KR20120117550A - A reinforcement mortar for concrete structure - Google Patents

Abstract

PURPOSE: A mortar for concrete structure reinforcement is provided to enhance adhesive force and mobility of the concrete structure. CONSTITUTION: A mortar for concrete structure reinforcement comprises an epoxy resin, a hardener, silica and aggregate. The mortar for concrete structure reinforcement additionally includes reactive diluent, non-reactive diluent, mineral fibers, barium sulfate, calcium carbonate and additives. The mortar for reinforcement comprises 7-17 wt% of epoxy resin, 1-5 wt% of hardener, 15-25 wt% of silica, 25-45 wt% of aggregate, 1-5 wt% of reactive diluent, 1-5 wt% of non-reactive diluent, 4-11 wt% of mineral fiber, 7-11 wt% of barium sulfate, 7-11 wt% of calcium carbonate, and 1-5 wt% of additive.

Description

Mortar for concrete structure {a Reinforcement Mortar for concrete structure}

The present invention relates to a reinforcing mortar used for stiffness reinforcement of concrete structures, and more particularly, when the reinforcing mortar is constructed on the cross section of the concrete structure for reinforcement of the concrete structure, the adhesion to the existing concrete structure is excellent. It can be tightly and strongly attached to existing concrete structures, and it has excellent fluidity so that it can be tightly injected into the place where reinforcing mortar is injected to increase workability under a very narrow working environment. Regarding the mortar for reinforcing concrete structures, which has the property of hardening in a short time after being poured so that the structure to be quickly reused can be prevented from cracking by reducing the coefficient of thermal expansion and drying shrinkage during hardening will be.

Concrete structures are generally used by reinforcing the characteristics of concrete, which are strong in compressive force but weak in tensile force, by using reinforcing bars, and can be said to be the most widely used architectural structure in modern society that builds high-rise buildings. However, many concrete structures are subject to a decrease in the strength of the structure due to faults in the construction process, lack of maintenance consciousness, inadvertent use, or changes in the use environment and increase in use load over time. They become obsolete and lose their function.

Recently, there are serious concerns about the durability and safety of concrete structures due to the large-scale accidents of reinforced concrete structures in Korea, and the construction of large-scale buildings that started after the 70s has declined in the strength of structures at the present time more than 20 years have passed. In many cases, reinforcement methods are required to restore the function of such structures, and in some cases, reinforcement is needed due to expansion and change of practicality due to the remodeling of buildings that are expanding in the construction market. It is true.

In the conventional concrete structure reinforcement method, a method of attaching a steel sheet or a carbon fiber sheet, etc. to the outside is used, or a method of pouring reinforcing mortar on the cut out portion of the concrete outside or inside is used.

In particular, in the method of increasing the cross section of the concrete structure by using the reinforcing mortar, the reinforcing mortar used for reinforcement must be tightly attached to the existing concrete structure, and thus, an excellent adhesion force is urgently required.

In addition, in the case of the method of increasing the cross-section of the concrete structure as described above, it is also important to have excellent fluidity so that the reinforcing mortar to be poured can be tightly injected into the pouring space.

In addition, due to the nature of reinforcement work, the reinforcing mortar can be cured quickly after pouring, so that it is also required to be able to quickly reuse the structure targeted for reinforcement work. (Because cracks in reinforcing surfaces, which are usually constructed with a thin thickness, are the main culprit of reducing the reinforcing effect) are also urgently needed.

Therefore, there is an increasing need for reinforcing mortar having excellent adhesion and fluidity, fast curing rate and low shrinkage rate that satisfy the above requirements.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

An object of the present invention is to provide a concrete structure reinforcement mortar that can be tightly attached to the existing concrete structure with excellent adhesion to the existing concrete structure when constructing the reinforcement mortar on the cross section of the concrete structure for the reinforcement of the concrete structure To provide.

Another object of the present invention is to provide a concrete structure reinforcement mortar having excellent fluidity so that the portion to be poured is tightly injected to the reinforcement mortar is injected to increase the workability in a very narrow working environment.

