KR101172808B1 - Repairing method of concrete structure using fibersheet and pushpin - Google Patents

Abstract

Concrete structures using fibrous sheets and pushpins that can improve the anti-bacterial resistance by improving the seismic performance as well as reinforcing the structures by reinforcing the deteriorated parts of concrete structures with fiber sheets and pushpins, and repairing them with antibacterial mortar. Repair process is disclosed. The disclosed repair method removes the deteriorated concrete part from the concrete structure and then places the perforated fiber sheet on the removed concrete part, inserts a push pin into the perforated hole of the placed perforated fiber sheet, and then pushes the push pin into the concrete structure to form the perforated fiber sheet. It is characterized in that to repair the deteriorated concrete part by fixing the to the concrete surface and then filled with the antibacterial mortar concrete part.

Concrete, Antibacterial, Mortar, Pushpin, Fiber Sheet

Description

Repairing method of concrete structure using fibersheet and pushpin}

The present invention relates to a method for repairing concrete structures using fiber sheets and push pins, and more particularly, by reinforcing deteriorated parts of concrete structures using fiber sheets and push pins, to improve not only reinforcement of structures but also seismic performance. The present invention relates to a method for repairing concrete structures using fiber sheets and pushpins that can improve antibacterial resistance by repairing antibacterial mortar.

In general, concrete is variously and effectively used to construct buildings by mixing cement, sand, and water, or to construct various structures such as roads, bridges, ports, dams, tunnels, and the like. However, such concrete structures may age or corrode depending on the time and atmosphere. For example, in the case of concrete structures installed in sewage facilities, the surface of the concrete structure is neutralized and deteriorated due to the action of sulfated bacteria.

The general method of repairing a deteriorated concrete structure is to remove the deteriorated portion of the concrete structure, and to fill and remove the cement mortar after hardening it, and to repair and repair it. Part of the original structure is difficult to integrate with the phenomenon that often falls off from the structure and this caused a problem that the smooth reinforcement of the structure is not made well.

The present invention has been proposed to improve the above-described problems, the object of which is to reinforce the deteriorated portion of the concrete structure by using a fiber sheet and push pins to improve the seismic performance as well as reinforcement of the structure, repair and construction with antibacterial mortar By providing a method for repairing concrete structures using fiber sheets and pushpins that can improve the antibacterial resistance.

An object of the present invention is to remove the deteriorated concrete part from the concrete structure and then to place the perforated fiber sheet on the removed concrete part, inserting the push pin into the perforated hole of the placed perforated fiber sheet and then push the push pin into the concrete structure perforated fiber It can be achieved by providing a method for repairing a concrete structure using fiber sheets and pushpins, which is characterized by repairing the degraded concrete part by fixing the sheet to the concrete face and then filling the removed concrete part with antibacterial mortar.

The concrete structure repair method using the fiber sheet and the push pin according to the present invention by reinforcing the deteriorated portion of the concrete structure by using the fiber sheet and push pin to improve the seismic performance as well as the reinforcement of the structure, by repairing with antibacterial mortar There is an effect that can improve the antibacterial resistance.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 1 to 3 are views showing in time series the repair method according to the present invention.

Referring to this, the repair method according to the present invention first removes the concrete portion deteriorated by neutralization, etc. in the concrete structure using a drill, as shown in Figure 1 to form a repair space (A). At this time, it is preferable that the fiber sheet 10 to be described later is flattened in the repair space A by flattening the curvature in the repair space A. FIG. In addition, it is preferable to apply a primer to the concrete surface of the repair space (A), if necessary, so that the fiber sheet is fixed to the concrete surface of the repair space.

On the other hand, when the deteriorated concrete portion is removed as described above, as shown in Figure 2, the perforated fiber sheet 10 is disposed in the repair space. Here, it is preferable to use carbon fibers having high tensile strength and high compressive strength in order to reinforce the strength of the deteriorated structure and improve the seismic performance. In addition, the perforated 11 is regularly formed in the fiber sheet, it is preferable that the fiber sheet 10 is uniformly fixed to the concrete surface through the push pin 20 to be described later.

When the perforated fiber sheet 10 is disposed in the repair space A as described above, the push pin 20 is inserted into the perforated part 11 of the perforated fiber sheet arranged as shown in FIG. It is embedded in the structure to fix the perforated fiber sheet to the concrete surface. Here, it is preferable that the toothed concave-convex 21 is formed on the side of the pushpin so as not to fall out after being pushed into the concrete while being easily embedded in the concrete.

