KR101309612B1 - Composition for cross-section repairment of reinforced concrete structures and repairing method for cross-section of reinforced concrete structures using the same - Google Patents

Abstract

PURPOSE: A cross section repairing composition of steel reinforced concrete structure and a cross section maintaining method thereof are provided to effectively repair corrosive part of the steel reinforced concrete and to prevent additional corrosion of reinforced steel in non-reinforced area near by the reinforced area by using anti-rust adhesive and repairing material with high endurance. CONSTITUTION: A cross section repairing composition of steel reinforced concrete structure comprises 24.84-25.47 wt% of phosphate based adhesion promoter, 15.58-16.32 wt% of diffusion rust preventive, 51.46-51.78 wt% of polymer emulsion and 7.17-7.38 wt% of admixture. The cross section repairing composition of steel reinforced concrete structure comprises 1.62-1.76 wt% of carboxylic based adhesion promoter, 1.04-1.12 wt% of diffusion rust preventive, 7.16-7.45 wt% of ceramic powder, 22.34-23.82 wt% of cement, 3.36-3.54 wt% of redispersible powder resin, 56.33-58.81 wt% of silica, 5.28-5.98 wt% of blending material, 0.27-0.32 wt% of admixture and 0.07-0.13 wt% of reinforcing fiber. [Reference numerals] (AA) Start; (BB) Remove damaged concrete; (CC) Remove corrosion of reinforced steel; (DD) Clean the surface of concrete and reinforced steel; (EE) Spray steel diffusion rust preventive; (FF) Spray diffusion rust binder; (GG) Spray reinforcing agent with high durability; (HH) Surface preventive complete coating; (II) End

Description

Composition for cross-section repairment of reinforced concrete structures and repairing method for cross-section of reinforced concrete structures using the same

The present invention relates to a cross-sectional repair composition for reinforced concrete structures and to a cross-sectional repair method for reinforced concrete structures using the same.

In general, reinforced concrete structures have been recognized to be used semi-permanently because they have high durability. However, many recent studies and investigations of existing structures show that deterioration of reinforced concrete structures is inevitable. ought. In particular, it is often reported that after the construction of the structure no longer than a few decades, the original function is lost.

In addition, the reinforced concrete structure is cracked due to the falling tensile stress of the concrete.If the crack width is greater than a certain limit, the surrounding air and moisture invade the cracked area and corrode the steel, and the infiltrated water freeze-expands in winter. May be damaged.

In addition, concrete is cracked due to drying shrinkage, temperature change, etc., and the neutralization of concrete in the cracked part and surface of the structure is promoted, and the deterioration phenomenon occurs in the concrete part of the structure, resulting in peeling and peeling of the surface of the structure. There was a problem showing.

Particularly, in the case of concrete without defects, the pH is about 12.5, so the rebar is formed with a passivation film having a thickness of 20-60 Å to prevent corrosion of the rebar. However, when carbon dioxide penetrates from the outside, alkaline calcium hydroxide, which is a hydration product of concrete, reacts to form neutral calcium carbonate, and the carbonation proceeds to a pH lower than 10. As a result, the passivation film on the surface of the reinforcing steel bars protecting the reinforcing bars increases permeability, and electrochemical corrosion proceeds when exposed to oxygen and moisture. In addition, corrosion of reinforcing bars is accelerated and increased by the destruction of the passivation film on the surface when chlorine ions are present, and the pH of concrete is further lowered, resulting in higher permeability of the passivation film on the surface of the rebar. You will be eliminated.

As a solution to this damage, conventionally repaired by removing the damaged concrete due to corrosion of the reinforcing bars by chlorine ions. This prevented the anodic reaction in which the reinforcing bars were corroded and repaired the cross section with a repair material. Because it was difficult to remove all the chlorine ions, it was difficult to prevent the reinforcing bars in the corrosion even after the cross section recovery. There was a problem that continued pay followed.

In addition, when corrosion of the rebar is advanced, there is a problem that a ring anode phenomenon occurs at the boundary area between the repaired portion and the non-repaired portion of the rebar even after the repair. The ring anode phenomenon is a phenomenon in which corrosion occurs from the repair site to the non-repair site due to the difference in the concentration of chlorine ions, and transitions from the cathode reaction in which corrosion does not occur to the anode reaction in which corrosion occurs.

In order to solve this problem, conventionally, a sacrificial cathode material including zinc or zinc alloy was adopted to paint reinforcement steel as a coating material or to assemble the structure to connect reinforcing steel bars. However, these methods also have a problem in that the use of a small amount of sacrificial cathode material is ineffective, followed by additional corrosion, and in the case of using a large amount to prevent this, the cost of repair is excessively increased.

In addition, the prior art Republic of Korea Patent No. 10-1104812 (Patent Document 1) relates to a method for repairing the cross-section of the reinforced concrete structure, penetration diffusion diffusion corrosion control material in the cross section of the reinforced concrete structure whose performance is degraded due to external environmental factors And to repair and repair using a high strength corrosion-resistant repair material. However, in the patent document 1, the penetration diffusion corrosion control material has an effect of suppressing the corrosion of the reinforcing steel, but it has to wait a long time until the penetration diffusion corrosion control material is cured, and in the case of concrete having a small pore size and a small number After the presence of the residue on the concrete surface was irregular surface and there was a problem that the adhesive strength between the concrete and the primer is weak.

In addition, the conventional repair methods are made by applying the anti-corrosive material only to the reinforcing bars subjected to corrosion, there was a problem that can not prevent the ring anode phenomenon that the reinforcing bars of the non-repaired parts that are not repaired and applied are corroded.

In addition, since conventional repair materials for end face recovery are used with an emphasis on strength, the problem of durability is neglected. Therefore, the resistance to infiltration of carbon dioxide and chlorine ions, which are corrosive factors of reinforcing bars, depends on the pore filling formed by the siliceous pozzolanic reaction or the film formed by the incorporated polymer. The physical solution by the voids or membranes thus formed lacked the ability to block harmful substances that cause corrosion. In particular, in the case of repairing materials for single-sided recovery, which are blocked by the film formed by the polymer, the thermal behavior of the existing concrete is different because a large amount of polymer is used. There was a problem to drop out.

Patent Document 1. Republic of Korea Patent No. 10-1104812

The present invention has been made to solve the above problems, the object of the present invention is to repair the eroded parts of the reinforced concrete structure, at the same time to prevent new corrosion of the non-repair site reinforcing bars adjacent to the repair site, and The present invention provides a cross-sectional repair composition for reinforced concrete structures that prevents ring anodes from occurring at the boundary between exposed rebars of the repair site and unexposed rebar boundaries.