Another object of the present invention is to reduce the thermal expansion rate and drying shrinkage during hardening so as not to cause cracks while having a property that can be cured within a short time after being placed so that the structure to be reinforcement can be quickly reused. It is to provide a mortar for reinforcing concrete structure having.

Mortar for reinforcing concrete structures for achieving the above object of the present invention includes the following configuration.

Mortar for reinforcing concrete structures according to an embodiment of the present invention is epoxy resin excellent in mechanical strength, chemical resistance and adhesion; A curing agent for curing by reacting with an epoxy resin; Silica to reinforce mechanical strength with fillers; Aggregate; characterized in that it comprises a.

According to another embodiment of the present invention, the mortar for reinforcing the concrete structure according to the present invention is a reactive diluent to reduce the viscosity by reacting with the epoxy resin and the curing agent to increase the fluidity by giving flexibility of the coating film; Non-reactive diluents that lower the viscosity of the mortar; Mineral fiber to prevent dry shrinkage and cracking; Barium sulfate and calcium carbonate to reduce the mortar's thermal expansion and cure shrinkage and improve adhesion; An additive; characterized in that it further comprises.

According to another embodiment of the present invention, the mortar for reinforcing concrete structures according to the present invention is 7 to 17% by weight epoxy resin, 1 to 5% by weight hardener, 15 to 25% by weight silica, 25 to 45% by weight aggregate, reactive 1 to 5% by weight of diluent, 1 to 5% by weight of non-reactive diluent, 4 to 10% by weight of mineral fiber, 7 to 11% by weight of barium sulfate, 7 to 11% by weight of calcium carbonate, and 1 to 5% by weight of additive It features.

According to another embodiment of the present invention, in the mortar for reinforcing concrete structures according to the present invention, the silica is any one of aluminum silicate, magnesium silicate, calcium silicate, the non-reactive diluent is benzyl alcohol or perfuryl alcohol, The additive is characterized in that it comprises a dispersant, antifoaming agent, curing accelerator, coating film leveling agent, flow control agent, anti-settling agent and the like.

The present invention can obtain the following effects by the above-described embodiment, the constitution described below, the combination, and the use relationship.

The present invention has an effect that can be tightly and strongly attached to the existing concrete structure by excellent adhesion to the existing concrete structure when constructing the reinforcing mortar on the cross section of the concrete structure for the reinforcement of the concrete structure.

The present invention has the effect of having excellent fluidity so that the portion to be poured is tightly injected into the reinforcement mortar is injected to increase the workability in a very narrow working environment.

The present invention has the effect of preventing the occurrence of cracks by reducing the thermal expansion rate and drying shrinkage rate at the time of hardening while having a property that can be cured in a fast time after pouring so as to quickly reuse the structure subjected to reinforcement work. .

1 is a reference diagram showing a state in which a crack occurs in an existing concrete structure
2 is a reference diagram showing a state in which reinforcement mortar is constructed on a concrete slab structure
3 is a reference diagram showing a state in which the reinforcement mortar to the concrete beam structure
4 is a reference diagram showing a state in which reinforcement mortar is constructed on the concrete wall structure
5 is a reference diagram showing a state in which the construction of the reinforcement mortar on the concrete column structure
6 is a test report of the mortar for reinforcing concrete structures according to the present invention

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the mortar for reinforcing concrete structures according to the present invention will be described in detail. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a reference diagram showing a state in which a crack occurred in an existing concrete structure, Figure 2 is a reference diagram showing a state in which reinforcement mortar was constructed in the concrete slab structure, Figure 3 is a construction of reinforcement mortar in the concrete beam structure Figure 4 is a reference diagram showing a state, Figure 4 is a reference diagram showing a state of constructing the reinforcement mortar on the concrete wall structure, Figure 5 is a reference diagram showing a state of constructing the reinforcement mortar on the concrete column structure, Figure 6 Is a test report of the mortar for reinforcing concrete structures according to the present invention.

