KR101325231B1 - Manufacturing method for pre-flex girder using prestressing - Google Patents

Abstract

The present invention relates to a girder mounting step of mounting a girder (10) on a cradle; A permanent load applying step of applying a permanent load (PS) to the girder (10) to generate tensile stress in the upper part of the girder (10) and generating compressive stress in the lower part of the girder (10); A prestressing load step of applying a prestressing load PF to the girder 10 to generate compressive stress in the upper part of the girder 10 and generating tensile stress in the lower part of the girder 10; Placing a concrete (12) on a lower portion of the girder (10); And a preflexion load removing step of removing the prestressing load (PF). The present invention provides a method of manufacturing a preflex girder using a permanent load, characterized in that the lower portion of the girder under substantially unstressed condition So that the structural stability can be enhanced.

Description

TECHNICAL FIELD [0001] The present invention relates to a method of manufacturing a preflex girder using a permanent load,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a construction field, and more particularly, to a method of manufacturing a girder.

1 to 4 are process drawings for explaining a conventional method of manufacturing a pre-flex girder.

The prestressing load P is loaded on the basis of the constant load point a and the compressive stress P is applied to the upper portion of the girder 10 by placing the steel girder 10 on the cradle (Compression side), so that tensile stress is generated in the lower portion of the girder 10 (tension side) (Fig. 2).

In this state, the concrete 12 is laid on the tension side of the girder 10 (Fig. 3), and the prestrain load P is removed (Fig. 4).

When the prilling load P is removed, compressive stress is generated in the concrete laid on the tensile side due to elastic recovery of the girder 10, which resists the working load in this stressed state (Fig. 5).

However, such a conventional manufacturing method has the following problems.

Basically, tensile stress is generated at the lower portion of the girder 10 by the loading of the flexural load (P). Even after completion of the process of removing the concrete and the prestressing load, compressive stress is generated in the concrete The tensile stress remains in the lower part of the girder (residual tensile stress).

This is because the lower part of the girder is to be returned to the original stressed state (unstressed state) by the elastic recovery after the removal of the preloading load, but the prestressed load (P) is put in the loaded state (the lower part of the girder is tensioned) Because it is constrained by hardened concrete.

In the case where the tensile stress remains on the lower part of the girder and the working load is applied to the upper part of the girder, the tensile stress due to the working load and the above-mentioned residual tensile stress simultaneously act on the lower part of the girder, Which has been pointed out as a cause of structural stability.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method of manufacturing a preflex girder using a permanent load to increase the structural stability by allowing the lower portion of the girder to be in a substantially non- And the like.

In order to solve the above-described problems, the present invention provides a girder fixing method for mounting a girder (10) on a girder; A permanent load applying step of applying a permanent load (PS) to the girder (10) to generate tensile stress in the upper part of the girder (10) and generating compressive stress in the lower part of the girder (10); A prestressing load step of applying a prestressing load PF to the girder 10 to generate compressive stress in the upper part of the girder 10 and generating tensile stress in the lower part of the girder 10; Placing a concrete (12) on a lower portion of the girder (10); And removing the prestressing load (PF) from the prestressing load (PF).

The permanent load applying step may include a step of installing a pair of tension member fixing holes 120 in the lower part of the girder 10 in the longitudinal direction at intervals, And tightening the tension member 110 to fix both ends to the pair of tension member fixing holes 120. [

The permanent load applying step may include the steps of installing a tension member support 121 inside the pair of tension member fixing holes 120; And tensioning the tension member 110 and fixing both ends of the tension member 110 to the pair of tension member fixing holes 120 so that the central portion of the stress member 110 is supported by the tension member support 121 and is bent desirable.

The girder mounting step includes the step of mounting the girder 10 to the cradle 20 so that the pre-flexion load (PF) is loaded to a plurality of loading points (a) in the central portion of the girder 10, The permanent load loading step preferably includes the step of installing the pair of tension member anchoring member 120 on the outside of the plurality of loading points (a), respectively.

The concrete pouring step may be performed such that the pair of the tension members 120 and the tensile member 110 are embedded in the concrete 12.

After the permanent load-carrying step, it is preferable to perform the pre-charging load-carrying step.

And a secondary permanent load applying step of applying a secondary permanent load (PS2) to the concrete (12) after the prefiring load removing step.

Preferably, the second permanent load applying step includes a step of tensioning the secondary tensile member 130 by the post tension method and fixing the secondary tension member 130 to the concrete 12.

The present invention proposes a method of manufacturing a preflex girder using a permanent load which enables the lower part of the girder to be in a substantially non-stressed state in the loaded state of the used load, thereby enhancing the structural stability.

1 to 5 are process drawings of a conventional manufacturing method.
6 shows an embodiment of the manufacturing method according to the present invention,
6 to 13 are process drawings of the first embodiment.
14 is a process chart of the second embodiment.
15 and 16 are process drawings of the third embodiment.

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

As shown in Fig. 6 and subsequent drawings, the method of manufacturing a preflex girder according to the present invention comprises the following steps.

The girder 10 is mounted on a cradle (not shown), and a permanent load PS is loaded on the girder 10 to generate tensile stress in the upper portion of the girder 10 and to compress the lower portion of the girder 10. Generate stress (FIGS. 6-9).

This is to create a stress state opposite to the stress condition occurring in the girder by the loading of the prestressing load (PF).

A prestressing load PF is applied to the girder 10 to generate compressive stress in the upper portion of the girder 10 and tensile stress is generated in the lower portion of the girder 10.

