied to the steel box girder 13 as well as the steel girder 10.

When the steel box girders 13 are used, there is an advantage that the vibration and deflection performance is improved because the rigidity and vibration performance can be increased (FIG. 9).

The prestressing force applying step and the preceding prestressing force applying step may be implemented by various methods, but the steps of installing a pair of tension fixing unit 110 at intervals in the longitudinal direction at the bottom of the steel girder 10; Tensioning the tension member 100 to fix both ends to the pair of tension member anchorage 110; the configuration including the preferred in terms of efficiency and structural stability of the operation.

The tension member support 111 is installed inside the pair of tension member anchorages 110, and the tension member 100 is tensioned to fix both ends in the pair of tension member anchorages 110, but the central portion of the tension member 100 is tension member support. The configuration for supporting and bending the support 111 is added to the advantage that the prestressing force can be loaded more structurally and stably (Fig. 10).

After the prestressing force removing step, it is preferable to install the auxiliary structure on the bridge on which the steel girders 10 are installed.

As ancillary structures, railings, walkways and boundary stones can be used.

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.

1: shift 20: restraint concrete
2: pier 30: slab concrete
3: stud 100: tension material
10: steel girder 110: tension member anchorage
11: reinforcing structure 111: tension member support
13: steel box girder

Claims (10)

Constrained concrete forming step of forming the confined concrete 20 on top of the steel girder 10;
Prestressing force is applied to the steel girder 10 on which the confined concrete 20 is formed, thereby generating tensile stress in the upper portion of the steel girder 10 and generating compressive stress in the lower portion of the steel girder 10. Prestressing force applying step;
Slab concrete placing step of installing the formwork on top of the confined concrete 20 and the slab concrete 30;
A prestressing force removing step of removing the prestressing force after curing the slab concrete 30;
Bridge construction method by restrained concrete, characterized in that it comprises a. The method of claim 1,
Before the confined concrete forming step,
Applying a preliminary prestress force to the steel girder (10) to generate a tensile stress in the upper portion of the steel girder (10) and a compressive stress in the lower portion of the steel girder (10); To
Bridge construction method according to the confined concrete further comprising. 3. The method according to claim 1 or 2,
The prestressing force is a bridge construction method by restrained concrete, characterized in that the stress generated by the use load to act on the steel girders (10) and the stress generated by the prestressing force is substantially the same. The method of claim 2,
The prestressing force is a bridge construction method according to the concrete, characterized in that greater than the preceding prestressing force. 3. The method according to claim 1 or 2,
The confining concrete forming step
Bridge construction method according to the confined concrete, characterized in that the use of cast concrete or precast concrete as the confined concrete (20). 3. The method according to claim 1 or 2,
The confining concrete forming step
Bridge construction method according to the confined concrete, characterized in that to form the confined concrete 20 so that the upper flange of the steel girders (10) in the confined concrete (20). 3. The method according to claim 1 or 2,
The slab concrete pouring step
Bridge construction method according to the constraint concrete, characterized in that the slab concrete 30 is poured so that the confined concrete 20 is embedded in the slab concrete (30). 3. The method according to claim 1 or 2,
The prestressing force applying step
Installing a pair of tension member anchorages (110) at intervals in the longitudinal direction at the bottom of the steel girder (10);
Tensioning the tension member 100 to fix both ends of the pair of tension member anchorages 110;
Bridge construction method by restrained concrete, characterized in that it comprises a. The method of claim 8,
The prestressing force applying step
Installing a tension member support 111 in the inner side of the pair of tension member anchorage (110);
Tensioning the tension member 100 to fix both ends to the pair of tension member anchorages 110, such that a central portion of the tension member 100 is supported by the tension member support 111 to be bent;
Bridge construction method by restrained concrete, characterized in that it comprises a. 3. The method according to claim 1 or 2,
After the prestressing force removing step, the auxiliary structure installation step of installing the auxiliary structure on the bridge on which the steel girder 10 is installed;
Bridge construction method according to the confined concrete further comprising.

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