Referring to FIG. 1, for example, an existing concrete slab structure, the slab a between the beams b and the b supporting the slab a due to the load acting continuously on the upper part of the slab a, Receive the same bending moment as shown by the dashed line, but the slab (a) between the beam (b) and the beam (b) the lower center ceiling surface (a2) and the upper floor of the slab (a) located above the beam (b) When the reinforcing bars are not made properly due to the reinforcing bars being reinforced by the pressure of the concrete placed during the concrete pouring operation or the reinforcing bars being out of the exact position of the bars, such as when the reinforcing bars on the surface (a1) are not properly made, FIG. 1 The upper side of the slab (a) located on top of the beam (b) and the lower side of the slab (Fig. 1), as shown in (2) of (this is the plane looking down from the top of the slab). Beams (b) and (b) as viewed from The cracks are generated at the center lower side of the slab (a) located between the), which lowers the strength of the structure and causes structural problems. The reinforcing work is to reinforce the mortar for reinforcing work. This is done.

In the reinforcement work using the reinforcing mortar, in the concrete slab structure as shown in Figure 2, after cutting the upper bottom surface of the slab (a) located in the upper portion of the beam after the reinforcing bar (1) and cut in the cut space The reinforcing mortar (2) can be constructed to reinforce the upper surface of the concrete slab (not shown, but in the case of reinforcing the lower surface of the slab, a separate formwork must be used to support the site where the reinforcing mortar is constructed. In the concrete beam structure as shown in FIG. 3, after the reinforcing bar 1 is disposed along the circumference of the side and the bottom surface of the beam b, the formwork 3 is installed and the reinforcement is formed in the formwork 3. Mortar (2) can be injected to reinforce the beam structure, and in the concrete wall structure as shown in FIG. 4, the formwork (3) is installed after the reinforcing bars (1) are disposed on both sides of the wall (c). And reinforce the wall structure by injecting a reinforcing mortar (2) into the formwork (3), and in the concrete column structure as shown in FIG. 5, the reinforcing bar (1) is placed along the circumference of the column (d). After the formwork (3) is installed and the reinforcement mortar (2) in the formwork 3 can be reinforced to the column structure.

That is, when looking at the concrete structure reinforcement work using the reinforcement mortar as described above, the reinforcement mortar used for reinforcement must be tightly attached to the existing concrete structure and strongly attached to the concrete structure as described above. In the case of the method of increasing the cross-sectional area of the casting is usually very narrow, it is also important to have excellent fluidity so that the reinforcing mortar to be poured is tightly injected throughout the pouring space. In addition, due to the nature of reinforcement work, the reinforcing mortar can be cured quickly after pouring, so that it is also required to be able to quickly reuse the structure targeted for reinforcement work. (Because cracks in reinforcing surfaces, which are usually constructed with a thin thickness, are the main culprit of reducing the reinforcing effect) are also urgently needed.

To this end, the mortar for reinforcing concrete structures according to an embodiment of the present invention 7 to 17% by weight of epoxy resin excellent mechanical strength, chemical resistance and adhesion; 1 to 5% by weight of a curing agent to react with the epoxy resin to cure; 15-25% by weight of silica to reinforce mechanical strength with filler; 25 to 45 weight percent aggregate; 1 to 5% by weight of a reactive diluent which reacts with the epoxy resin and the curing agent to lower the viscosity and give flexibility of the coating to increase fluidity; 1 to 5% by weight non-reactive diluent to lower the viscosity of the mortar; Mineral fiber 4 to 10% by weight to prevent dry shrinkage and cracking; 7-11% by weight of barium sulfate and 7-11% by weight of calcium carbonate to reduce the thermal expansion rate and curing shrinkage of the mortar and improve adhesion; Additives 1 to 5% by weight; characterized in that comprises a.

The epoxy resin is a composition for securing the mechanical strength of the reinforcing mortar according to the present invention and for securing chemical resistance and adhesiveness, and epoxy resin which is a thermosetting resin formed by polymerization of an epoxy group and a dendritic substance having two or more epoxy groups in a molecule. Properties of the mechanical strength such as bending strength of the resin and chemical resistance and adhesiveness can be applied to the reinforcing mortar of the present invention to ensure the mechanical strength necessary for the properties of the reinforcing mortar and to exhibit chemical resistance and adhesion. In particular, bisphenol A or bisphenol F diglycidyl ether is used as the epoxy resin used in the present invention, and it is preferable to use a mixture of 7 to 17% by weight based on the total weight of the reinforcing mortar.

