KR101465352B1 - Prestressed Concrete having Self-eccentricity - Google Patents

Abstract

The present invention relates to a prestressed concrete member which has its own eccentric shaft. The prestressed concrete member includes: a concrete placement unit (101) which has a convex center part instead of a linear center line (102); and a linear steel wire (103) which is embedded in the concrete. A prestressed moment is generated by the eccentricity (104) between the center line and the steel wire in the concrete placement unit to effectively reduce the moment due to the working load. Also, the cross-section of prestressed concrete member is reduced to reduce the work load in the field.

Description

[0001] PRESTRESSED CONCRETE having Self-eccentricity [0002]

The present invention relates to a prestressed concrete member having self-eccentricity, and more particularly, to an eccentricity between a center line of a concrete pouring portion capable of introducing a prestressing effect itself and a steel line stretched in a straight line, To a prestressed concrete member having its own eccentricity.

Beams and slabs in the structure are bending moments (Fig. 1) in the members when the service load is supported by the horizontal members. A technique of introducing a prestress into a member is used in the most effective way to resist this bending moment. The pre-tension method and the post-tension method are referred to as pre-tension and post-tension, respectively.

In a typical pre-stressed concrete member, the arrangement of the steel wire becomes similar to the bending moment (Fig. 1) due to the applied load. Fig. 2 shows the arrangement of the steel wire of the existing pre-tensioned concrete member. The eccentricity 14 is generated between the center 12 of the concrete poured portion 11 and the steel wire 13 which is bent to be stretched so that a moment effect due to the prestress is utilized. Due to the nature of the pretension, the steel wire can only be arranged in a straight line and a hold down device (15) is used, which is very expensive material and must withstand a large load, have. A pre-tension bed 16 also requires a foundation for securing the hold-down device 15.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the above-described problems of the prior art and to provide a method of manufacturing a prestressed prestressed prestressed prestressed prestressed prestressed prestressed prestressed prestressed concrete structure, The present invention provides a pre-tensioned concrete member having its own eccentricity.

As an example of a prestressed concrete member having self-eccentricity according to the present invention, a concrete pouring portion having a convex upward portion at the center of the upper surface and a straight line at the lower surface, And an eccentricity is formed between the center line of the concrete poured portion and the steel wire.

The lower surface of the concrete poured portion has a straight shape, and the upper surface may be a curved shape, a straight slope-a horizontal plane-a straight slope shape, or a symmetric stair shape.

As another example of the prestressed concrete member having self-eccentricity according to the present invention, there is a concrete pouring portion having a top surface of a straight line and a central portion of a lower surface convex upward, And an eccentricity is formed between the center line of the concrete poured portion and the steel wire.

The upper surface of the concrete poured portion may be straight, and the lower surface may be curved or straight slope-horizontal-straight slope.

As another example of the prestressed concrete member having self-eccentricity according to the present invention, a concrete pouring portion having a convex shape in which the central portion and the central portion of the lower surface of the upper surface have the same convex shape, And an eccentricity is formed between the center line of the concrete poured portion and the steel wire.

The upper and lower surfaces of the concrete poured portion may have the same curved shape or straight slope-horizontal plane-straight slope shape.

The method of tensioning a steel wire according to the present invention is a pretension or post tension method.

The prestressed concrete member having its own eccentricity according to the present invention has the following effects.

1) Pre-tensioned concrete members with a similar moment effect can be manufactured without using a hold-down device used in conventional pre-tensioned concrete production.

2) Due to the nature of the form, the weight is reduced compared to existing prestressed concrete members, resulting in reduced installation load in the field.

3) It is used as a half-slab (108) that creates a horizontal plane by installing a topping concrete after installation. It can be applied to a long-span slab of a building and a small bridge of a civil engineering work. In the case of the structure, it is possible to reduce the amount of concrete by installing it as it is without finishing.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a graph showing a bending moment generated in a member when a service load is supported on horizontal members in a slab or a slab,
2 is a cross-sectional view of a conventional pre-stressed concrete member,
3 is a sectional view of a precast concrete plate according to a first embodiment of the first type of the present invention,
4 is a cross-sectional view of a precast concrete plate according to a second embodiment of the first type of the present invention,
5 is a sectional view of a precast concrete plate according to a third embodiment of the first type of the present invention,
Figure 6 is a cross-sectional view of a precast concrete plate according to a first embodiment of the second type of the present invention,
7 is a sectional view of a precast concrete plate according to a second embodiment of the second type of the present invention,
8 is a cross-sectional view of a precast concrete plate according to a first embodiment of the third type of the present invention,
9 is a cross-sectional view of a precast concrete plate according to a second embodiment of the third type of the present invention
Fig. 10 is a graph showing a moment graph
11 is a cross-sectional view of a precast concrete plate according to a fourth type of the present invention

3 to 5, as a first type of a self-eccentrically-prestressed concrete member according to the present invention, a center line 102 of concrete poured portion 101 and a steel wire 103 So that the eccentricity 104 is generated and the effect of the moment due to the prestress (FIG. 10) is effectively utilized.

The center portion of the upper surface of the concrete poured portion 101 is convex upward and the lower surface thereof is in the form of a straight line and the steel wire 103 is pulled in the form of a straight line to secure the minimum concrete covering thickness from the lower surface.

3 has a curved upper surface, and the upper surface is a straight inclined surface-a horizontal surface-a straight inclined surface. The shape of FIG. 5 is a symmetrical step shape of the upper surface and a straight line of the center line 102 But it is set according to the stair shape.

6 and 7, there is shown a second type of prestressed concrete member having self-eccentricity according to the present invention, in which the centerline 102 of the concrete placement portion 101 and the steel wire 103 tensioned in a straight line So that the eccentricity 104 is generated and the effect of the moment due to the prestress (FIG. 10) is effectively utilized.