In the state where the preflection load PF is loaded, the concrete 12 is poured on the lower part of the girder 10 (FIG. 11), and the preflection load PF is removed (FIG. 12).

In other words, a permanent load (PS) is previously loaded on the girder (10) in addition to the load of the prestrain load (PF), and a stress state opposite to the stress state due to the prestressing load (PF The tensile stress state, and the lower portion of the girder are in the compressive stress state), and again the pre-reflection load PF is applied as in the conventional case.

In this state, the concrete 12 is placed on the lower portion of the girder 10, and the prestrain load PF is removed, but the permanent load PS is maintained as it is.

Through this process, the lower part of the girder is first subjected to a compressive stress state by the permanent load (PS) (Fig. 7), and then to a tensile stress state by the pre-flexion load (PF) (Fig. 10), And back to the compressive stress state by removal of the preflection load PF (FIG. 12).

In this state, when the working load is applied to the upper part of the girder, the tensile stress due to the working load and the above-mentioned compressive stress simultaneously act on the lower part of the girder, so that the structural stability of the girder can be increased .

In other words, in the related art, since the lower portion of the girder is in the tensile stress state after the completion of the manufacturing work of the preflex girder, the lower portion of the girder is in a compressive stress state after the completion of the manufacturing work according to the present invention, You can do it.

The permanent loading operation may be implemented by various methods, but it is also possible to install a pair of tension member fixing openings 120 (FIG. 6) spaced longitudinally at the bottom of the girder 10; And a step of tightening the tension member 110 and fixing both ends of the tension member 110 to the pair of tension member fixing holes 120 (Fig. 7), is preferable in terms of efficiency of operation and structural stability.

A separate tension member support 121 is installed inside the pair of tension member fixing holes 120 and the tension member 110 is tightened to fix both ends of the tension member 110 to the pair of tension member fixing holes 120, When the construction is such that it is supported by the tension member support 121 and is bent and arranged, there is added an advantage that the permanent load can be more stably and firmly loaded (Fig. 14).

The girder 10 is mounted on a cradle such that the prestrain load PF is loaded on a plurality of cradles a of the center portion. (Fig. 10). [0052] As shown in Fig.

Further, it is preferable for the structural stability that the pair of fixing member fixing ports 120 are provided at both ends of the girder 10 as much as possible in a line that does not hinder the loading operation of the pulling load PF.

Since the structure for loading a permanent load such as a pair of the tensioning material fixing port 120 and the tensioning material 110 together with the lifetime of the girder is embedded in the concrete 12 placed at the lower part of the girder, .

The permanent loading operation and the preloading loading operation can be carried out at any time, but it is not necessary to carry out the preloading loading step with the permanent load placed on the girder, .

If more permanent load is to be applied to the girder 10, after the removal of the preflection load, the secondary permanent load PS2 may be loaded on the concrete 12 (FIG. 15).

In this way, it is preferable to divide the girder 10 by two steps of the step of applying the permanent load (prestressing) in terms of reducing the harmful stress that may occur in the girder 10 due to the load of the permanent load .

The second tension member 130 may be tensed and fixed to both ends of the concrete 12 by a post-tensioning method in which a secondary permanent load is applied (FIG. 16).

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: girder 12: concrete
110: Tension material 120: Tension material fastener
121: Tension support PS: Permanent load
PF: Deflection load

Claims (8)

In the method of manufacturing the preflex girder,
A girder mounting step of mounting the girder (10) on the mount;
A prestressing load step of applying a prestressing load PF to the girder 10 to generate compressive stress in the upper part of the girder 10 and generating tensile stress in the lower part of the girder 10;
Placing a concrete (12) on a lower portion of the girder (10); And
Including; a preflection load removing step of removing the preflection load (PF),
In order to ensure that the stress applied to the lower part of the girder 10 after the preflection load removing step is in the compressive stress state, the permanent load PS is loaded on the girder 10 before the preflection load loading step. By doing so, the upper part of the girder 10 generates a tensile stress, the lower part of the girder 10 generates a permanent load for generating a compressive stress;
Method for producing a preflex girder, characterized in that it further comprises.
The method of claim 1,
The permanent loading step
Installing a pair of tension member fastening openings (120) in the lower part of the girder (10) at intervals in the longitudinal direction;
Tightening the tension member 110 and fixing both ends to the pair of tension member fixing holes 120;
Wherein the pre-flex girder is made of a material selected from the group consisting of polypropylene and polypropylene. 3. The method of claim 2,
The permanent loading step
Installing a tension member support (121) inside the pair of tension member fixing holes (120);
Tightening the tension member 110 and fixing both ends of the tension member 110 to the pair of tension member fixing holes 120 so that the central portion of the tension member 110 is supported and bent by the tension member support 121;
Wherein the pre-flex girder is made of a material selected from the group consisting of polypropylene and polypropylene. 3. The method of claim 2,
The girder mounting step
And mounting the girder 10 on the holder 20 such that the pre-flexion load PF is loaded at a plurality of loading points a of the central portion of the girder 10.
The permanent loading step
And installing the pair of tension member fixing holes 120 on the outer side of the plurality of load points a respectively. 5. The method according to any one of claims 2 to 4,
The concrete pouring step
Wherein the pair of tension member fixing holes 120 and the tension member 110 are embedded in the concrete 12. delete The method of claim 1,
Further comprising a second permanent load applying step of applying a second secondary permanent load (PS2) to the concrete (12) after the preliminarily removing load removing step Gt; The method of claim 7, wherein
The second permanent load applying step
And tensioning the second tension member (130) by the post tension method to fix the second tension member (130) to the concrete (12).

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