KR200409435Y1 - The crack induction structure of a concrete wall for improvement to effect of control joint - Google Patents

Abstract

The present invention relates to a crack inducing structure applied on a wall to improve the effect of crack inducing joint.

Such a crack inducing structure of the present invention, in a concrete structure embedded with rebar;

The cracks are induced by forming crack inducing joints in the longitudinal direction on the walls of the concrete structure so that the cracks generated through the tensile stress in the concrete due to the dry shrinkage of the concrete structure can be effectively controlled according to the sectional reduction rate of the wall. It is characterized in that it is made of a structure in which a hollow embedding body is embedded in a wall in which reinforcing bars are embedded in order to induce cracking to the joint side and to satisfy a sectional reduction rate defined on the wall.

And, the hollow buried body is installed in a line between the reinforcing bar and the reinforcing bar embedded in the wall of the concrete structure, characterized in that the rate of cross-sectional reduction of the wall defined by the hollow cross-sectional area of the buried body is satisfied.

Therefore, according to the present invention, it is possible to satisfy about 20% or more of the reduction ratio of the wall section defined by the hollow cross-sectional area of the buried body embedded in the wall of the concrete structure, and also to increase the tensile stress in the concrete by dry shrinkage. The cracks generated through the cracks are effectively induced to the crack-induced joints according to the sectional reduction rate of the wall, thereby reducing the cracks while preventing cracks in other parts. This is an excellent effect, such as easy to take action.

Concrete structures, walls, tensile stresses, cracks, crack-induced joints, hollow embedding

Description

The crack induction structure of a concrete wall for improvement to effect of control joint}

1 is a state diagram showing a crack generation process according to the dry shrinkage of a typical concrete.

Figure 2 is a state diagram and the A-A cross-sectional view of the conventional crack-induced joint for forming the crack on the wall.

3 is a cross-sectional state diagram of the wall to which the crack-induced structure of the present invention is applied.

Explanation of symbols on the main parts of the drawings

10. Crack Induced Joint

15. Rebar

20. Hollow embedded body

C. Concrete Structure Walls

The present invention relates to a crack inducing structure applied on a wall to improve the effect of crack inducing joints, and more specifically, to control the occurrence of cracks generated through tensile stress in concrete by dry shrinkage of a concrete structure. In order to satisfy the sectional reduction rate defined in the wall of the concrete structure in which crack-induced joints are spaced apart in the longitudinal direction of the wall, hollow embedding bodies, which are PVC round pipes, are arranged in a row, In addition to ensuring that the wall reduction rate of the wall defined by the hollow cross-sectional area of the sieve is about 20% or more, the cracks generated through the tensile stress in the concrete due to dry shrinkage are determined in accordance with the reduction rate of the wall. Effectively control crack induction, such as causing it to occur on the crack-induced joint The present invention relates to a crack inducing structure of a wall for improving the effect of crack inducing joint, which makes it possible to easily reduce the cracking point while preventing cracks in other parts and to easily follow up at the cracking point.

In general, at the beginning of concrete pouring, cement paste is known to cause a loss of wetting, which causes shrinkage and shrinkage up to 0.05% of the maximum concrete volume.

If the shrinkage of the concrete occurs without any restraint force, the concrete will not crack, but the concrete structure is usually constrained by the foundation or other structural members or the reinforcing bars in the concrete.

As described above, tensile stress is generated in the concrete by the combination of shrinkage and restraint. When the tensile stress reaches the tensile strength of the concrete, the concrete is cracked due to dry shrinkage as shown in FIG. 1.

In addition, another form of restraint may be caused by the difference in shrinkage in the concrete surface and the amount of shrinkage in the concrete member, where the dry shrinkage is always large in the surface exposed to the atmosphere, Restrain the contraction.

Due to this difference, the tensile stress is generated inside the concrete, which causes the surface crack. Cracks on the surface do not initially penetrate into the concrete, but upon further drying they propagate deep into the concrete member.

On the other hand, the main factors influencing the drying shrinkage are cement, aggregate form, water content and compounding components, and also greatly influenced by the moisture loss rate of concrete, the size and shape of the members, environmental factors and the time exposed to drying. Among them, the material factors related to dry shrinkage are described as follows.

The size of the dry shrinkage depends on the type of cement. According to the results of experiments using concrete made of various cements, the cement mixed with medium thermal cement or fly ash shows the least dry shrinkage. Next, the crude steel portland cement and the ordinary portland cement show relatively close dry shrinkage. When the silica or blast furnace slag is mixed, the dry shrinkage is higher than the ordinary portland cement. Known.

The crack initiation period also differs by cement, so when blast furnace slag is used, the crack initiation period is also the fastest, followed by portland cement and fly ash cement.