As such, the repairing method of the deteriorated concrete part is completed by filling the antimicrobial mortar 30 in the repair space A fixed by the fiber sheet 10 by the push pin 20, as shown in FIG. .

Here, the antimicrobial mortar 30 is used to recycle the recycled fine aggregate aggregate, as well as to inhibit the growth of sulfated bacteria and prevent the production of sulfuric acid by using an inorganic antibacterial agent to prevent corrosion of the concrete structure to extend its life. It is preferable to use cement mortar to make it possible.

For example, the composition (weight%) of the cement mortar used in the present invention is 34-37% Portland cement, 1-8% powdery illite, 1-2% powdery inorganic antibacterial agent, and 0.5-1.0 EVA polymer. %, 3.5-6.5% admixtures; And it is preferable that the balance consists of circulating fine aggregates.

When explaining the reason for the numerical limitation of the antimicrobial mortar component of the present invention having such a composition as follows.

(Portland Cement: 34-37 wt%)

Portland cement is mainly a clinker obtained by mixing calcite and clay raw materials in an appropriate proportion (sometimes adding siliceous and iron oxide raw materials to control the composition) and then pulverizing them until they are molten (about 1,450). It is prepared by adding some gypsum as a coagulation controlling agent and pulverizing it. Such portland cement is suitable for use according to the present invention, namely, maintenance, repair and reinforcement because of its roughness, and is particularly limited to the above range in consideration of the blendability with the circulating fine aggregate and the curing time after the mortar is manufactured.

(Powder illite: 1-8% by weight)

The illite is a fine mica mineral belonging to monoclinic system. The illite is 1 ~ 2, the specific gravity is 2.6 ~ 2.9, and the streak color is white. Calculated in tuff sedimentary rock and produced as altered minerals of hydrothermal deposits, which are mainly SiO ₂ : 55 ~ 80wt%, Al ₂ O ₃ : 5 ~ 30wt%, Fe ₂ O ₃ : 3 ~ 20wt% And, broadly belong to primary clay, and the particle size refers to the assembled mineral. In the present invention, the elite is pulverized and manufactured in the form of a powder having a particle size of 100 to 500 mesh, and then mixed with the Portland cement at a ratio of 1 to 8% by weight, which is air through far infrared rays and anions emitted from the elite. It is to perform the purification function. At this time, the powdered illite has a higher grinding process cost as the particle size is smaller and the adsorption effect of harmful components occurs over a short period of time, so after 10 years or more, the adsorption and anion emission functions are drastically deteriorated. It is particularly preferable to have a size of the above-mentioned particle size because it is long lasting but weak, and the homogeneity of the product is lowered and the air permeability of the mortar is reduced to lower the harmful substance blocking performance. In addition, even if the addition amount is less than 1% by weight, the adsorption effect and the harmful substance blocking effect is sharply lowered, the adhesion strength is also lowered, when added to more than 8% by weight, the strength is lowered, so the addition is limited to the above range desirable.

(Powdered inorganic antibacterial agent: 1-2 wt%)

Antibacterial agents are substances that inhibit or inhibit the growth of bacteria, and are classified into organic and inorganic antibacterial agents. Inorganic antimicrobials are mainly made of silver, zinc, copper, etc., which are metals that have antimicrobial action on inorganic substances such as zeolite, calcium phosphate, zirconium phosphate, silica gel, etc. Since the stability of the human body is high, resistant bacteria do not appear, and the antimicrobial duration is almost semi-permanent, its use area is expanding. In particular, since the inorganic antimicrobial agent must solve the problem of dispersibility when applied to the polymer material, the range that can be applied according to the atomization of particles and the complexation technology with the polymer is expanding. However, the known inorganic antimicrobial agent has a disadvantage in that the cost is increased because it has to be prepared by coating with substitution, support, and nanoparticles. Therefore, in the present invention, in consideration of the aspects of resource recycling while having ease of processing and equivalent effects, by mixing the water-tight material (eg silica, fly ash) with nickel, tungsten obtained as a by-product during metal smelting, grinding to a certain particle size which; Powdered activated carbon mixed with nickel-zinc-tungsten and ground to a predetermined particle size; The salts of the amine acid derivatives are ground to a certain particle size; The salts of the oxyquinoline derivatives are ground to a certain particle size; Grinding the silver supported catalyst, which is a by-product obtained in the production of ethylene oxide, to a certain particle size; Grinding of activated carbon ion-exchanged with silver to a certain particle size is utilized as an inorganic antibacterial agent. At this time, the inorganic antimicrobial agent added according to the present invention inhibits the activity of the sulfated bacteria to block the production of sulfuric acid to inhibit the corrosion of the concrete structure. In particular, in the present invention, in consideration of the dispersion in Portland cement, the above-described inorganic antimicrobial agent is more preferably formed in powder form having a particle size of 20 nm-10, and when it is added below 1% by weight, the antimicrobial effect is sharply decreased. When added in excess of 2% by weight, the adhesion strength of the mortar falls, so it is preferable to limit it to the above range.

