KR101382026B1 - Reclaimation sealant for induced crack - Google Patents

Abstract

The present invention relates to a linear sealant being buried for inducing cracks which is installed on the periphery of a concrete structure such as a tunnel, a bridge, an ecological corridor, a waterway, a passageway, an underground roadway, a retaining wall, an under drainage, and a closed conduit and which enables the induction of structural cracks (C) having a concrete cut-surface form so as to prevent non-structural cracks caused by the drying shrinkage owing to the temperature difference between summer and winter, a creep, and live loads. The present invention is characterized by comprising: a body (10) buried on the periphery of the portion of the concrete structure (80) desired to form the structural cracks (C); branch units (20) which are extended downward from both lower sides of the body (10) and branched to expose the bottoms of the branch units to the outside; joining protrusions (30) which are extended upward from the upper parts of the branch units (20) in order to increase a force of being joined to the concrete structure (80); and a crack inducing plate (40) which is extended from the upper part of the body (10) to the inside of the concrete structure (80) to induce the structural cracks on the concrete structure (80).

Description

Crack induction sealant {RECLAIMATION SEALANT FOR INDUCED CRACK}

The present invention relates to a landfill sealant for crack induction, and more particularly, it is installed in concrete structures such as tunnels, bridges, ecological passages, waterway boxes, passage boxes, underground roadways, retaining walls, side holes, and culverts. The present invention relates to a crack inducing sealant for inducing structural cracks in the form of a concrete cut surface to prevent dry shrinkage caused by change and unstructured cracks caused by creep and live loads.

In general, concrete structures are installed continuously and spaced at regular intervals to facilitate the movement of drying contraction, creep, and live load due to temperature changes such as winter and summer.

At this time, silicon finish is essential to prevent rainwater or groundwater from penetrating between the constructed concrete structure and the structure.

Hereinafter, a brief description will be given of a conventional silicone finish for waterproofing.

As shown in Figure 9, to proceed with the "face" arrangement ② to waterproof between the concrete structures 80 ① separately constructed.

Then, a masking tape is applied to a portion where silicon is not required (not shown).

Thereafter, a primer is applied to a region where the silicon is to be applied (not shown).

Then, the silicon (S) is applied to the "side" treated part ③.

Wait until the silicon (S) is cured and back to silicon (S) to complete.

As such, the following problems occur because the conventional silicon finish.

There was a problem that the construction period is long.

In addition, additional costs, such as the cost of crushing the workpiece, are increased.

In addition, it takes a long time to process the residue after the silicon treatment.

In addition, since the silicon processing work must be done manually, labor costs for silicon processing are high.

In addition, due to the poor strength and durability of silicon, extra repair fees are issued until the end of construction.

In addition, the quality is not constant depending on the skill of the skilled worker.

Meanwhile, conventional concrete structures such as tunnels, bridges, ecological passages, waterway boxes, passage boxes, underground roadways, retaining walls, side holes, and culverts have to be constructed at regular intervals to prevent unstructured cracks. There was a problem.

The present invention has been made in view of the above problems, the first object of the present invention, tunnels, bridges, ecological passages, waterway boxes, passage boxes, underground passages, retaining wall holes, side holes, culverts, such as concrete structures It is to provide a crack-induced landfill sealant that can induce structural cracks in the form of concrete cut surfaces to prevent dry shrinkage caused by temperature changes during winter and summer, and unstructured cracks caused by creep and live loads. .

A second object of the present invention is to provide a crack inducing sealant for a structure that can induce a structural crack in the concrete structure to build a plurality of concrete structures separated by only one concrete pouring.

A third object of the present invention is to provide a crack inducing sealant which does not require a separate silicone waterproofing process on the structural crack portion of the concrete structure.