As shown in FIG. 2, the crack-induced joints 10 are longitudinally formed on the wall C of the concrete structure so as to effectively control the crack caused by the tensile stress in the concrete due to the dry shrinkage of the concrete structure as described above. ) Is formed to be spaced apart at equal intervals so as to cause cracks on the crack-induced joint 10, in which case the crack-induced joint 10 is constructed in the field with a length of about 35mm × 35mm while forming a triangular notch shape. do.

At this time, the triangular notch-shaped crack-induced joint 10 is formed in a length of about 35 mm x 35 mm in order to prevent exposure of the steel coating thickness embedded in the concrete structure to the atmosphere. Since the crack-induced joints 10 of 10 are applied to the walls C of concrete structures of different thicknesses collectively, the reduction ratio of the walls of the concrete structures wall C specified in the specification should be about 20% or more. It is not possible to meet the expected effect of being able to control effective crack initiation such as causing cracks generated through tensile stress in concrete to be caused to the crack inducing joint 10 side according to the sectional reduction rate of the wall C defined above, In particular, since the triangular notch-shaped crack inducing joint 10 is prescribed in the specification, the reduction rate of the cross-section of the concrete structure wall C is approximately reduced. If more than 20%, the reinforcing steel bars embedded in the concrete structure is exposed to the air there was a big problem such that the strength of the concrete structure is greatly reduced by the oxidation and corrosion effects.

In addition, when the crack-induced joint 10 having a length of about 35 mm × 35 mm is formed on the wall C of the concrete structure as described above, the crack caused by the tensile stress in the concrete due to dry shrinkage is caused by the crack-induced joint 10 As the cracks grow to the other part and the cracks occur at the same time, the post-working work is very cumbersome and the strength of the concrete structure becomes very weak. There was also.

The present invention devised to solve the conventional problems as described above, to form a crack-induced joint in the longitudinal direction of the wall to control the generation of cracks generated through the tensile stress in the concrete by the dry shrinkage of the concrete structure In order to satisfy the sectional reduction rate defined in the wall of the concrete structure, hollow embedding bodies, which are PVC circular pipes, are arranged in a row, so that the wall defined by the hollow cross-sectional area of the embedded structure embedded in the wall of the concrete structure The purpose is to be able to meet the section reduction rate of about 20% or more.

In addition, by embedding the hollow embedding material, which is a PVC circular pipe, in a line in the wall of the concrete structure in which the crack-induced joints are spaced apart in the longitudinal direction of the wall as described above, the cracks generated through the tensile stress in the concrete by dry shrinkage. Another purpose is to be able to effectively control the crack initiation, such as to be caused to the crack-induced joint side according to the sectional reduction rate of the wall.

And by satisfying the sectional reduction rate of the wall through the hollow buried body embedded in the wall of the concrete structure as described above, while preventing the occurrence of cracks in other parts of the wall of the concrete structure while reducing the cracking point Another goal is to make it easier to follow up at the crack.

The crack inducing structure of the wall for improving the crack inducing joint effect of the present invention, in the concrete structure embedded with rebar;

The cracks are induced by forming crack inducing joints in the longitudinal direction on the walls of the concrete structure so that the cracks generated through the tensile stress in the concrete due to the dry shrinkage of the concrete structure can be effectively controlled according to the sectional reduction rate of the wall. It is characterized in that it is made of a structure in which a hollow embedding body is embedded in a wall in which reinforcing bars are embedded in order to induce cracking to the joint side and to satisfy a sectional reduction rate defined on the wall.

And, the hollow buried body is installed in a line between the reinforcing bar and the reinforcing bar embedded in the wall of the concrete structure, characterized in that the rate of cross-sectional reduction of the wall defined by the hollow cross-sectional area of the buried body is satisfied.

In addition, the size of the hollow buried body is determined according to the wall thickness of the concrete structure, characterized in that the hollow buried body between the reinforcing bar and the reinforcing bars are spaced apart at equal intervals.

In addition, the hollow buried body is characterized in that the hollow circular pipe of PVC material.

Hereinafter, the crack inducing structure of the wall for improving the crack inducing joint effect of the present invention will be described in detail with reference to the drawings.

Figure 3 shows a cross-sectional state diagram of the wall to which the crack-induced structure of the present invention is applied.

Before describing the crack inducing structure for improving the crack inducing joint (10) effect of the present invention to apply the same reference numerals to the same structure as the conventional wall (C) in which the crack inducing joint (10) is formed Shall be.