Anti-corrosive adhesive composition used for the cross-sectional repair of reinforced concrete structures according to one feature of the present invention for solving the above problems is phosphate-based adhesion promoter 24.84-25.47% by weight, diffusion rust inhibitor 15.58-16.32% by weight, polymer emulsion 51.46- 51.78 weight% and 7.17-7.38 weight% admixture.

The composition for high durability repair materials used in repairing the cross section of reinforced concrete structures according to another aspect of the present invention is 1.62-1.76 wt% of carboxylic acid adhesion promoter, 1.04-1.12 wt% of diffusion rust inhibitor, 7.16-7.45 wt% of ceramic powder, 22.34-23.82 weight percent cement, 3.36-3.54 weight percent remulsifying powder resin, 56.33-58.81 weight percent silica sand, 5.28-5.98 weight percent admixture, 0.27-0.32 weight percent admixture, and 0.07-0.13 weight percent reinforcing fiber.

Section repair method of the reinforced concrete structure according to another feature of the present invention

In the method of repairing the cross section of a reinforced concrete structure in which rebar is corroded,

1) removing the damaged concrete;

2) cleaning the removed concrete surface and the surface of the rebar being exposed by removing the concrete;

3) applying a reinforcing bar rust inhibitor to the surface of the cleaned reinforcing bar;

4) applying a rust preventive adhesive on the cleaned concrete surface and the surface of the reinforcing steel is coated with a reinforcing bar rust inhibitor;

5) after applying the anti-rust adhesive, repairing the concrete portion removed by a high durability repair material; And

6) coating the surface exposed to the outside of the structure of the repaired site with a surface protective material;

/ RTI >

The rust preventive adhesive comprises 24.84-25.47% by weight of phosphate adhesion promoter, 15.58-16.32% by weight of diffusion rust inhibitor, 51.46-51.78% by weight of polymer emulsion and 7.17-7.38% by weight of admixture,

The high durability repair material is 1.62-1.76% by weight carboxylic acid adhesion promoter, 1.04-1.12% by weight diffusion rust inhibitor, 7.16-7.45% by weight ceramic powder, 22.34-23.82% by weight cement, 3.36-3.54% by weight re-emulsified powder resin 56.33-58.81 wt%, 5.28-5.98 wt% admixture, 0.27-0.32 wt% admixture, and 0.07-0.13 wt% reinforcing fiber.

Section repair method of the reinforced concrete structure according to another feature of the present invention

In the method of repairing the cross section of a reinforced concrete structure in which the concrete is peeled and peeled off,

1) removing the damaged concrete;

2) cleaning the surface of the removed concrete;

3) applying an antirust adhesive to the cleaned concrete surface;

4) after applying the anti-rust adhesive, repairing the concrete portion removed by a high durability repair material; And

5) coating a surface exposed to the outside of the structure of the repaired site with a surface protective material;

/ RTI >

The rust preventive adhesive comprises 24.84-25.47% by weight of phosphate adhesion promoter, 15.58-16.32% by weight of diffusion rust inhibitor, 51.46-51.78% by weight of polymer emulsion and 7.17-7.38% by weight of admixture,

The high durability repair material is 1.62-1.76% by weight carboxylic acid adhesion promoter, 1.04-1.12% by weight diffusion rust inhibitor, 7.16-7.45% by weight ceramic powder, 22.34-23.82% by weight cement, 3.36-3.54% by weight re-emulsified powder resin 56.33-58.81 wt%, 5.28-5.98 wt% admixture, 0.27-0.32 wt% admixture, and 0.07-0.13 wt% reinforcing fiber.

In addition, the diffusion rust preventive agent 5-amino-N-acetyltryptamine (5-Amino-N-acetyltryptamine), 5-aminovaleric acid (5-Aminovaleric acid), 4-aminonicotinic acid (4-Aminonicotinic acid), 4-amino It is characterized in that any one selected from the group consisting of phenylalanine (4-Aminophenylalanine) and mixtures thereof.

In addition, the phosphate-based adhesion promoter is dimethacryloyloxy ethyl hydrogen phosphate, methacryloyloxy ethyl dihydrogen phosphate, and diacryloyloxy ethyl hydrogen phosphate. phosphate), acryloyloxy ethyl dihydrogen phosphate, and a mixture thereof.

In addition, the polymer emulsion is composed of an acrylic (Acryl) emulsion, an acrylic-styrene (Eryl-Styrene) emulsion, an ethylene vinyl acetate (Ethylene vinyl acetate) emulsion, an acrylic-Ethylene vinyl acetate emulsion and a mixture thereof It is characterized in that any one selected from the group.

In addition, the carboxylic acid-based adhesion promoter is acrylic acid succinate (Acryloyloxy ethyl acid succinate), acrylic acid phthalate (Acryloyloxy ethyl acid phthalate), acrylic acid phthalate (Acryloyloxy propyl acid phthalate), acrylic Acryloyloxy ethyl acid methylphthalate, Acryloyloxy butyl acid phthalate, and a mixture thereof.

In addition, the ceramic powder is characterized in that any one selected from the group consisting of aluminum nitride, silicon nitride, zirconium oxide and mixtures thereof.

In addition, the cement is any one selected from the group consisting of Portland cement, fly ash cement, silica fume cement, blast furnace slag cement, and mixtures thereof,

The re-emulsified powder resin is an acryl powder, acryl-styrene powder, ethylene vinyl acetate powder, acryl-ethylene vinyl acetate powder, and mixtures thereof. Any one selected from the group consisting of,

The silica sand is characterized in that 20 ~ 80mesh,

The admixture is any one selected from the group consisting of high strength silica fume, fly ash, metakaolin, blast furnace slag powder, slaked lime, expanded material and mixtures thereof, which are inorganic minerals,

The admixture is any one selected from the group consisting of high performance sensitizers, AE sensitizers, glidants, thickeners, waterproofing agents, coagulation accelerators, coagulation retardants, antifoaming agents and mixtures thereof,

The reinforcing fiber is made of steel fiber, polypropylene fiber, polyethylene fiber, polyethylene terephthalate fiber, polyvinyl alcohol fiber and mixtures thereof It is characterized in that it is any one selected from the group.

In addition, the surface protective material is characterized in that any one selected from the group consisting of acrylic, epoxy, urethane, urea and mixtures thereof.

The cross-sectional repair composition of the reinforced concrete structure according to the present invention and the cross-sectional repair method using the same can effectively repair the cross-section of the reinforced concrete structure subjected to corrosion by carbon dioxide or chlorine ions, and also the corrosion is not progressed and the repair is not performed. It has the effect of preventing additional corrosion on the rebar of unrepaired areas. It also has the effect of preventing ring anodes that frequently occur at reinforcing bar boundaries in adjacent non-repaired areas.