According to a feature of the present invention for achieving the above object, the first invention is a circumference of a concrete structure, such as tunnels, bridges, ecological passages, waterway boxes, passage boxes, underground passages, retaining wall holes, side holes, culvert holes Linear crack induction sealant installed in the concrete to induce structural crack (C) in the form of concrete cutting surface to prevent dry shrinkage and creep and live loads. It relates to, for this purpose the body 10 is buried around the position to form a structural crack (C) in the concrete structure (80); and, so that the lower surface can be exposed to the outside of the concrete structure (80) Branches 20 extending downwardly branching on both lower sides of the body 10; And, to increase the binding force with the concrete structure 80, extending upwardly on the top of each branch 20 In projections 30; And a crack induction plate 40 extending toward the inside of the concrete structure 80 on the top of each body 10 to induce a structural crack C in the concrete structure 80; Between each branch portion 20 is formed with a groove portion 21 for fixing the crack-inducing buried sealant 60 to the formwork 70, the groove portion 21 with a concrete structure 80 and a watertight function The cover member 50 is inserted to horizontally finish the inner periphery, and the body 10 and each branch portion 20 form a truss space portion T in the center to form a concrete structure 80. It is characterized in that it is configured to be smoothly stretched in response to the contraction and expansion.

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In the fourth invention, in the first invention, it is preferable that a water-expandable index agent 31 is applied to the surface of each of the binding protrusions 30 so as to expand and block the inflow of water when water is introduced therein.

The fifth invention, in the first invention, it is preferable that the body 10 and the branch portion 20 has a wrinkle portion (W) on the surface to enhance the binding force with the concrete structure (80).

The sixth invention, in the first invention, the body 10 has a shape that gradually decreases in thickness toward the top, the crack guide plate 40 of the concrete structure 80 in the upper portion of the body (10) It is preferable that the structure extends inwardly.

According to the crack induction sealant of the present invention, the concrete structure can be separated into multiple stages by only one concrete pouring, and thus the construction is very quick and simple and the construction cost can be greatly reduced.

In addition, there is an effect that does not require a separate silicone waterproofing process on the structural crack of the concrete structure.

In addition, by applying the water-expandable index agent to prevent rainwater or groundwater from penetrating, it is easy to install and has a pre-fabricated effect to maintain a uniform quality.

1 is a perspective view of a crack inducing sealant for induction according to the present invention;
2 is a cross-sectional view of the crack inducing sealant for induction according to the present invention;
3 is an exploded perspective view of a crack inducing sealant for induction according to the present invention;
Figure 4 is a cross-sectional view of the concrete structure to which the crack induction sealant for induction according to the present invention,
5 is a cross-sectional view of a crack induction sealant showing a crack induction plate of various forms,
6 to 8 is a construction sequence diagram of the crack induction sealant for induction according to the present invention,
9 is a flow chart showing the silicon finish of concrete structures individually constructed.

In the following, the crack inducing sealant for induction according to the present invention will be described in detail together with the accompanying drawings.

1 is a perspective view of a crack induction sealant according to the present invention, FIG. 2 is a cross-sectional view of a crack induction sealant according to the present invention, and FIG. 3 is an exploded perspective view of the crack induction sealant according to the present invention. 4 is a cross-sectional view of a concrete structure to which a crack induction sealant is applied according to the present invention, and FIG. 5 is a cross-sectional view of a crack induction sealant showing various types of crack induction plates.

First, as shown in Figures 1 to 4, the present invention is installed in concrete structures, such as tunnels, bridges, ecological passages, waterway boxes, passage boxes, underground roadways, retaining wall holes, side holes, culverts, winter, summer temperature changes The present invention relates to a crack inducing sealant (60) for inducing structural cracks (C) in the form of a concrete cut surface to prevent unstable cracking caused by dry shrinkage, creep, and live load.

The crack induction sealant 60 is installed in a circumference of the concrete structure 80 is configured in a linear manner to induce a structural crack (C) of the concrete structure (80).

The crack induction sealant 60 for induction according to the present invention takes a linear form and is partially embedded around the concrete structure 80 to induce a structural crack (C) in the concrete structure 80, rubber, Made of PVC, PE, polyethylene, silicone.