The curing agent is a component that reacts with the epoxy resin to cure the epoxy resin, and combines with the functional group of the epoxy resin to form a crosslinked structure. In particular, a polyamine curing agent or a polyamide curing agent is used as the curing agent, and it is preferable that the curing agent is mixed in a proportion of 1 to 5% by weight based on the total weight of the reinforcing mortar. The cured product of such a polyamine-based curing agent is hardly deformed in physical properties below the heat distortion temperature, and has a strong characteristic against alkalis and acids.

The silica is a component used as a filler to reinforce the mechanical strength of the reinforcing mortar according to the present invention. Silica is a compound of oxygen and silicon, also called silicic anhydride. In the present invention, since the silica is mixed with the reinforcing mortar, the mechanical strength of the reinforcing mortar is increased by increasing the mechanical strength of the concrete structure. It is effective to further increase the characteristics of the reinforcing mortar to reinforce the strength. As the silica, aluminum silicate, magnesium silicate, calcium silicate may be used, and it is preferable to use a mixture of 15 to 25% by weight based on the total weight of the reinforcing mortar.

The aggregate is a component that is mixed with the reinforcing mortar according to the present invention to reduce the coefficient of thermal expansion and increase the mechanical strength, in particular, to reduce the cost of manufacturing the reinforcing mortar. In other words, by incorporating the aggregate of the reinforcing mortar with a cheaper material cost and a certain degree of strength, the manufacturing cost of the entire reinforcing mortar can be lowered, and the mechanical strength and low thermal expansion coefficient of the aggregate can be utilized. . As the aggregate, fine aggregates having a diameter of about 1 to 3 mm are preferably used. The aggregate is mixed after the mixing of the epoxy resin is completed, which will be described later. The aggregate is preferably used is mixed at a ratio of 25 to 45% by weight of the total weight of the reinforcing mortar.

The reactive diluent reacts with the epoxy resin and the curing agent to lower the viscosity and give flexibility of the coating to increase fluidity. The reactive diluent includes C6-C28 alkyl glycidyl ether and C6-C28 fatty acid glycidyl ester. , C6-C28 alkylphenol glycidyl ether, versatic acid glycidyl ester and the like can be utilized. The reactive diluent as described above is reactive with the epoxy resin and the curing agent, and by reacting with the epoxy resin and the curing agent lowers the viscosity of the entire reinforcing mortar and increases the fluidity as well as to ensure the flexibility of the coating film. The reactive diluent is preferably used in a mixture of 1 to 5% by weight based on the total weight of the reinforcing mortar.

The non-reactive diluent is a composition that is mixed with the reinforcing mortar separately from the reactive diluent to lower the viscosity of the reinforcing mortar according to the present invention, as described above, the construction properties of the reinforcing mortar due to the nature of the space in which the reinforcing mortar is constructed In order to improve the bar, excellent fluidity must be ensured. In the present invention, in addition to the reactive diluent reacting with the epoxy resin and the curing agent, the non-reactive diluent may be mixed separately to lower the viscosity of the mortar so that the reinforcing mortar has excellent fluidity. It also penetrates into the construction space, allowing tight contact with the concrete structure to be reinforced. To this end, as the non-reactive diluent, benzyl alcohol, perfuryl alcohol, or the like is utilized, and it is preferable to use a mixture of 1 to 5% by weight in the total weight of the reinforcing mortar.

The mineral fiber is mixed, added to prevent the dry shrinkage and cracking of the reinforcing mortar according to the present invention, the mineral fiber has environmentally friendly, as well as mixed in the reinforcing mortar due to the characteristics of the fiber particles and particles Since it acts to bind each other, it is effective to prevent drying shrinkage or cracks caused during drying of reinforcing mortar after construction. As described above, in the present invention, by mixing the mineral fiber in the reinforcing mortar, it is possible to effectively improve the problems caused by shrinkage or cracking during drying that occurred in the conventional reinforcing mortar. The mineral fiber is preferably used in a mixture of 4 to 10% by weight of the total weight of the reinforcing mortar.