1 is a diagram illustrating the process of Example 1.
2 is a view showing a cross section of the specimen according to Example 1.
3 is a diagram schematically illustrating a process of Example 2. FIG.
4 is a view showing a cross section of the specimen according to Example 2.
5 is a graph showing the results of measuring the adhesive strength of each specimen according to Experimental Example 1.
6 is a graph showing the measurement results of the bending strength of each specimen according to Experimental Example 2.
7 is a graph showing a result of measuring the compressive strength of each specimen according to Experimental Example 3.
8 is a graph showing the results of measuring the coefficient of thermal expansion of each specimen according to Experimental Example 4.
9 is a graph showing the results of the evaluation of the neutralization resistance of each specimen according to Experimental Example 5.
10 is a graph showing the results of evaluation of chloride ion penetration resistance of each specimen according to Experimental Example 6. FIG.
11 is a graph showing the evaluation results of the reinforcement corrosion inhibition of each specimen according to Experimental Example 7.

Therefore, the present inventors repair the reinforced concrete structure undergoing corrosion, while preventing the ring anode phenomenon occurring at the boundary between the repaired and non-repaired parts of the reinforcing bar, the composition for repairing the cross section of the reinforced concrete structure and the cross section of the reinforced concrete structure using the same As a result of earnest research efforts to develop a repair method, the present invention has been found by discovering a composition for repairing a cross section of a reinforced concrete structure and a method for repairing a cross section using the same.

Reinforcing bars are installed as the support and frame of the structure when constructing the reinforced concrete structure, and the concrete is poured by using these reinforcing bars as the skeleton. Thus, the rebar is placed inside the concrete.

Meanwhile, carbonation of the reinforced concrete structure by carbon dioxide proceeds according to Scheme 1 below, and corrosion of the reinforcing bars based on chlorine ions proceeds according to Scheme 2 below.

[Reaction Scheme 1]

[Reaction Scheme 2]

When carbon dioxide penetrates into concrete, a reaction as in Scheme 1 proceeds. Specifically, alkaline calcium hydroxide as a hydration product is reacted as in Scheme 1 to form neutral calcium carbonate, and the carbonation is lowered to about 10 or less. As a result, the passivation film on the surface of the reinforcing bar increases permeability, and oxygen and moisture come into contact with each other, thereby causing electrochemical corrosion.

In addition, the corrosion of the reinforcing bars by chlorine ions is corroded by the reaction as shown in Scheme 2, specifically, when chlorine ions are present, the passivation film on the surface of the reinforcing bars is destroyed, so that the corrosion proceeds quickly, and the pH of the concrete is further lowered and thus reinforced. The permeability of the passivation film on the surface of the rebar is increased. Thus, the internal expansion of the oxide due to corrosion causes an expansion pressure of about 50 N / mm 2, resulting in a crack in the reinforced concrete structure, resulting in the dropping or damage of the cross section. The present invention provides a composition for repairing a cross section of a reinforced concrete structure damaged in cross section and a method for repairing a cross section of a reinforced concrete structure using the same, and also relates to preventing further corrosion of non-repaired reinforcing bars adjacent to the repair site. In addition, the present invention relates to preventing a ring anode phenomenon of reinforcing bars, which is a phenomenon in which corrosion of the reinforcing bar is repaired from the repairing part of the reinforcing bar to the non-repairing part due to a difference in the concentration of chlorine ions, and transitions from the cathode reaction to the anode reaction.

The composition for the rust preventive adhesive used for the cross-sectional repair of the reinforced concrete structure according to one aspect of the present invention is preferably 24.84-25.47 wt% of phosphate-based adhesion promoter, 15.58-16.32 wt% of diffusion rust inhibitor, 51.46-51.78 wt% of polymer emulsion, and 7.17-7.38 weight percent of admixtures.

The anti-corrosive adhesive composition forms a passivation oxide film as a protective coating on the surface of the reinforcing bar exposed as reinforcing bar of the repair site and at the same time passivates the reinforcing bar not exposed as a non-repair site reinforcing bar adjacent to the repair site. It forms an oxide film. This can prevent further corrosion of the non-repaired rebar as well as the rebar of the repaired site. In addition, it is possible to prevent the ring anode phenomenon occurring at the boundary between exposed rebar of the repair site and unexposed rebar of the non-repair site. In addition, the antirust adhesive composition has an effect of achieving excellent adhesion between the concrete and the composition for high durability repair materials according to the present invention.

The anti-corrosive adhesive composition is 24.84-25.47% by weight of phosphate adhesion promoter, 15.58-16.32% by weight of diffusion rust inhibitor, 51.46-51.78% by weight of polymer emulsion and 7.17-7.38% by weight of admixture to prevent corrosion of ring reinforcement and ring anode phenomenon. It can be effectively prevented, and it is preferable because the adhesive strength is better achieved than the composition for the cross-sectional repair of the existing reinforced concrete structure.

The phosphate-based adhesion enhancer is to improve adhesion between concrete and high durability repair materials or concrete and surface protection materials, such as dimethacryloyloxy ethyl hydrogen phosphate, and methacryloyloxy ethyl phosphate. It is preferably any one selected from the group consisting of dihydrogen phosphate, Diacryloyloxy ethyl hydrogen phosphate, Acryloyloxy ethyl dihydrogen phosphate, and mixtures thereof. The phosphate-based adhesion promoter prevents the phenomenon that the repair material is easily detached after repair due to the weak adhesion between the repair material and the concrete due to the residue present on the surface of the repair site in the existing section repair method of the existing reinforced concrete structure. In addition, such a phosphate-based adhesion promoter has a shortening the curing time has an effect of significantly shortening the working time.

In addition, when the phosphate-based adhesion promoter is less than 24.84% by weight, the adhesion between concrete and high durability repair materials is insufficient, and when it exceeds 25.47% by weight, the workability of the rust-preventive adhesive is lowered, so that the mixing ratio is preferably 24.84-25.47% by weight. .

The diffusion rust inhibitor is to form a protective coating on the surface of the reinforcement of the exposed repair site and the unexposed rebar surface of the non-repair site adjacent thereto, and to fix the internal salt and the proportional salt, and 5-amino-N-acetyltrytamine (5-Amino-N-acetyltryptamine), 5-Aminovaleric acid, 4-Aminoonicotinic acid, 4-Aminophenylalanine, and mixtures thereof It is preferably any one selected. Such diffusion rust preventives prevent corrosion of rebar in exposed areas and at the same time prevent corrosion of unexposed rebar in unrepaired areas. In addition, the ring anode phenomenon can be prevented from occurring.

