KR102038406B1 - Repair and Reinforcement Method of Concrete Structure - Google Patents

Abstract

The present invention relates to a concrete structure repair and reinforcement method that can effectively prevent the failure of a repair site by reliably repairing a concrete structure that is cracked or partially damaged due to aging. The concrete structure repair and reinforcement method according to the present invention for solving the above problems comprises: a repair site selection step of selecting a repair site of a cracked concrete structure; a surface cutting step of cutting a predetermined radius and a predetermined depth based on the selected repair site to expose a rebar of the repair site to the outside; an antirust treatment step of applying a rust inhibitor to the rebar exposed to the surface; a primer applying step of applying a primer to the cut concrete surface; a concrete repair agent applying step of applying a concrete repair agent to the concrete surface to which the primer is applied; and a finishing step of applying and finishing an anti-neutralization agent on the surface after the applied concrete repair agent is dried. In the surface cutting step, if the repair site is the concrete surface partially broken and damaged, the repair site is cut 2-5 cm deeper than the concrete surface damaged and exposed, and, when the repair site is a crack having a predetermined gap, the repair site is cut to have a ″V″ shape up to the inner surface where there is no crack from the crack.

Description

Repair and Reinforcement Method of Concrete Structure

The present invention relates to a method for reinforcing concrete structures, and more particularly, to a method for repairing and strengthening structural steel and neutralized concrete corroded by cracks and concrete shorts in concrete structures that are constructed so that the concrete surface is exposed to the outside. It is about.

In general, when concrete structures are constructed so that the surface is exposed to the outside, after 10 years, carbon dioxide in the air and calcium hydroxide in concrete undergo chemical reactions, which are converted to calcium carbonate, and neutralization (carbonation) proceeds. Concrete loses alkalinity.

When the alkalinity of the concrete is lost, the internal steel bars are oxidized and rust is generated. As a result, the volume of the steel bars increases due to the rust, thereby causing expansion pressure, which results in cracking of the concrete structure.

In addition, when water and carbon dioxide are infiltrated into the cracked portion of the concrete structure and degraded, the concrete is more easily damaged by external force, and as a result, the concrete structure is partially shorted and the internal steel bars are exposed to the outside. Safety will fall dramatically.

Therefore, in recent years, the repair method for improving the safety of the structure by repairing the aging concrete structure has been made.

As a prior art for the above purpose is disclosed a repair method (hereinafter referred to as "patent document") for the recovery and improvement of durability of the aging concrete structure No. 0743029.

Repair method of the concrete structure disclosed in the patent document, the rebar rust prevention step of applying a reinforcing steel bar anti-rust reducing agent consisting of a water-soluble lithium nitrite metal salt and a silane compound on the surface of the rebar exposed to the dropped concrete; Applying an alkali recovery and surface strengthening agent having a pH of 11 to 12 consisting of a water-soluble lithium silicate metal salt and a silane compound to the corroded reinforcement and damaged concrete surfaces; A cross-sectional recovery step of applying a hard-hard cross-section restoration mortar mainly composed of ultrafine cement having a diameter of 30 μm to 100 μm to the drop-off portion to which the alkali recovery and surface hardening agent is applied, to recover the cross-section; After the cross-sectional recovery of the concrete dropping portion is made of a finishing treatment step to finish the surface with a water repellent or waterproof resin material.

However, the repair method of the concrete structure disclosed in the patent document is to remove the rust of the rebar exposed to the outside, and then to repair the short-circuit part by applying the mortar after applying the alkali recovery and surface strengthening agent on the concrete surface, but in this case the neutralization progressed As the concrete remains in the interior, the neutralization of the concrete continues, whereby cracks easily occur between the repaired surface and the neutralized concrete surface, such that the repaired surface is shorted.

In addition, even if the rust is applied to remove the rust of the rebar, a large amount of rust may remain in the reinforcing bar, in this case, even if the mortar is applied to repair the surface, the reinforcing the rust proceeds in the interior as the crack is generated on the repaired surface again There is.

Therefore, in the repair of aging concrete structures, it is necessary to develop a reinforcing reinforcement method that can prevent the neutralization of concrete and rust recurrence (diffusion) of the reinforcing bars, and effectively prevent the regeneration of cracks on the repaired surface. .

KR 10-0743029 B1 (2007.07.20.) KR 10-1998-0075891 A (Nov. 16, 1998) KR 10-1994-0002454 A (1994. 02. 17.) KR 10-1859885 B1 (2018. 05. 14)

The present invention was devised to solve the problems of the conventional concrete structure repair and reinforcement method as described above, the problem to be solved by the present invention is to repair and repair a concrete structure that is cracked or partially damaged due to aging It is to provide a concrete structure repair and reinforcement method that can effectively prevent the defect of the site.