The barium sulfate is mixed in order to reduce the thermal expansion and curing shrinkage of the reinforcing mortar according to the present invention and improve the adhesiveness, barium sulfate has a high specific gravity, excellent smoothness and easily dispersed and spread in the present invention By mixing the barium sulfate with the reinforcing mortar, it is possible to reduce the thermal expansion and curing shrinkage during drying and curing of the reinforcing mortar, as well as to allow the components of the reinforcing mortar to penetrate and adhere to the joint surface of the concrete structure. It is possible to improve the adhesion so that the construction of the reinforcing mortar and dry shrinkage and cracks hardly occur after construction. To this end, the barium sulfate is preferably used in a mixture of 7 to 11% by weight based on the total weight of the reinforcing mortar.

The calcium carbonate is mixed with the barium sulfate to reduce the thermal expansion and curing shrinkage of the reinforcing mortar according to the present invention and to improve adhesion. The calcium carbonate also has less shrinkage and deformation, as well as fluidity and dispersibility. In this invention, the calcium carbonate is mixed with the barium sulfate in the reinforcing mortar so that the thermal expansion rate and the hardening shrinkage rate can be reduced during drying and curing of the reinforcing mortar, as well as the reinforcing mortar. It is possible to improve the adhesiveness so that the components can be adhered to the joint surface of the concrete structure so that the construction of reinforcing mortar and the dry shrinkage and cracking after construction are hardly generated. To this end, the calcium carbonate is preferably used in a mixture of 7 to 11% by weight based on the total weight of the reinforcing mortar.

The additives are additionally added to improve the performance and workability of the reinforcing mortar according to the present invention, the dispersing agent is added to increase the fluidity by improving the dispersibility of the powder including the aggregate, reinforcing mortar Antifoaming agent is added to the mixture of each component of the antifoaming agent to suppress the generation of bubbles, the curing accelerator, coating film smoothing agent, flow control agent, added to control the reactivity to improve the reactivity between the epoxy resin and the curing agent, Anti-settling agents and the like. As the dispersant, an alkyollammonium salt copolymer may be particularly used as a multi-purpose wetting dispersant to improve fluidity and thereby improve workability. The antifoaming agent may be a polysiloxane-based or non-silicone-based antifoaming agent. It is used to prevent bubbles from occurring when mixing the reinforcing mortar. In addition, the curing accelerator is used to control the reactivity between the epoxy resin and the curing agent to quickly cure the reinforcing mortar according to the present invention to reuse the concrete structure, in particular trisdimethylaminomethylphenol (tris ( dimethylamino methyl) phenol) and the like can be utilized. The additive is preferably used in a mixture of 1 to 5% by weight of the total weight of the reinforcing mortar.

The reinforcing mortar according to the present invention containing such a component has excellent adhesion to the existing concrete structure when the reinforcing mortar is constructed on the cross section of the concrete structure for reinforcement of the concrete structure. Not only can it be attached, but it also has excellent fluidity so that the site to be poured can be tightly injected into the place where reinforcing mortar is injected by increasing workability in a very narrow working environment, and it is possible to quickly reuse the structure to be reinforced. So that it has a property that can be cured in a short time after pouring so as to reduce the thermal expansion rate and dry shrinkage rate during curing to prevent cracking.

Hereinafter, a brief description will be given of a method of mixing and constructing mortar for reinforcing concrete structures according to an embodiment of the present invention.