(EVA polymer: 0.5-1.0 wt%)

EVA (Ethylene-Vinyl Acetate copolymer) is a generic name for polymer compound made by copolymerization of polyethylene and poly vinylacetate, and it is a thermoplastic material that is more environmentally friendly than conventional polymers such as polystyrene. Has The EVA polymer forms a film inside the hardened cement paste to improve warpage, tensile and adhesion strength, and improve water retention to improve durability such as neutralization, chloride ion penetration, and freezing and thawing, and to be added at less than 0.5% by weight. In this case, interfacial oxidation and dew condensation caused by organic acids caused by bacteria, fungi, and other microorganisms, such as sulfated bacteria, which may grow at the interface, may be deteriorated. It is preferable to limit the thickness to the above range because it causes a decrease in adhesion strength by delaying the curing time.

(Mixed material: 3.5-6.5 wt%)

Admixtures are components added to improve compressive strength, flexural strength, and adhesion strength, and in the present invention, the expanded material, the fast hard material, and the silica fume do not have the same ratio or any of the three components to be less than twice the one of the other two. The sum within the range may be formulated to conform to the range. In this case, the expander reduces the required unit quantity necessary for securing the consistency of cement paste, and reduces the excess amount other than the amount required for cement hydration, thereby densifying the internal structure of the cement hardened body, thereby improving watertightness and freeze-thawing. In order to improve resistance and increase durability, fast hardwood is added to promote hydration, and silica fume is added to reduce the increase in the amount of air due to the generation of entrained air.

(Circulating fine aggregate: balance)

As described above, the recycled fine aggregate is recycled from concrete lumps in construction waste. In the present invention, it is required to have a particle size of 2.5 mm or less, an absorption rate of 2.6 or less, and an absolute dry density of 2.3 or less in consideration of dispersibility and miscibility. In addition, the recycled fine aggregate has a very great value in terms of recycling resources, the main component is added to the above range in consideration of the composition ratio of the Portland cement and illite, and the inorganic inorganic antimicrobial agent and EVA polymer, admixture, etc. desirable.

As described above, the repair method according to the present invention improves the anti-microbial resistance by reinforcing not only the structure but also the seismic performance by reinforcing the deteriorated part of the concrete structure using the fiber sheet and the push pin. have.

While the invention has been shown and described in connection with specific embodiments, it will be understood that various modifications and variations can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone can grow up easily.

1 to 3 are views for explaining the repair method according to the present invention.

Claims (3)

Remove the deteriorated concrete part from the concrete structure, and then place the perforated fiber sheet on the removed concrete part, insert the push pin into the perforation of the placed perforated fiber sheet, and push the push pin into the concrete structure to insert the perforated fiber sheet into the concrete surface. When fixing deteriorated concrete parts by fixing them and then filling the removed concrete parts with antibacterial mortar, The antibacterial mortar is in weight percent, Portland cement: 34-37%, powdered illite: 1-8%, powdered inorganic antibacterial: 1-2%, EVA polymer: 0.5-1.0%, admixture: 3.5-6.5%; And balance circulating aggregates, The powdery inorganic antimicrobial agent is pulverized to a particle size of 20nm-10 by mixing water-tight material with nickel and tungsten obtained as a by-product of metal smelting; Powdered activated carbon mixed with nickel-zinc-tungsten and ground to a particle size of 20 nm-10; The salts of the amine acid derivatives are ground to a particle size of 20 nm-10; The salts of the oxyquinoline derivatives are ground to a particle size of 20 nm-10; Grinding the silver supported catalyst which is a by-product obtained in the production of ethylene oxide into a particle size of 20 nm-10; Concrete structure repair method using a fiber sheet and pushpin, characterized in that any one selected from the pulverized activated carbon exchanged in silver to a particle size of 20nm-10. delete delete

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