Concrete structure repair and reinforcement method according to the present invention for solving the above problems, the repair site selection step of selecting a repair site of the cracked concrete structure; A surface cutting step of cutting a predetermined radius a predetermined depth based on the selected repair portion to expose the rebar of the repair portion to the outside; An antirust treatment step of applying a rust inhibitor to the rebar exposed to the surface; Applying a primer to the cut concrete surface; A concrete repair agent applying step of applying a concrete repair agent to the concrete surface to which the primer is applied; And a finishing step of applying and finishing the anti-neutralization coating on the surface after the applied concrete repair agent is dried, and in the surface cutting step, when the repair part is a broken concrete surface that is partially shorted and damaged, the exposed concrete 2 to 5 cm deeper than the surface, and the repair portion is a crack having a predetermined gap, characterized in that the cross section is cut to the "V" shape to the inner surface without cracks based on the crack.

In another aspect, the present invention is characterized in that the cutting angle is cut to form a 30 ~ 120 ° when the crack is cut in the "V" shape in the surface cutting step.

In addition, the present invention is cut at an angle close to 30 ° when the depth of the crack portion is less than 5 cm in the surface cutting step, when the depth of the crack portion exceeds 5 cm at an angle closer to 120 ° The cutting is another feature.

In addition, the present invention is characterized in that the repair plan is established together to reinforce or install a steel plate or anchor to the concrete structure in the step of selecting the repair site or to increase the cross-sectional area of the concrete structure.

And the present invention is characterized in that the epoxy-based or acrylic primer is used in the primer coating step, the primer is applied to the cut surface three to five times so as to have a thickness of 2-3 mm as a whole.

According to the present invention, since the concrete portion that has been neutralized is removed by completely removing the repaired portion, it is possible to fundamentally prevent the secondary crack from occurring due to the neutralized concrete remaining.

In addition, since the rust of the reinforcing bar is removed using a rust inhibitor and then the surface is coated, even if rust remains in the reinforcing bar, the rust of the bar may be exposed to the air to prevent oxidation from proceeding.

In addition, since reinforcing bars are reinforced using reinforcing wires, there is an advantage of reinforcing concrete structures in which cracks are generated.

1 is a process chart showing an example of a concrete structure reinforcement method according to the present invention.
2 is a view showing a repair portion of the concrete structure according to the present invention.
3 is a view showing an example in which the repair portion according to the present invention is cut.
4 is a view showing an example in which the crack is cut according to the present invention.
5 is a process chart showing an example of the antirust treatment step according to the present invention.
6 is a view showing an example of the step of installing the reinforcing wire of the antirust process step according to the present invention.
Figure 7 shows an example of a primer application step according to the present invention.
8 is a view showing an example of a concrete repair agent applying step according to the present invention.
9 is a view showing an example in which the primer and the concrete repair agent are respectively applied to the cracks according to the present invention.

Hereinafter will be described in detail according to the accompanying drawings showing a preferred embodiment of the present invention.

The present invention is to provide a concrete structure repair and reinforcement method that can effectively prevent the damage of the repair site by reliably repairing the concrete structure that is cracked or partially damaged due to aging, this invention is shown in FIG. As described above, repair part selection step S10, surface cutting step S20, antirust treatment step S30, primer applying step S40, concrete repair agent applying step S50 and finishing step S60 are included.

(1) Step of repair part selection (S10)

This step is to grasp the degree of neutralization and the extent of cracking of the concrete structure in which the crack has occurred, and to select the repair part A to be repaired based on this.

In such a repair site selection step (S10), a separate support structure may be installed to temporarily support the structure as necessary in consideration of the extent of the repair site (A) and the progress of work.

In addition, in order to further secure the structural safety of the repaired concrete structure, the repair plan is established by sufficiently considering a method of reinforcing and installing a steel plate or an anchor on the concrete structure, or a method of increasing the cross-sectional area of the concrete structure.

(2) surface cutting step (S20)

In this step, after the repair part (A) is selected in the repair part selection step (S10), the reinforcement (B) of the repair part (A) is secured to the outside by cutting a predetermined radius based on the selected repair part (A). To be exposed.

The surface cutting step (S20) is divided into a case where the repair portion (A) is a short-circuit concrete surface broken and a crack (C) in which a crack is formed to a predetermined depth proceeds.