The crack-induced structure of the wall (C) for improving the effect of the crack-induced joint 10 according to the present invention, is generated through the tensile stress in the concrete by the dry shrinkage of the concrete structure embedded with the reinforcing bar 15 as in the prior art The crack-induced joints 10 are formed at equal intervals in the longitudinal direction on the wall C of the concrete structure so that the cracks can be effectively controlled according to the sectional reduction rate of the wall C. The crack generated by the tensile stress is moved to the crack-induced joint 10 to cause cracks on the crack-induced joint 10, and is formed on the wall C of the concrete structure as described above. The reinforcing bar 15 may be used to satisfy the section reduction rate defined on the wall C so that the induction effect on the crack induction to the crack inducing joint 10 may be expected. It consists of embedding the hollow embedding body 20 in the installed wall (C).

At this time, the crack-induced joint 10 formed on the wall (C) of the concrete structure has a triangular notch shape as described in the prior art, and is constructed in the field with a length of about 35 mm × 35 mm.

In addition, the hollow buried body 20 is made of a hollow circular pipe made of PVC, and is installed in a line between the reinforcing bar 15 and the reinforcing bar 15 embedded in the wall (C) of the concrete structure is By the hollow cross-sectional area of the embedding body 20, the reduction ratio of the cross section of the wall C is satisfied to about 20% or more.

And, the hollow buried body 20, that is, in the case of a hollow circular pipe made of PVC material is installed at regular intervals between the reinforcing bar 15 and the reinforcing bar 15 while being circular according to the thickness of the wall (C) of the concrete structure The size of the pipe and the separation distance between the pipes are determined.

As described above, when the reduction ratio of the cross section of the concrete structure wall C is about 20% or more by the hollow embedding body 20, that is, the hollow circular pipe made of PVC, the reinforcing bars embedded in the concrete structure as in the prior art ( 15) Even if the triangular notched crack inducing joint 10 is formed to a length of about 35 mm x 35 mm to prevent the exposure of the coating thickness, cracks generated through the tensile stress in the concrete due to dry shrinkage are not defined. According to the cross-sectional reduction rate of C), it is possible to effectively control the induction of cracks such as to be caused to the crack inducing joint 10 side, to prevent the occurrence of cracks in other parts and to reduce the crack points and to easily follow up at the crack points. have.

As described above, the above-described embodiment is described with respect to the most preferred example of the present invention, but is not limited to the above embodiment, and it is apparent to those skilled in the art that various modifications are possible without departing from the technical spirit of the present invention. will be.

The crack inducing structure of the wall for improving the crack inducing joint effect of the present invention is spaced apart from the crack inducing joint in the longitudinal direction of the wall to control the occurrence of the crack generated through the tensile stress in the concrete by the dry shrinkage of the concrete structure The wall is defined by the hollow cross-sectional area of the buried body embedded in the wall of the concrete structure by constructing the hollow embedding body, which is a PVC circular pipe, in a row in order to satisfy the sectional reduction rate defined in the wall of the formed concrete structure. There is an excellent effect, such as can meet the cross-sectional reduction rate of about 20% or more.

In addition, by embedding the hollow embedding material, which is a PVC circular pipe, in a line in the wall of the concrete structure in which the crack-induced joints are spaced apart in the longitudinal direction of the wall as described above, the cracks generated through the tensile stress in the concrete by dry shrinkage. There is also an effect such as to effectively control the crack induction, such as to be caused to the crack-induced joint side according to the sectional reduction rate of the wall.

And by satisfying the sectional reduction rate of the wall through the hollow buried body embedded in the wall of the concrete structure as described above, while preventing the occurrence of cracks in other parts of the wall of the concrete structure while reducing the cracking point and at the same time There are also effects that make it easier to follow up at a point.

Claims (4)

In a concrete structure in which rebar is embedded; The cracks are induced by forming crack inducing joints in the longitudinal direction on the walls of the concrete structure so that the cracks generated through the tensile stress in the concrete due to the dry shrinkage of the concrete structure can be effectively controlled according to the sectional reduction rate of the wall. In order to cause cracking to the joint side, and to satisfy the sectional reduction rate defined on the wall, the crack-induced joint effect improvement is characterized in that the hollow buried body is embedded in the wall in which the reinforcing bar is embedded. Crack-induced structure for walls. The method of claim 1, wherein the hollow buried body is installed in a line between the reinforcing bar and the reinforcing bar embedded in the wall of the concrete structure, characterized in that the reduction rate of the cross section of the wall defined by the hollow cross-sectional area of the buried body Wall cracking structure to improve crack inducing joint effect. The method of claim 2, wherein the size of the hollow buried body is determined according to the thickness of the wall of the concrete structure, improving the crack-induced joint effect, characterized in that the hollow buried body is installed at equal intervals between the reinforcing bar and the reinforcing bar Crack-induced structure for walls. 4. The crack inducing structure of a wall for improving the crack inducing joint effect according to any one of claims 1 to 3, wherein the hollow embedding body is a hollow circular pipe made of PVC.

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