Mortar for reinforcing concrete structures according to the present invention is installed in the concrete structures such as slabs, beams, walls, columns to be reinforced as described above and then injected into the formed molds to be hardened and cured and attached to the concrete structure In order to construct the concrete structure reinforcement mortar according to the present invention, first, the ground surface cleanup work on the surface of the concrete structure to be reinforced (that is, the surface of the structure is treated to the extent that coarse aggregates are derived). After that, clean the mold to remove fine dust, etc.), and then form the mold so that reinforcing mortar can be injected and poured. After the preparation for pouring and pouring is completed, the reinforcing mortar is mixed and poured. First, the epoxy resin, the reactive diluent, the non-reactive diluent, the additive and the curing agent are mixed and reacted so that the chemical reaction between the two and three minutes occurs first. After the first mixing, aggregate, mineral fiber, silica, barium sulfate, calcium carbonate, etc. are mixed to perform a second mixing so that the aggregate is sufficiently mixed and the remaining ingredients are sufficiently mixed and dispersed. The casting of the reinforcing mortar must be completed quickly into the formwork before it is finished. At this time, the depth to be injected at one time is preferably about 2.5 ~ 15㎝ and when pouring the outdoor temperature is most preferably made in about 20 ℃. After finishing the casting and curing, if the post-treatment finishing work such as surface treatment is performed smoothly with a brush or the like, the construction of the reinforcing mortar according to the present invention is completed.

Hereinafter, through the test of the reinforcing mortar according to the present invention to determine the properties of the mechanical strength, adhesive strength and thermal expansion coefficient exhibited by the reinforcing mortar according to the present invention.

[Test] Characteristic test of reinforcing mortar according to the present invention

-Purpose: Examining the mechanical strength, adhesive strength and thermal expansion coefficient of the reinforcing mortar according to the present invention

-Sample: Reinforcing mortar according to the present invention (product name: MEM-6000) 12% by weight epoxy resin, 2% by weight curing agent, 22% by weight silica, 35% by weight aggregate, 2% by weight reactive diluent, 1% non-reactive diluent 50 mm cube specimen made of reinforcing mortar containing%, mineral fiber 7%, barium sulfate 9%, calcium carbonate 9%, and additive 1%

-Test method: Tests thermal expansion coefficient, durometer hardness, tensile strength, compressive strength, bending strength, impact strength, adhesive strength based on KS M 3015, KS M ISO 868, KS M 3055, KS M 3437

-Test result: Referring to the test report of FIG. 6, the reinforcing mortar specimen (sample) according to the present invention exhibits a coefficient of thermal expansion of 2.8 * 10 ^-5 mm / ° C, a tensile strength of 17.0 MPa, and a compressive strength of 106.2 MPa. , 46.9MPa of bending strength, 1.4kJ / ㎡ of impact strength, 10.8N / mm2 of adhesive strength, and excellent mechanical properties (tensile strength, compressive strength, bending strength) as well as excellent adhesiveness compared to the characteristics of existing concrete structures. It can be seen that the thermal expansion rate is low.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Should be interpreted as belonging to the scope.

a: slab b: beam c: wall d: column
1: rebar 2: reinforcing mortar 3: formwork

Claims (4)

In the reinforcement mortar used to reinforce the concrete structure,
Epoxy resins excellent in mechanical strength, chemical resistance and adhesion;
A curing agent for curing by reacting with an epoxy resin;
Silica to reinforce mechanical strength with fillers;
Aggregate; reinforcement mortar, characterized in that it comprises a aggregate. The method of claim 1, wherein the reinforcing mortar
A reactive diluent reacting with the epoxy resin and the curing agent to lower the viscosity and give flexibility of the coating to increase fluidity;
Non-reactive diluents that lower the viscosity of the mortar;
Mineral fiber to prevent dry shrinkage and cracking;
Barium sulfate and calcium carbonate to reduce the mortar's thermal expansion and cure shrinkage and improve adhesion;
Mortar for reinforcing concrete structures, characterized in that it further comprises an additive. The method of claim 2, wherein the reinforcing mortar
Epoxy resin 7-17 wt%, curing agent 1-5 wt%, silica 15-25 wt%, aggregate 25-45 wt%, reactive diluent 1-5 wt%, non-reactive diluent 1-5 wt%, mineral fiber 4 ~ Mortar for reinforcing concrete structures, characterized in that it comprises 10% by weight, barium sulfate 7-11% by weight, calcium carbonate 7-11% by weight, additives 1-5% by weight. The method of claim 3, wherein
The silica is any one of aluminum silicate, magnesium silicate, calcium silicate,
The non-reactive diluent is benzyl alcohol or perfuryl alcohol,
The additive mortar for reinforcing concrete structures, characterized in that it comprises a dispersing agent, an antifoaming agent, a curing accelerator.

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