Here, in the case where the repair part A is a concrete surface that is partially shorted, as shown in FIG. 3, the concrete is partially shorted to cut irregular surfaces to be horizontal and vertical surfaces. 2 ~ 5 ㎝ deeper cutting is constructed so that the neutralized concrete can be completely removed.

In contrast, in the case where the repair portion A is the crack portion C of a predetermined gap, the cross section of the repair portion A as far as the deepest inner portion of the crack portion C is “V” as shown in FIG. 4. "It's cut to be shaped.

At this time, the angle to be cut is cut close to 30 ° when the depth of the crack C is less than 5 cm, and on the contrary, when the depth of the crack C exceeds 5 cm, the angle is cut closer to 120 °. The shallower the depth of the crack C, the narrower the depth of the deterioration through the crack C, and the narrower the depth of the crack C, through the crack C. This is due to the fact that the deteriorated depth is wide and the range is wide. Through this cutting method, it is possible to reliably remove the deteriorated concrete part while preventing unnecessary excessive cutting.

(3) antirust treatment step (S30)

This step is to remove the rust of the reinforcing bar (B) exposed to the outside through the cut surface after the concrete surface is cut through the surface cutting step (S20).

This anti-rust treatment step (S30) is a rust removal step (S31) for removing the rust by applying a rust remover to the surface of the rebar (B), as shown in Figure 5, the rust inhibitor on the surface of the rebar (B) from which the rust has been removed Anti-corrosive step of applying (S32), the coating step (S33) for applying a coating on the surface of the reinforcing bar (B) to which the rust inhibitor is applied and a reinforcing wire of a predetermined size so as to cover the surface of the reinforcing bar (B) to which the coating is applied Reinforcing wire installation step (S34) for mounting and fixing the (10).

In the rust removal step (S31), a rust remover composed of 12 to 15 parts by weight of oxalic acid, 10 to 15 parts by weight of silicon dioxide, 15 to 20 parts by weight of carboxymethyl cellulose, and 65 to 70 parts by weight of water is used. After being applied to the surface of (B), it is wiped off after a predetermined time and the components of the rust remover are removed together with the rust of the reinforcing bar (B).

In addition, in the rust prevention step (S32), an oil-soluble rust preventive agent is used, and more specifically, a rust preventive agent including alkylallyl sulfonate and lubricating oil is used.

In the coating step (S33), a coating agent including a carboxyvinyl polymer and an oil-soluble amine is used, wherein the carboxyvinyl polymer has a property of not being easily oxidized without a change in viscosity with respect to temperature. Therefore, when applied to the outer surface of the reinforcing bar (B) is prevented the diffusion of rust remaining in the reinforcing bars (B) while the bar (B) is blocked from contacting the air.

In addition, in the reinforcing wire installation step S34, as shown in FIG. 6, the reinforcing wire 10 is formed by twisting a plurality of steel wires having a diameter of 2 to 3 mm, and the reinforcing wire 10 is exposed to the rebar ( It is provided to surround the outer surface of B), whereby the rigidity of the reinforcing bar (B) is reliably reinforced.

(4) primer application step (S40)

In this step, after the rust of the reinforcing bar (B) is removed in the rust prevention treatment step (S30), and the rust prevention and coating process, the primer is applied to the concrete cutting surfaces (D, E) as shown in FIGS. 8 and 9. 20, 20 '), whereby the concrete repair layers 30, 30' formed in the concrete repair agent application step S50 to be described later and the existing concrete surface are strongly bonded so that cracks do not easily occur between them. .

At this time, the primer is epoxy or acrylic primer is used, and such primer is applied 3 to 5 times so as to have a thickness of 2 to 3 mm as a whole on the cutting surface (D) so that sufficient adhesive force can be exhibited.

(5) concrete repair agent application step (S50)

This step is to form a concrete repair layer (30, 30 ') by applying a concrete repair agent to the cutting surface (D, E) to which the primer is applied in the primer application step (S40).

In the concrete repair agent application step (S50), the repair is performed using a different type of concrete repair agent depending on the repair area. For example, in the case of a cutting surface (D) having a relatively large repair area, the repair is performed by using mortar as a repair agent. On the contrary, in the case of the cutting surface E with a small repair area, repair is progressed using an epoxy repair agent.

At this time, the epoxy-based repair agent is used a repair agent made of an epoxy resin, a curing agent, a curing accelerator and an additive, and the additive of such a repair agent may further include an antioxidant or an anti-UV agent for preventing and delaying neutralization.

In addition, the fiber glass chips cut to have a predetermined width and length are mixed in the epoxy-based repair agent at a predetermined ratio, thereby improving the rigidity of the hardened concrete repair agent and further preventing cracks from occurring.