In addition, when the diffusion rust inhibitor is less than 15.58% by weight, the protective film formation and the intrinsic salt and proportional salt fixing performance are insufficient on the surface of the reinforcing steel, and when the diffusion rusting agent exceeds 16.32% by weight, irregular cracking occurs due to abnormal condensation of the rust preventive adhesive. It is preferable to set it as 15.58-16.32 weight%.

The polymer emulsion is to enhance the watertightness and airtightness of the rust-preventive adhesive, acrylic (Acryl) emulsion, acrylic-styrene (Eryl-Styrene) emulsion, ethylene vinyl acetate (Ethylene vinyl acetate) emulsion, acryl- ethylene vinyl acetate (Acryl- Ethylene vinyl acetate) emulsion and mixtures thereof are preferably any one selected from the group consisting of.

In addition, when the polymer emulsion is less than 51.46% by weight, the porous rustproof adhesive becomes porous, and when the polymer emulsion exceeds 51.78% by weight, the flowability of the rustproof adhesive increases and the workability is lowered, so that the blending ratio is preferably 51.46-51.78% by weight.

The admixture is to improve the physical properties and workability of the rust preventive adhesive and to adjust the curing time, and is selected from the group consisting of high performance sensitizers, AE sensitizers, glidants, thickeners, waterproofing agents, coagulants, coagulation delay agents, antifoaming agents and mixtures thereof. It is preferable that it is at least one.

In addition, when the admixture is less than 7.17% by weight, the effect of improving the properties of the rust-preventing adhesive is insufficient, and when it exceeds 7.38% by weight, the quality decreases due to abnormal coagulation of the rust-preventing adhesive, so that the blending ratio is preferably 7.17-7.38% by weight. Do.

The composition for high durability repair materials used for repairing the cross section of reinforced concrete structures according to another aspect of the present invention is preferably 1.62-1.76 wt% of carboxylic acid adhesion promoter, 1.04-1.12 wt% of diffusion rust inhibitor, and ceramic powder 7.16-7.45 Weight%, cement 22.34-23.82 weight%, re-emulsified powder resin 3.36-3.54 weight%, silica sand 56.33-58.81 weight%, admixture 5.28-5.98 weight%, admixture 0.27-0.32 weight% and reinforcing fiber 0.07-0.13 weight% do.

The composition for high durability repairing material is for repairing concrete parts whose sections are dropped or removed by section repair. That is, the high durability repair material composition is replaced with the removed concrete and is installed in the reinforced concrete structure is used as a high durability repair material. The composition for high durability repair materials used for repairing the cross-section of reinforced concrete structures according to the present invention is different from the existing repair repair materials for cross-section repair, while preventing corrosion of reinforcing bars by physical methods as well as chemical methods of film formation. The adhesive force with the composition for antirust adhesives which concerns on this invention can be achieved outstanding. That is, the diffusion rust prevents the internal salt and the proportional salt to prevent further corrosion of the reinforced concrete structure. In addition, the chemical powder and thermal shock resistance is largely stabilized by the ceramic powder to maintain the chemically stable state so that the state of the reinforced concrete structure can be stably maintained after repair.

The composition for high durability repair materials is 1.62-1.76 wt% carboxylic acid adhesion promoter, 1.04-1.12 wt% diffusion rust inhibitor, 7.16-7.45 wt% ceramic powder, 22.34-23.82 wt% cement, 3.36-3.54 wt% reemulsified powder resin , Consisting of 56.33-58.81% by weight of silica, 5.28-5.98% by weight of admixture, 0.27-0.32% by weight of admixture, and 0.07-0.13% by weight of reinforcing fiber, excellent adhesion to concrete and excellent chemical resistance and thermal shock stability It is preferable to maintain the state of the repair material stably after a long time.

The carboxylic acid-based adhesion promoter is to enhance the adhesion of the composition for high durability repair materials, acrylic acid succinate (Acryloyloxy ethyl acid succinate), acrylic acid phthalate (Acryloyloxy ethyl acid phthalate), acrylic acid It is preferably one selected from the group consisting of Acryloyloxy propyl acid phthalate, Acryloyloxy ethyl acid methylphthalate, Acryloyloxy butyl acid phthalate and mixtures thereof. Do.

In addition, if the carboxylic acid-based adhesion enhancer is less than 1.62% by weight, the adhesive strength of the composition for high durability repair material is insufficient, and if it exceeds 1.76% by weight, the composition for high durability repair material is applied by a manpower or spraying equipment and then finish plastering When workability becomes poor, it is preferable to make the compounding ratio 1.62-1.76 weight%.

The diffusion rust inhibitor is for fixing the internal salt and the proportional salt, if the diffusion rust preventive agent in the composition for the high durability repair material is less than 1.04% by weight of the existing internal salt and proportional salt fixed performance is insufficient, and exceeds 1.12% by weight Irregular cracks are generated by abnormal condensation of the composition for high durability water-retaining materials, so that the blending ratio is preferably 1.04-1.12 wt%.

The ceramic powder is intended to enhance the chemical resistance and thermal shock resistance of the composition for high durability repair materials and to make the coefficient of thermal expansion of the composition for high durability repair materials similar to concrete, and the size of the ceramic powder is not limited, but the powder degree is approximately 7,000- It is preferably any one selected from the group consisting of aluminum nitride, silicon nitride, zirconium oxide and mixtures thereof of 9,000 cm 2 / g.

In addition, when the ceramic powder is less than 7.16% by weight, the composition for high durability repairing materials has a low resistance to acid, alkali, and thermal shock, and the coefficient of thermal expansion increases, so that the long-term adhesion to concrete is lowered. Since the fluidity | liquidity of the composition for water-retaining materials falls, and workability becomes poor, it is preferable to make the compounding ratio into 7.16-7.45 weight%.

The cement serves as a binder in the composition for high durability repair materials and to enhance the strength of the composition for high durability repair materials, and is selected from the group consisting of portland cement, fly ash cement, silica fume cement, blast furnace slag cement, and mixtures thereof. It is preferable that it is either.

In addition, when the cement is less than 22.34% by weight, the strength of the high durability repair material is not sufficiently expressed. When the cement is more than 23.82% by weight, excessive heat of reaction is generated during the hydration reaction of the cement, so that a wide crack occurs on the surface of the repair material after repair. It is preferable to make compounding ratio 22.34-23.82 weight%.

The re-emulsified powder resin is to firmly bind the hydrate and silica sand produced by the hydration reaction of cement and to form an elastic band between the hydrates to improve the watertightness and airtightness of the composition for high durability repair materials and to suppress the expansion of microcracks It is selected from the group consisting of acryl powder, acryl-styrene powder, ethylene vinyl acetate powder, acryl- ethylene vinyl acetate powder, and mixtures thereof. It is preferable that it is either.