The upper surface of the concrete poured portion 101 is straight and the central portion of the lower surface has a convex shape and the steel wire 103 secures a minimum concrete covering thickness from the lower surface and is pulled in the form of a straight line.

6 has a lower surface in a curved shape, and the lower surface in FIG. 7 has a straight inclined surface-a horizontal surface-a straight inclined surface.

8 and 9, a third type of prestressed concrete member having self-eccentricity according to the present invention is characterized in that between the center line 102 of the concrete casting portion 101 and the steel wire 103 pulled straight So that the eccentricity 104 is generated and the effect of the moment due to the prestress (FIG. 10) is effectively utilized.

The center portion of the upper surface and the lower surface of the concrete poured portion 101 are convex upward and the steel wire 103 secures the minimum concrete covering thickness from the lower surface and is pulled in the form of a straight line.

8, the top and bottom surfaces are in the same curved shape, and the top and bottom surfaces of FIG. 9 have the same shape of the straight inclined plane-the horizontal plane-the straight inclined plane.

In all of the above types, a moment due to the prestress (FIG. 10) is generated by the eccentricity 104 between the center line of the concrete poured portion and the steel wire, effectively reducing the moment due to the working load (FIG. Also, the cross section of the pre-stressed concrete members is reduced, reducing the working load in the field.

The prestressed concrete member having self-eccentricity according to the present invention is composed of a steel wire 103 which is linearly disposed and tensioned at a position where the minimum covering thickness is secured from the lower surface of the concrete placement portion 101. The tensioning method of the steel wire 103 is a pre-tensioning or post-tensioning method.

The prestress uses a method of tensioning a steel wire and transferring its restoring force to the concrete by a compressive force. When there is eccentricity between the center of the concrete placement part and the steel wire being tensioned, a moment due to the prestress (FIG.

The design process of the prestressed concrete member having the self-eccentricity according to the present invention is as follows.

1) Calculate the moment value by the load at each load step

2) Assume the dimensions of a prestressed concrete member with its own eccentricity.

3) Determining the minimum thickness of the concrete in the steel wire determines the moment due to the tensile of the unit steel wire.

4) The number of necessary steel wire is assumed according to the value of moment by the working load.

5) Calculate the stresses generated in the members by the axial force (tensile force of the steel wire) and the moment acting on the concrete member (composite member in the case of the half slab) by the load step.

6) Repeat steps 1) to 5) to determine the appropriate dimensions of the concrete pouring part and the appropriate number of steel wires.

In the present invention, the center line is formed in a convex shape along the axial direction of the concrete member rather than a straight line, and a negative moment (FIG. 10) is generated by a straight line. This can effectively reduce the positive moment generated by the working load (Fig. 1).

Referring to FIG. 11, a half slab 108, which is a half-slab 108 that creates a horizontal plane by installing a topping concrete 107 after installation, can be applied to long-span slabs of buildings and small bridges of civil engineering works. In the case of a structure that does not require a horizontal plane, it can be installed in the form of an invention to reduce the amount of concrete.

It is to be understood that the present invention is not limited to the above-described embodiment, but may be practiced in various other forms, such as those described in the following claims It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

101: concrete pouring portion 102: center line
103: Steel wire 104: Eccentricity
107: Finishing concrete 108: Half slab

Claims (12)

delete delete The upper surface is a concrete slab having a straight sloping surface - a horizontal slope - a straight sloping surface, a center portion protruding from the bottom surface with a maximum protrusion and a lower surface having a straight line shape, and a steel slab having a minimum concrete covering thickness from the lower surface, Wherein an eccentricity is formed between a center line of the concrete pouring portion and the steel wire.
The upper surface of which is a symmetrical stepped shape, the center portion of which is projected to the maximum with respect to the lower surface and the lower surface has a straight shape, and a steel wire which has a minimum thickness of concrete covering from the lower surface thereof and is stretched in the form of a straight line, And an eccentricity is formed between the center line of the poured portion and the steel wire.
delete delete delete delete The upper surface and the lower surface of which are formed of a concrete pouring portion having a curved shape so as to have a convex curved shape and a steel wire which is stretched in the form of a straight line while ensuring a minimum concrete covering thickness from the lower surface, And the eccentricity is formed between the first and second members.
Wherein the upper and lower surfaces comprise a concrete pouring portion having a straight sloped surface, a straight horizontal surface and a straight sloped surface and further projecting a central portion thereof, and a steel wire having a minimum concrete covering thickness secured from the lower surface thereof and stretched in the form of a straight line, And an eccentricity is formed between the center line and the steel wire.
delete A first step of calculating a moment value due to a load at each load step;
A second step of assuming the dimensions of a prestressed concrete member having its own eccentricity;
A third step in which a moment due to tensile of the unit steel wire is determined when the minimum thickness of concrete of the steel wire is determined;
A fourth step of assuming the necessary number of steel wires according to the moment value by the working load;
A fifth step of setting an axial force acting on the concrete member and a stress occurring in the moment member for each load step; And
The first to fifth steps are repeated so that the shape of the concrete poured portion is a curved shape in which the central portion of the upper surface is convex, the upper surface is a shape in which the central portion is further protruded in the form of a straight slope, a horizontal plane and a straight slope, A central portion of the upper surface and a central portion of the lower surface are curved so as to have a convex curve shape, and the upper surface and the lower surface have a shape of a straight slope - a horizontal plane - a straight slope, And determining an optimal number of the steel wires and a dimension of any one of the protruding shapes. The method of manufacturing a prestressed concrete member with self-eccentricity according to claim 1,

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