KR101529170B1 - Method for loading Pre-flex load and pre-loading prestress - Google Patents

Abstract

The present invention relates to a preflex load method and a pre-tensioning method. More particularly, the present invention relates to a preflex loading method for a preflex composite composite girder, in which a load-bearing device for applying a preflex load to a steel material is not required, The present invention relates to a pre-press load method and a pre-tension method of pre-pressurizing a pre-press load capable of applying a pre-flex load in a required amount.
The present invention relates to a preflex steel composite girder or a steel composite beam composed of a steel material and a concrete, and a method of loading a preflex load in the steel composite beam. In this method, a first connecting member, A first connecting step of connecting the first connecting part and the second connecting part so that the moment and the shearing force can be transmitted; A mounting step of mounting the main body and both ends of the first connecting member on the supporting member in the connecting step; A concrete construction step of placing / curing concrete in a lower flange of the main body in a state where the main body and the first connection member are mounted on the support member; And a separating step of separating the first connecting member and the main body from each other after the concrete pouring / curing step; Wherein the preflex loading method is a preflex loading method.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pre-flex load and pre-

The present invention relates to a preflex load method and a pre-tensioning method. More particularly, the present invention relates to a preflex loading method for a preflex composite composite girder, in which a load-bearing device for applying a preflex load to a steel material is not required, The present invention relates to a pre-press load method and a pre-tension method of pre-pressurizing a pre-press load capable of applying a required amount of pre-

The preflex steel composite girder has a preflex load applied to the I-shaped cross-section steel which has been pre-heated in a direction opposite to its own weight, and the concrete is placed in the lower flange of the steel and cured. And to introduce the prestress into the concrete.

Fig. 1 is a view schematically showing a method of manufacturing a general preflex steel composite girder. Fig. 1 (a) shows a state in which the I-shaped steel material 10 which has been subjected to the upward upward treatment is placed on the support base 1. Fig. The configuration labeled 10H in (a) is the upper flange and the configuration labeled 10L is the lower flange. 1 (a), the preloading load Pf is loaded in the direction of the main load. When the preloading load Pf is loaded and the steel material 10 is deformed, as shown in FIG. 1 (b) Respectively. As shown in FIG. 1 (b), the concrete is poured / cured on the side of the lower flange 10L of the steel material 10 in a state in which the prying load Pf is loaded. (c). In this state, when the prestrained load Pf is removed, the prestress is introduced into the concrete as shown in FIG. 1 (d).

The most difficult process in the construction process of the preflex steel composite girder mentioned above is a process of applying a preflex load. First, since the pre-flex load is a very large load, a heavy equipment is basically required to apply it. Therefore, it is very expensive. Furthermore, in the process of loading the preflex load, the support does not properly support the load, so that the preflex load can not be preloaded due to the change of the load point of the preflex load. In addition, when the preflex load is applied, Or buckling may occur.

The pre-tension method and the post-tension method are the methods of applying the prestress. In the pre-tension method, when the concrete girder or beam to be applied with the prestress is manufactured, And the post-tension method is a method of embedding a sheath tube in advance when a girder or a beam is manufactured, inserting a stranded wire into the buried sheath tube, and then applying a tensile force to the sheath tube and fixing it. The pre-tension method has many advantages compared with the post-tension method, but is not widely used due to the necessity of a reaction force of a large scale to apply pretension.

SUMMARY OF THE INVENTION The present invention has been made to overcome the problems of the conventional preflex loadings, and it is an object of the present invention to provide a preflex load distribution apparatus and a preflex load distribution apparatus, A pre-flex load method and a pre-tension method in which a prestress method using a tension method can be applied.

As a means for solving the above-mentioned problems,

The present invention relates to a method of loading a preflex load on a composite girder or composite beam of preflex steel consisting of steel and concrete,

A connecting step of connecting a first connecting member and a second member, which are steel members, to both ends of the main body, which is long in one direction, so as to transmit a bending moment and a shearing force;

A mounting step of mounting both ends of the first connecting member and the second connecting member connected to each other on the supporting member in the connecting step;

A strand fixing step of fixing the stranded wire in a state that the stranded wire is tensioned to the stranded wire fixing device in a state where the first connecting member and the second connecting member are provided with a stranded wire fixing device;

A concrete block forming step of placing a tensile steel strand in a lower portion of the main body and casting and curing the reinforcing concrete to form a concrete block;

A strand cutting step of removing the tensile force applied to the strand after the concrete block forming step is completed, and then cutting the strand exposed to the outside of the concrete block;

A separating step of separating the main body from the first connecting member and the second connecting member after the strand cutting step; The preflex loading method of the preflex load and pretiltion method is provided.

Prior to the separation step,

It is preferable that a load in the same direction as the self weight direction of the concrete block is loaded on the first connecting member or the second connecting member.

It is more preferable that the main body and the first connecting member and the second connecting member are all steel members having the same cross section.

According to the present invention, the pre-flex load and the pre-tension type pre-stress are applied, and the pre-flex load is applied without using the equipment for loading the additional load, and the pre- The present invention can provide a pre-flex load method and a pre-tension method of a prestressing method which can reduce the manpower required for equipment use and reduce the risk of safety accidents that may occur during the use of the equipment.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view for explaining a general process for producing a preflex steel composite girder or a beam. Fig.
FIGS. 2A to 2E are views for explaining a preflex loading method according to an embodiment of the present invention; FIGS.
Figs. 3A to 3D are diagrams showing load states in several states shown in Fig. 2. Fig.

Hereinafter, a pre-press load method and a pre-tension method according to a preferred embodiment of the present invention will be described with reference to the drawings.

FIGS. 2A to 2E are views for explaining a preflex loading method according to an embodiment of the present invention, and FIGS. 3A to 3D are diagrams showing load states of several states shown in FIG.