In addition, when the re-emulsified powder resin is less than 3.36% by weight, material separation occurs in the composition for high durability repair materials, and the watertightness, airtightness, and suppression of microcracks expansion of the composition for high durability repair materials are lowered. Since the reaction is hindered and excessive bubbles are generated to lower the strength of the high durability water-retaining material, the mixing ratio is preferably 3.36-3.54 wt%.

The silica sand is to increase the strength of the composition for high durability repair materials and to suppress the expansion of cracks, preferably 20 to 80 mesh.

In addition, when the silica sand is less than 56.33% by weight, the manufacturing cost of the composition for high durability repair materials is high, and economic efficiency is lowered, and the amount of mixed water is increased, so that the drying shrinkage of the composition for high durability repair materials increases, and when it exceeds 58.81% by weight, When applying the cross section with the equipment, the dropping rate of the composition for high durability repair material is generated a lot, and the recovered cross section is rough, so that the subsequent surface protective material finish coating is difficult, it is preferable that the compounding ratio is 56.33-58.81% by weight.

The admixture is to enhance the strength and durability of the highly durable repairing material, and is preferably any one selected from the group consisting of inorganic minerals such as high strength silica fume, fly ash, metakaolin, blast furnace slag powder, slaked lime and expanded material, and mixtures thereof. Do.

In addition, when the admixture is less than 5.28% by weight, the effect of enhancing strength and durability is lowered. When the admixture is more than 5.58%, the quality is lowered beyond the condensation of the composition for high durability repairing materials, so the blending ratio is preferably 5.28-5.58% by weight. .

The admixture is to improve the workability and durability of the composition for high durability repair materials and to control the curing time, and comprises a high performance water reducing agent, an AE water reducing agent, a fluidizing agent, a thickener, a waterproofing agent, a coagulant, a coagulant delaying agent, an antifoaming agent, and mixtures thereof. It is preferably any one selected from the group.

In addition, when the admixture is less than 1.33% by weight, less than 0.27% by weight, the effect of improving the properties of the composition for high durability repair materials is lowered. When the amount of the admixture is more than 0.32% by weight, the strength of the high durability repair materials is lowered and the fluidity is excessively increased and the quality is increased. Since it falls, it is preferable to make the compounding ratio into 0.27-0.32 weight%.

The reinforcing fiber increases the tensile strength and the bending strength of the high-durability repairing material and suppresses the expansion of the microcracks, as well as dissociating the dissociated moisture present in the concrete in the event of a fire to prevent the thermal expansion phenomenon due to water vapor pressure. Steel fiber, Polypropylene fiber, Polyethylene fiber, Polyethylene terephthalate fiber, Polyvinyl alcohol fiber and mixtures thereof It is preferable to be one.

In addition, when the reinforcing fiber is less than 0.07% by weight, the tensile strength and the bending strength of the high durability repairing material are reduced after repair, and the performance of inhibiting the expansion of the microcracks is degraded. Ball phenomenon occurs, and the nozzle of the spray is clogged, which causes difficulties in construction. Therefore, the mixing ratio is preferably 0.07-0.13% by weight.

Section repair method of the reinforced concrete structure corrosion-resistant rebar according to another aspect of the present invention

In the method of repairing the cross section of a reinforced concrete structure in which rebar is corroded,

1) removing the damaged concrete;

2) cleaning the removed concrete surface and the surface of the rebar being exposed by removing the concrete;

3) applying a reinforcing bar rust inhibitor to the surface of the cleaned reinforcing bar;

4) applying a rust preventive adhesive on the cleaned concrete surface and the surface of the reinforcing steel is coated with a reinforcing bar rust inhibitor;

5) after applying the anti-rust adhesive, repairing the concrete portion removed by a high durability repair material; And

6) coating the surface exposed to the outside of the structure of the repaired site with a surface protective material;

/ RTI >

The rust preventive adhesive comprises 24.84-25.47% by weight of phosphate adhesion promoter, 15.58-16.32% by weight of diffusion rust inhibitor, 51.46-51.78% by weight of polymer emulsion and 7.17-7.38% by weight of admixture,

The high durability repair material is 1.62-1.76% by weight carboxylic acid adhesion promoter, 1.04-1.12% by weight diffusion rust inhibitor, 7.16-7.45% by weight ceramic powder, 22.34-23.82% by weight cement, 3.36-3.54% by weight re-emulsified powder resin 56.33-58.81 wt%, 5.28-5.98 wt% admixture, 0.27-0.32 wt% admixture, and 0.07-0.13 wt% reinforcing fiber.

Step 1) is a step of removing the damaged concrete, the method of removal is not particularly limited as long as it can remove the damaged concrete can be applied to all, preferably in the field conditions suitable for attraction chipping or sandblaster , Waterjet, rock drill and other suitable methods.

In the cleaning of step 2), the concrete surface removes residues on the surface, and the rebar surface cleaning removes rust present on the surface, and they are cleaned by wire brush, water jet, water sand jet, and other suitable methods. Cleaning will remove rust. In particular, it is necessary to remove foreign substances such as dust and oil that prevent the adhesion between the concrete surface and the reinforcement surface by appropriate methods such as water jet or vacuum inhaler. desirable. In addition, if the rebar is found to be severely corroded after removing the rust of the exposed rebar by removing the concrete, and there is a need to increase the load capacity due to the change in the use of the reinforced concrete structure, the new rebar or fiber rod, etc. Reinforcement can be installed to reinforce reinforced concrete structures.

The step of applying the reinforcing bar rust preventive of step 3) is to prevent corrosion of the exposed reinforcing bar is preferably performed using a brush, a roller or a spray, it is preferable to apply evenly to the back of the reinforcing bar.

The step of applying the anti-rust adhesive of step 4) is to form a passivation oxide film as a protective film on the surface of the reinforcing bar exposed as the reinforcing bar of the repair site and to expose it as the non-repair site reinforcing bar adjacent to the repair site. Passive oxide films are also formed on unreinforced rebar. This can prevent additional corrosion of the rebar in the non-repair site as well as the rebar in the repair site, thereby preventing the ring anode phenomenon.

The rust preventive adhesive is 24.84-25.47% by weight of the phosphate-based adhesion promoter, 15.58-16.32% by weight of the diffusion rust inhibitor, 51.46-51.78% by weight of the polymer emulsion and 7.17-7.38% by weight of admixtures effectively prevent the corrosion of the reinforcing bar and ring anode phenomenon It is preferable to be able to do it, and also excellent adhesion than the composition for the cross-sectional repair of the existing reinforced concrete structure is preferable.

Step 5) is a step of repairing the concrete part removed by the high durability repair material or removed by the step 1). That is, the high durability repair material is installed in the reinforced concrete structure while being newly filled by replacing the removed concrete.