At this time, it is preferable that the fiber glass chips are mixed at a ratio of 0.2 to 0.3: 1 compared to the epoxy resin, and when the fiber glass chips are mixed at less than 0.2, the stiffness reinforcing effect using the fiber glass chips is insufficient, and conversely, the fiber glass chips If it exceeds 0.3, there is a problem that it is difficult to obtain a uniform surface.

(6) finishing step (S60)

This step is to form a coating layer 40 of a predetermined thickness by applying the anti-neutralization coating on the concrete surface as shown in Figure 8 after the concrete repair agent applied in the concrete repair agent application step (S50) is dried.

This finishing step (S60) is made of a mixture consisting of an anti-neutralization coating comprising an epoxy resin, a plasticizer, a diluent, an antifoaming agent and a curing agent, more specifically 65 to 70 parts by weight of epoxy resin, 8 to 10 parts by weight of plasticizer, The anti-neutralization coating agent which consists of 0.1-0.2 weight part of antifoamers and 10-15 weight part of hardening | curing agents is used.

The concrete surface repaired by the above structure is prevented from being in direct contact with air by the coating layer, thereby preventing (delaying) the concrete, and as a result, the repair performance of the concrete structure is ensured for a long time.

As described above, since the present invention is completely removed by cutting concrete parts exposed to air and neutralized, and then repairing and reinforcing, the secondary cracks generated by the neutralized concrete remain essentially prevented.

In the above description, for the convenience of description, preferred embodiments have been described with reference to the drawings and the components shown in the drawings, but with reference to the figures and the designations shown in the drawings as one embodiment according to the present invention. It should not be construed that the scope of the right should be construed, and that the simple substitution of a configuration having the same function as the change to the various shapes predictable from the description of the invention is within the range that can be changed by those skilled in the art. It will be very self-explanatory.

10: reinforcing wire 20, 20 ': primer layer
30, 30 ': concrete repair layer 40: coating layer
A: repair site B: rebar
C: crack D, E: cutting surface

Claims (5)

Repair site selection step of selecting a repair site (A) of the concrete structure in which the crack occurred (S10);
A surface cutting step S20 of cutting a predetermined radius a predetermined depth based on the selected repairing portion A to expose the rebar B of the repairing portion A to the outside;
Anti-rust treatment step (S30) of applying a rust inhibitor to the rebar (B) exposed to the surface;
Primer application step (S40) for applying a primer on the cut concrete surface;
Concrete repair agent coating step of applying a concrete repair agent on the concrete surface is the primer is applied (S50); And
Finishing step (S60) to finish by applying the anti-neutralization coating on the surface after the applied concrete repair agent is dried;
Including,
In the surface cutting step (S20),
When the repaired part A is partially shorted and damaged concrete surface is cut 2 to 5 cm deeper than the damaged and exposed concrete surface, the irregular surface is cut to be horizontal and vertical surface, the repaired portion (A) is In the case of a crack part C having a predetermined gap, the cross section is cut to have an “V” shape up to the inner surface without cracks based on the crack part C,
The rust prevention step (S30),
Rust removal step (S31) for removing rust by applying a rust remover to the surface of the reinforcing bar (B);
Antirust step (S32) of applying a rust inhibitor to the surface of the reinforcing bar (B) rust is removed;
Coating step (S33) for applying a coating on the surface of the reinforcing bar (B) to which the rust preventive agent is applied; And
Reinforcing wire installation step (S34) to be installed so that the surface of the reinforcing bar (B) coated with a coating agent through the reinforcing wire 10 is formed by twisting a plurality of steel wire having a diameter of 2 ~ 3mm;
Including,
In the concrete repair agent application step (S50),
If the repair area is large, the repair is carried out using a mortar repair agent. If the repair area is small, the repair is carried out using an epoxy-based repair agent.
As said epoxy repair agent,
A repair agent composed of an epoxy resin, a curing agent, a curing accelerator and an additive is used,
The additive,
A method of repairing and reinforcing concrete structures, comprising an antioxidant or a sunscreen, wherein the fiberglass chips cut to have a predetermined width and length are mixed at a predetermined ratio.
delete delete The method according to claim 1,
In the repair site selection step (S10),
Repair method for reinforcing concrete structures, characterized in that the reinforcement by installing a steel plate or anchor to the concrete structure or a repair plan is established together to increase the cross-sectional area of the concrete structure.
The method according to claim 1,
In the primer application step (S40),
Epoxy or acrylic primers are used,
The primer is,
Concrete structure repair and reinforcement method, characterized in that applied to the cut surface three to five times as a whole to a thickness of 2-3mm.

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