The pre-flex load method and pre-tension method according to this embodiment are a method for loading a pre-flex load in the process of manufacturing a pre-flex steel composite girder or a steel composite beam composed of a steel material and concrete, A step of fixing the strand, a step of forming the concrete block, a step of cutting the strand of strand, and a separation step.

The connecting step is a step of connecting the first connecting member 110 and the second connecting member 120, which are steel, to both ends of the main body 100, which is a steel material (I-type beam) long in one direction. At this time, the main body 100, the first linking member 110, and the second linking member 120 are strong enough to transmit a bending moment and a shear force.

The first connection member 110 and the second connection member 120 are formed to have the same cross-section as the main body 100, thereby facilitating connection.

The connection between the first connection member 110 and the second connection member 120 and the main body 100 is made by the connection member 101. The connection member 101 may be composed of a steel plate and a bolt / Here, the method of detachably connecting the steel material can be easily understood by a person having an average degree of knowledge in the technical field of the present invention, and thus a detailed description thereof will be omitted.

After the first and second connection steps have been completed, the mounting step may be performed such that both ends of the main body 100, the first connecting member 110, and the second connecting member 120 are coupled to each other through the support 200 ). Thus, one end of the first connecting member 110 and one end of the second connecting member 120 are respectively mounted on the support 200.

A state in which the connecting step is completed and both ends thereof are stationary is shown in Fig.

2B, a fixing device 140 is installed on the first connection member 110 and the second connection member 120, and a tensile force is applied to the strand 150 in the fixing device 140. In this case, In the state of being applied. The arrows shown in the drawing indicate the direction (tensile direction) of the force applied to the stranded wire 150.

The concrete block forming step is a step of placing / curing the concrete block 130 on the lower flange of the main body 100 in a state where the mounting step is completed. At this time, the concrete block 130 is manufactured in a state in which the strand 150, which is fixed in a state where a tensile force is applied in the strand fixing step, is accommodated therein. The state in which the concrete block forming step is completed is shown in FIG.

In the strand cutting step, after the concrete block forming step is completed, the tensile force of the strand subjected to the tensile force is removed, and the strand exposed to the outside of the concrete block 130 is cut. When the strand is cut, a pre-tension is applied to the concrete block 130 in which the strand 150 with the tensile force is accommodated.
The state in which the strand cutting step is completed is shown in Fig.

The separating step separates the first connecting member 110 and the second connecting member 120 from the main body 100 after completion of the concrete construction step. FIG. 2E shows a state in which the first connecting member 110 and the second connecting member 120 are separated from the main body 100 and are mounted on the supporting table 200.

When the length of the main body 100 is L and the lengths of the first connecting member 110 and the second connecting member 120 are 1/4 L, the concrete block 130 is pre- And a pre-flex load is applied to the main body 100. [0050] FIG.

First, when the fixing device 140 is fixed with the tensile force P applied to the strand 150 in the state shown in FIG. 3A, a bending moment is applied to the main body 100. When the distance between the center of gravity of the main body 100 and the strand 150 is e, the magnitude of the bending moment is Pe. The distance between the center of gravity of the first connecting member 110 and the strand 150 and the distance between the center of gravity of the main body 100 and the first connecting member 110 and the second connecting member 120, Since the distance from the center of gravity to the strand 150 is the same, the distance between the first connecting member 110 and the strand 150 is represented by e in the figure)

3B shows a load state in which the concrete block 130 is installed in a state where the first connecting member 110 and the second connecting member 120 are tightly coupled to the main body 100. [ In the drawing, w is a value obtained by simplifying the distribution load of the concrete block 130.

The moment diagram of the load state shown in Figure 3b is shown in Figure 3c.

And the magnitude of the moment acting on the main body 100 and the magnitude of the load after the separation step is completed are shown in Fig.

As described above, according to the present invention, since the concrete is installed in a state where the two connecting members 110 and 120 are connected to each other, the preflex load can be loaded only by the weight of the concrete. The size of the preflex load to be loaded can be controlled by the lengths of the first connection member 110 and the second connection member 120. The longer the length of the first connection member 110 and the second connection member 120 A larger pre-flex load can be loaded.

In addition, since a pre-tension type pre-stress can be applied to the concrete block 130, a separate reaction force necessary for applying a prestress is not required, so that it is very cost effective and an effect of applying a prestress by a simple method can be expected.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It can be embodied by various types of preflex load method and pre-tension method of pre-tension method.

100: main body 110: first connecting member
120: second connecting member 130: concrete block
140: Fixing device 150: Strand
200: Support

Claims (3)

The present invention relates to a method of loading a preflex load on a composite girder or composite beam of preflex steel consisting of steel and concrete,
A connecting step of connecting a first connecting member and a second member, which are steel members, to both ends of the main body, which is long in one direction, so as to transmit a bending moment and a shearing force;
A mounting step of mounting both ends of the first connecting member and the second connecting member connected to each other on the supporting member in the connecting step;
A strand fixing step of fixing the stranded wire in a state that the stranded wire is tensioned to the stranded wire fixing device in a state where the first connecting member and the second connecting member are provided with a stranded wire fixing device;
A concrete block forming step of placing a tensile steel strand in a lower portion of the main body and casting and curing the reinforcing concrete to form a concrete block;
A strand cutting step of removing the tensile force applied to the strand after the concrete block forming step is completed, and then cutting the strand exposed to the outside of the concrete block;
A separating step of separating the main body from the first connecting member and the second connecting member after the strand cutting step; Wherein the preflex loading method is a preflex loading method.

delete The method according to claim 1,
Wherein the main body, the first linking member, and the second linking member are all made of a steel material having the same cross-section, and the pre-press load and the pre-tensioning method.

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