The high durability repair material is 1.62-1.76% by weight carboxylic acid adhesion promoter, 1.04-1.12% by weight diffusion rust inhibitor, 7.16-7.45% by weight ceramic powder, 22.34-23.82% by weight cement, 3.36-3.54% by weight re-emulsified powder resin 56.33-58.81% by weight, 5.28-5.98% by weight of admixtures, 0.27-0.32% by weight of admixtures and 0.07-0.13% by weight of reinforcing fibers. Unlike the conventional repair material for repairing the end face, the highly durable repair material can achieve excellent adhesion with the rust preventive adhesive material while preventing corrosion of concrete and reinforcing bars by a chemical method as well as a physical method of film formation. That is, the diffusion rust prevents the internal salt and the proportional salt to prevent further corrosion of the reinforced concrete structure. In addition, the chemical powder and thermal shock resistance is largely stabilized by the ceramic powder to maintain the chemically stable state so that the state of the reinforced concrete structure can be stably maintained after repair.

The surface protective material is not particularly limited as long as it can finish the external exposed surface of the reinforced concrete structure, but is preferably any one selected from the group consisting of acrylic, epoxy, urethane, urea and mixtures thereof.

When repairing the cross section of the reinforced concrete structure using the method for repairing the cross section of the reinforced concrete structure according to the present invention, the reinforcing steel exposed by the dropout of the concrete and the concrete is not dropped off to prevent corrosion of the unreinforced rebar. In addition, there is an effect of preventing the ring anode phenomenon occurring at the reinforcing bar boundary of the non-repair area adjacent to the reinforcing bar of the repair site. In addition, there was a phenomenon that the adhesion between the concrete and the primer was weakened due to the presence of residue due to the corrosion control agent, which was treated to prevent corrosion on the surface exposed to the repair site by removing the corroded concrete in the section repair method of the existing reinforced concrete structure. By resolving the problem, the adhesive strength is improved so that the repair site does not fall off the reinforced concrete structure even after repair.

Section repair method of the reinforced concrete structure according to another feature of the present invention

In the method of repairing the cross section of a reinforced concrete structure in which the concrete is peeled and peeled off,

1) removing the damaged concrete;

2) cleaning the surface of the removed concrete;

3) applying an antirust adhesive to the cleaned concrete surface;

4) after applying the anti-rust adhesive, repairing the concrete portion removed by a high durability repair material;

5) coating a surface exposed to the outside of the structure of the repaired site with a surface protective material;

/ RTI >

The rust preventive adhesive comprises 24.84-25.47% by weight of phosphate adhesion promoter, 15.58-16.32% by weight of diffusion rust inhibitor, 51.46-51.78% by weight of polymer emulsion and 7.17-7.38% by weight of admixture,

The high durability repair material is 1.62-1.76% by weight carboxylic acid adhesion promoter, 1.04-1.12% by weight diffusion rust inhibitor, 7.16-7.45% by weight ceramic powder, 22.34-23.82% by weight cement, 3.36-3.54% by weight re-emulsified powder resin 56.33-58.81 wt%, 5.28-5.98 wt% admixture, 0.27-0.32 wt% admixture, and 0.07-0.13 wt% reinforcing fiber.

The method for repairing the cross section of the reinforced concrete structure in which the concrete is peeled and peeled off according to the present invention is not only for repairing the concrete of the peeled and peeled reinforced concrete structure, but also has an effect of preventing corrosion from occurring in the reinforcing steel reinforcement existing in the concrete. Do.

In addition, the cross-sectional repair method for the reinforced concrete structure in which the concrete is peeled and peeled off according to the present invention is to repair the damaged concrete section so that the reinforcing bars are not corroded and the reinforcing bars are not exposed. Unlike the method, it is not necessary to clean the rebar such as removing rust of the rebar. Other processes, compositions and composition ratios are the same as described above in the method for repairing the cross section of the reinforced concrete structure in which the reinforcing steel is corroded according to another feature of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

Example

Example  One

Reinforced concrete specimens (25.4 × 25.4 × 285.75 mm) prepared by corrosion of about 30% by exposure to chlorine ions and carbon dioxide were prepared as the compounding ratios shown in Table 1 below. Particularly, concrete is a concrete using one kind of ordinary portland cement. The test mix was designed to achieve a compressive strength of 27 to 30 MPa. The slump is 18 ± 2.5 cm and the maximum size of the coarse aggregate is 25 mm. Polycarboxylic acid-based high performance water reducing agent (SP) was used.

The corroded portions of these reinforced concrete specimens were removed using attraction chipping. The removed concrete surface was cleaned with a vacuum inhaler. In addition, the removal of the concrete was cleaned while removing through the molten wire brush present in the exposed rebar.

 Thereafter, an aqueous acrylic rebar rust preventive was applied to the surface of the rebar exposed by the removal of concrete. And an antirust adhesive was applied to the surface of the concrete exposed to the removal site of the concrete and the surface of the reinforcing steel coated with the reinforcing bar rust inhibitor.

The rust preventive adhesive was prepared using 25.22% by weight of dimethacrylooxyethyl hydrogen phosphate, 15.90% by weight of 5-amino valeric acid, 51.60% by weight of acrylic emulsion, 6.76% by weight of polysaccharide thickener and 0.52% by weight of silicone antifoaming agent. It is,

And the removal part was filled with high durability repairing material on the concrete part which was improved by corrosion. At this time, the high-durability repair material is 1.70% by weight of acryloxyethyl phthalate, 1.08% by weight of 5-amino valeric acid, 7.21% by weight of silicon nitride, 23.06% by weight of one ordinary portland cement, 3.46% by weight of acrylic powder, No. 5 (20-30) mesh) 38.45 wt%, No. 6 (30 ~ 60 mesh) 19.23 wt%, high strength silica fume 1.16 wt%, blast furnace slag fine powder 4.25 wt%, polycarboxylic acid-based high performance water reducing agent 0.26 wt%, silicone antifoaming agent 0.03 wt% and polyvinyl alcohol fiber It was prepared using 0.11% by weight. The areas where concrete was removed were filled with high durability repair materials, and then the outer surface of reinforced concrete was coated with a surface protective material to finish.

Meanwhile, FIG. 1 is a diagram illustrating a manufacturing process thereof, and FIG. 2 is a cross-sectional view of the repaired reinforced concrete specimen according to the first embodiment.

Example  2

Reinforced concrete specimens were repaired in the same manner as in Example 1 except that the damaged concrete was removed but the reinforcing bars did not proceed to corrode and the concrete was removed so that the reinforcing bars were not exposed.

Meanwhile, FIG. 3 is a diagram illustrating a manufacturing process thereof, and FIG. 4 is a cross-sectional view of the repaired reinforced concrete specimen according to the second embodiment.