The crack induction sealant 60 is composed of four parts, which is composed of a body 10, a branch 20, a binding protrusion 30 and a crack induction plate 40.

In addition, the body 10 is embedded in each of the periphery of the position to form a structural crack (C) in the concrete structure (80).

The branch portions 20 are branched to extend downwards to the outside on both lower sides of the body 10, respectively.

Each branch 20 is formed in the shape of a rectangular cross section so as to increase the contact area with the concrete structure 80 to strengthen the binding force, structural cracks (C) generated in the concrete structure 80 is separated into two If so, each concrete structure 80 is configured to be fixed to each of the elastically buried separately.

In addition, the groove portion 21 is formed between the branch portion 20 which is branched from the body 10, the groove portion 21 of the concrete structure 80 together with the lower surface of each branch portion 20 It is a configuration exposed to the outside.

The groove portion 21 is used to fix the crack induction sealant 60 to the formwork 70 before placing the concrete.

In addition, the groove 21 is a surface finish after the curing of the concrete to be parallel to the inner periphery of the concrete structure 80 with a waterproof function to prevent the discharge of groundwater and rainwater through the structural crack (C) It is used to insert a cover member 50 which can be processed.

Here, the cover member 50 is composed of a coupling portion 51 and the seal portion 52, the coupling portion 51 is coupled to the groove portion 21, the seal portion 52 is each branch portion 20 Cover the bottom surface of the silicone (S) is configured to allow the surface finish with the function of watertightness without a separate waterproof (S).

The cover member 50 is also made of rubber, PVC, PE, polyethylene, silicon.

On the other hand, each of the binding projections 30 is to prevent each branch 20 from being separated from the concrete structure 80, in each branch 20 to increase the binding force with the concrete structure (80) It is a structure extending upward.

Each of the binding protrusions 30 is configured to be formed at each branch 20, but in addition, two, three, four, etc. may be formed in order to increase the binding force with the concrete structure (80). Do.

In addition, the water-expandable index agent 31 is applied to each of the binding protrusions 30 so that when the rainwater and groundwater flow in, the water-expandable index agent 31 expands to block the inflow of rainwater and groundwater. It is configured to be further strengthened.

The crack induction plate 40 extends toward the inside of the concrete structure 80 on the upper portion of each body 10, the concrete structure 80 to induce a structural crack (C) of the concrete structure 80 ) To weaken the stress.

That is, the crack induction plate 40 weakens the stress at a predetermined portion of the concrete structure 80 so that a structural crack (C) is generated as a site where the stress is weakened so that one concrete structure 80 is divided into two concretes. It serves to guide the separation into the structure (80).

Meanwhile, the body 10 has a form in which the thickness gradually decreases toward the upper side, and the crack induction plate 40 extends toward the inside of the concrete structure 80 at an upper vertex of the body 10. It is desirable to configure so that.

This is to gradually narrow the upper thickness of the body 10 is to enable the body 10 also to form a structural crack (C) of the concrete structure.

In addition, the shape of the body 10 is preferably formed in a triangular shape or trapezoidal shape.

In addition, the body 10 and each branch 20 may form a wrinkle portion (W) on the surface to strengthen the binding force with the concrete structure (80).

In addition, the body 10 and each branch 20 may be configured to be smoothly stretched in response to the contraction and expansion of the concrete structure 80 by forming a truss space portion (T) in the center.

On the other hand, the crack induction plate 40 may be formed of two and three, as shown in (a), (b) of Figure 5, in addition to the three, as shown in (c), the crack induction plate 40 of the center Of course, it can be configured to lengthen.

Hereinafter, the construction method of the crack inducing sealant for induction according to the present invention will be briefly described.

6 to 8 are construction sequence diagrams of the crack inducing sealant for induction according to the present invention.

① form the formwork (70) of the concrete structure.

② Fix the crutch 71 to the formwork 70 of the portion to form a structural crack (C) in the concrete structure.