Comparative example

Comparative example  One

Reinforced concrete specimens were repaired using the domestic A company's liquid primer and repair materials.

Comparative example  2

Reinforced concrete specimens were repaired using B primers and water repellents from Korea.

Experimental Example

< Experimental Example  1: Adhesion Strength Evaluation>

Experiment to compare the adhesive strength with Example 1 (PrMo), Comparative Example 1 (A-PrMo) and Comparative Example 2 (B-PrMo). In addition, in Example 1, in order to effectively compare the anti-rust adhesive agent was added to the case of treating only a high durability repair material (Mo). Its experiments were measured according to KS F 4042-2012 “Polymer Cement Mortar for Repairing Concrete Structures”. In addition, the results thereof are shown in FIG. 5.

As shown in Figure 5 Mo after applying the primer of the A company after applying the repair material of Comparative Example 1 (A-PrMo) and B after applying the primer of B company appeared to be equal or more than the comparative example 2 (B-PrMo) with the repair material In addition, Example 1 according to the present invention was much larger than the other test specimens, it was confirmed that both the antirust adhesive and the high durability repairing material according to the present Example 1 in terms of adhesive strength.

< Experimental Example  2: Flexural Strength Evaluation>

In order to evaluate the flexural strength of the high durability repair material according to the present invention was tested according to KS F 4042-2012 "polymer cement mortar for repairing concrete structures", the measurement result is a high durability repair material according to the present invention as shown in Figure 6 It was found that the flexural strength of was higher than that of A's repair material (A-Mo) and B's repair material (B-Mo), indicating excellent flexural strength.

< Experimental Example  3: Evaluation of Compressive Strength>

In order to evaluate the compressive strength of the high durability repairing material according to the present invention, a test specimen was prepared according to KS F 4042-2012 "Polymer cement mortar for repairing concrete structures" and the bending strength was measured. The compressive strength was tested, and the measured result is that the compressive strength of the high durability repairing material (Mo) according to the present invention as shown in Figure 7 is more than the compressive strength of the repairing material (A-Mo) of company A and the repairing material (B-Mo) of B company It was found to be large, indicating that the compressive strength was excellent.

< Experimental Example  4: Evaluation of thermal expansion coefficient>

ASTM D 696 “Standard Test Method for Coefficient of Linear Thermal Expansion of Plastic” and KS F 2424 “After each specimen was cured in air for 28 days to evaluate the thermal expansion coefficient of the rustproof adhesive and the high durability repairing material according to the present invention. The coefficient of thermal expansion was measured by the test method for varying the length of mortar and concrete-a dial gauge method, and the results were obtained by applying the antirust adhesive according to the present invention to all surfaces of the high durability repairing material according to the present invention. The thermal expansion coefficient of the test body (Pr) and the high durability repairing material (Mo) according to the present invention, which was cured for 1 day, was compared to the thermal expansion coefficient of the repairing material (A-Mo) and the repairing material (B-Mo) of Company A (Con). It is very similar to the coefficient of thermal expansion of. On the other hand, generally known thermal expansion coefficient of reinforcing bar is about 12 × 10 ^-6 / ℃.

Thus, it was found that the antirust adhesive and the high durability repairing material according to the present invention can be integrated with concrete as reinforced concrete is established.

< Experimental Example  5: Neutralization Resistance Evaluation>

Each specimen was tested according to KS F 4042-2012 “Polymer Cement Mortar for Concrete Structure Repair” in order to evaluate the resistance to neutralization due to carbon dioxide of the highly durable repair material according to the present invention. The neutralization depth of the high durability repair material (Mo) is much smaller than the neutralization depth of the repair material (A-Mo) of the company A and the repair material (B-Mo) of the company B was found to be excellent in the neutralization resistance performance.

< Experimental Example  6: Chloride Ion Resistance Evaluation>

Each specimen was tested according to KS F 4042-2012 “Polymer Cement Mortar for Repairing Concrete Structures” in order to evaluate the chloride ion penetration resistance of the highly durable repair material according to the present invention. It was determined by the "chlorine ion penetration resistance test method of concrete by electrical conductivity", and the measurement result is the average value of three test specimens excluding the minimum and maximum values of the measured values for the five test specimens as shown in FIG. According to the results, the charge of high durability repair material (Mo) is much smaller than that of A repair material (A-Mo) and B repair material (B-Mo).

< Experimental Example  7: Evaluation of Reinforcing Bar Corrosion>

After repairing the concrete using the antirust adhesive and the high durability repairing material as in Example 1 according to the present invention, a circular steel bar having a diameter of 10 mm to measure the potential of the repairing part and the non-repairing part and the repairing part and the non-repairing part boundary area The cover thickness of one side is 20 mm and embedded in 100 × 70 × 400 mm concrete, forming a space of 100 × 50 × 50 mm in two places inside the surface to expose the round steel bar and One place to the back was coated with a high durability repair material after applying the antirust adhesive according to the present invention and the other one was made a test body coated with only the high durability repair material according to the present invention was cured for 28 days in the atmosphere, the present invention Except for the surface coated with a high durability repair material according to all the surfaces were cured after coating with epoxy.

In the same manner as above, a primer of company A was applied to one space of 100 × 50 × 50 mm, and a primer of company B was applied to one test space of 100 × 50 × 50 mm and a water-retaining material was applied to the test body. A test body was produced.

The test specimens were immersed in about 3.5 mm sodium chloride solution of about 20 mm under the surface coated with the high durability repair material according to the present invention and the repair company A and repair company B, the non-repair site (Con), according to the present invention A repair site (Mo) coated only with a high durability repair material, a repair site (PrMo) to which the antirust adhesive material according to the present invention is applied and a high durability repair material is applied, a site to which a primer of A company is applied and a repair material is applied (A-PrMo), B-PrMo coated with a primer of the company B and the repairing material (B-PrMo), the repairing portion and the non-maintenance boundary (Mo-B) applied only to the high-durability repairing material according to the present invention, the antirust adhesive according to the present invention And the non-maintenance part (PrMo-B) between the repaired part and the non-repaired part, which is coated with high durability repairing material

The natural potential was measured at the boundary area (A-PrMo-B) and the B company's primer and the non-repair area (B-PrMo-B). It was evaluated by ASTM C 876-1991 "Standard Test Method for Half-Cell Potentials of Uncoated Reinforcing Steel in Concrete" as shown in Table 3.

As a result of measuring the natural potential, the repair site (Mo) coated only with the high durability repair material according to the present invention as shown in FIG. 11, the repair site (PrMo) and the present after applying the high durability repair material after applying the antirust adhesive according to the invention In the boundary part (PrMo-B) between the repaired part and the non-repaired part, which is coated with the anti-rust adhesive material according to the present invention, and the non-repairing part, it is within -100 to -200mv, which is the potential in the sound concrete where a passivation film is formed on the surface of the rebar. Therefore, it was found that the corrosion resistance of reinforcing bars was excellent, and when reinforcing concrete structures exposed to rebar by using anti-rust adhesive and high durability repairing materials according to the present invention, new reinforcing steel corrosion at the boundary between repair and non-repair sites Ring Anode does not appear to occur.

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, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It is natural.

Claims (11)

delete delete In the method of repairing the cross section of a reinforced concrete structure in which rebar is corroded,
1) removing the damaged concrete;
2) cleaning the removed concrete surface and the surface of the rebar being exposed by removing the concrete;
3) applying a reinforcing bar rust inhibitor to the surface of the cleaned reinforcing bar;
4) applying a rust preventive adhesive on the cleaned concrete surface and the surface of the reinforcing steel is coated with a reinforcing bar rust inhibitor;
5) after applying the anti-rust adhesive, repairing the concrete portion removed by a high durability repair material; And
6) coating the surface exposed to the outside of the structure of the repaired site with a surface protective material;
Including;
The rust preventive adhesive comprises 24.84-25.47% by weight of phosphate adhesion promoter, 15.58-16.32% by weight of diffusion rust inhibitor, 51.46-51.78% by weight of polymer emulsion and 7.17-7.38% by weight of admixture,
The high durability repair material is 1.62-1.76% by weight carboxylic acid adhesion promoter, 1.04-1.12% by weight diffusion rust inhibitor, 7.16-7.45% by weight ceramic powder, 22.34-23.82% by weight cement, 3.36-3.54% by weight re-emulsified powder resin 56.33-58.81 wt%, 5.28-5.98 wt% admixture, 0.27-0.32 wt% admixture, and 0.07-0.13 wt% reinforcing fiber,
The re-emulsified powder resin is an acryl powder, acryl-styrene powder, ethylene vinyl acetate powder, acryl-ethylene vinyl acetate powder, and mixtures thereof. Any one selected from the group consisting of,
The admixture is any one selected from the group consisting of high strength silica fume, fly ash, metakaolin, blast furnace slag powder, slaked lime, expanded material and mixtures thereof, which are inorganic minerals,
The admixture is any one selected from the group consisting of high performance water reducing agent, AE water reducing agent, fluidizing agent, thickener, waterproofing agent, coagulant accelerator, coagulant delaying agent, antifoaming agent and mixtures thereof.
In the method of repairing the cross section of a reinforced concrete structure in which the concrete is peeled off
1) removing the damaged concrete;
2) cleaning the surface of the removed concrete;
3) applying an antirust adhesive to the cleaned concrete surface;
4) after applying the anti-rust adhesive, repairing the concrete portion removed by a high durability repair material;
5) coating a surface exposed to the outside of the structure of the repaired site with a surface protective material;
Including;
The rust preventive adhesive comprises 24.84-25.47% by weight of phosphate adhesion promoter, 15.58-16.32% by weight of diffusion rust inhibitor, 51.46-51.78% by weight of polymer emulsion and 7.17-7.38% by weight of admixture,
The high durability repair material is 1.62-1.76% by weight carboxylic acid adhesion promoter, 1.04-1.12% by weight diffusion rust inhibitor, 7.16-7.45% by weight ceramic powder, 22.34-23.82% by weight cement, 3.36-3.54% by weight re-emulsified powder resin 56.33-58.81 wt%, 5.28-5.98 wt% admixture, 0.27-0.32 wt% admixture, and 0.07-0.13 wt% reinforcing fiber,
The re-emulsified powder resin is an acryl powder, acryl-styrene powder, ethylene vinyl acetate powder, acryl-ethylene vinyl acetate powder, and mixtures thereof. Any one selected from the group consisting of,
The admixture is any one selected from the group consisting of high strength silica fume, fly ash, metakaolin, blast furnace slag powder, slaked lime, expanded material and mixtures thereof, which are inorganic minerals,
The admixture is any one selected from the group consisting of high performance water reducing agent, AE water reducing agent, fluidizing agent, thickener, waterproofing agent, coagulant accelerator, coagulant delaying agent, antifoaming agent and mixtures thereof.
The method according to claim 3 or 4,
The diffusion rust inhibitor is 5-amino-N-acetyltryptamine, 5-aminovaleric acid, 4-aminonicotinic acid, 4-aminophenylalanine (4-Aminophenylalanine) and a method for repairing the cross section of a reinforced concrete structure, characterized in that any one selected from the group consisting of these.
The method according to claim 3 or 4,
The phosphate adhesion promoters include dimethacryloyloxy ethyl hydrogen phosphate, methacryloyloxy ethyl dihydrogen phosphate, and diacryloyloxy ethyl hydrogen phosphate. ), Acryloyloxy ethyl dihydrogen phosphate (Acryloyloxy ethyl dihydrogen phosphate) and a method for repairing the cross section of a reinforced concrete structure, characterized in that any one selected from the group consisting of.
The method according to claim 3 or 4,
The polymer emulsion is a group consisting of acrylic emulsion, acryl-styrene emulsion, ethylene vinyl acetate emulsion, acryl-ethylene vinyl acetate emulsion, and mixtures thereof. Section repair method of reinforced concrete structure, characterized in that any one selected from.
The method according to claim 3 or 4,
The carboxylic acid adhesion promoter is acrylic acid succinate (Acryloyloxy ethyl acid succinate), acrylic acid phthalate, acrylic acid phthalate (Acryloyloxy propyl acid phthalate), acrylic acid A method for repairing a cross-section of a reinforced concrete structure, characterized in that it is any one selected from the group consisting of ethylcryloyloxy ethyl acid methylphthalate, acryloyloxy butyl acid phthalate, and mixtures thereof.
The method according to claim 3 or 4,
The ceramic powder is any one selected from the group consisting of aluminum nitride, silicon nitride, zirconium oxide and mixtures thereof.
The method according to claim 3 or 4,
The cement is any one selected from the group consisting of portland cement, fly ash cement, silica fume cement, blast furnace slag cement, and mixtures thereof,
The silica sand is characterized in that 20 ~ 80mesh,
The reinforcing fiber is made of steel fiber, polypropylene fiber, polyethylene fiber, polyethylene terephthalate fiber, polyvinyl alcohol fiber and mixtures thereof Section repair method of reinforced concrete structure, characterized in that any one selected from the group.
The method according to claim 3 or 4,
The surface protective material is any one selected from the group consisting of acryl-based, epoxy-based, urethane-based, urea-based and mixtures thereof.

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