③ Insert the groove part 21 formed between each branch part 20 in each said strut 71, and fix the crack guide embedding sealant 60.

④ curing by pouring concrete into the formwork (70).

⑤ When the curing process of the concrete is finished, the concrete structure (80) is constructed by dismantling the formwork (70) and the shoring (71).

⑥ Insert the cover member 50 into the groove portion 21 exposed to the outside of the concrete structure 80 to increase the waterproof function, and also to finish the surface by making the inner circumference with the concrete structure 80 to be horizontal do.

⑦ The crack induction plate 40 extended to the body 10 of the crack inducing sealant 60 to concentrate the stress in accordance with the dry shrinkage, creep, live load caused by temperature changes in winter and summer To form a crack (C).

Through the above process, even if the concrete is poured only once, it is possible to build a plurality of concrete structures.

As such, the induction sealant for crack induction according to the present invention does not have to undergo a separate silicone waterproofing process on the structural cracks of the concrete structure as its vehicle body, thereby reducing construction cost and further increasing the waterproof function by combining the cover member. The surface treatment can also be smoothed.

In addition, conventionally to form a large number of formwork for each single piece to prevent unstructured cracks in a long concrete structure, and to build a concrete structure in each form individually, on the other hand, the present invention is to build a single formwork, If you install a crack induction sealant at regular intervals at the position where you want to form a structural crack in the formwork, it can be separated into two, three, four concrete structures even if only one concrete is poured. There is this.

Although the present invention has been described in connection with the preferred embodiments mentioned above, various other modifications and variations will be possible without departing from the spirit and scope of the invention. It is, therefore, to be understood that the appended claims are intended to cover such modifications and changes as fall within the true scope of the invention.

10: Body
20: branch portion 21: groove portion
30: binding protrusion 31: water expansion index
40: crack induction plate
50: cover member 51: coupling portion 52: seal portion
T: Truss space portion W: Corrugation portion
60: landfill sealant for crack induction according to the present invention
70: Formwork 71: Shoring
80: concrete structure C: structural crack

Claims (6)

It is installed around concrete structures such as tunnels, bridges, ecological passages, waterway boxes, passage boxes, underground roadways, retaining walls, sideways holes, and culverts. In the linear crack-induced landfill sealant that can induce structural cracks (C) in the form of concrete cutting surfaces to prevent cracks,
A body 10 embedded in a circumference of a position where a structural crack C is to be formed in the concrete structure 80;
Branch portions 20 extending downwardly branching to both lower sides of the body 10 so that the lower surface is exposed to the outside of the concrete structure 80;
Binding protrusions 30 extending upwardly on the upper ends of the respective branching portions 20 to increase the binding force with the concrete structure 80; And
In order to induce a structural crack (C) in the concrete structure 80, the crack induction plate 40 extending toward the inside of the concrete structure 80 on the upper portion of each body 10;
Between each branch portion 20 is formed a groove portion 21 for fixing the crack-inducing buried sealant 60 to the formwork 70,
The groove portion 21 is inserted into the cover member 50 for the surface finish by making the concrete structure 80 and the inner circumference parallel to the watertight function,
The body 10 and each branch 20 is formed in the center truss space portion (T) for crack induction, characterized in that configured to be smoothly stretched in response to the contraction and expansion of the concrete structure (80) Landfill sealant.
delete delete The method according to claim 1,
The buried sealant for crack induction sealant, characterized in that the water expansion index (31) is applied to the surface of each of the binding projections 30 to expand when the water is introduced to block the inflow of water.
The method according to claim 1,
The body (10) and the branch portion (20) is a crack-inducing buried sealant, characterized in that it has a wrinkle portion (W) on the surface to strengthen the binding force with the concrete structure (80).
The method according to claim 1,
The body 10 has a shape that gradually decreases in thickness toward the top, the crack induction plate 40 is characterized in that the structure extending toward the inside of the concrete structure 80 from the top of the body 10 A crack sealant for landfill seal.

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