KR20050051840A - Composition for construction using inorganic hollow particle - Google Patents

Abstract

The present invention relates to a building composition used in the finishing work of the building, or mixed with cement in the interior and exterior construction of the building and used as an adhesive or a base material, in a conventional building composition comprising a mixture of water, resin, filler By adding hollow particles, heat insulation function is given as compared with the conventionally used building composition, and it is resistant to cracks due to expansion and contraction due to impact resistance, and is excellent in workability and ultra-lightweight. In particular, the hollow particles are economical by using inorganic hollow particles instead of organic hollow particles which are expensive, and also exhibit excellent characteristics in heat resistance and impact resistance.

Description

Composition for construction using inorganic hollow particle}

The present invention relates to a building composition used in the finishing work of the building, or mixed with cement in the interior, exterior construction of the building and used as an adhesive or a base material, more specifically used in a building finishing material or adhesives that are generally used The present invention relates to a building composition using inorganic hollow particles having more excellent properties such as enhanced heat insulation by adding inorganic hollow particles having an air layer therein to the building composition.

Generally, reinforcing bars and concrete constituting the main structure of a building can construct a structure excellent in strength, and are widely used as a material of a building structure conventionally. However, it is difficult to express various colors on the surface of reinforcement and concrete buildings, and it is easy to cause cracks and is damaged by the infiltration of rainwater, and the concrete is neutralized by the action of carbon dioxide in the air, and the chloride and acid rain According to the action, there is a problem such as to reduce the strength of the structure by causing corrosion of the rebar. Therefore, in order to improve the above problems to secure the durability of the building for a long time and to exhibit each characteristic, it is necessary to perform various finishes on the surface of the building. In addition to the purpose of securing durability in recent years, it is necessary to consider factors that improve the aesthetics of the building surface and improve the functionality such as waterproofness, heat insulation, etc. in accordance with the social request.

FIG. 1 schematically shows an outer wall heat insulation structure of a conventional building, in which a heat insulating material 3 such as strofoam is bonded to the outer wall surface 1 of a structure made of concrete or the like with an adhesive 2. However, since the heat insulator 3 is made of a styrofoam or the like, the strength is weak, and after the mesh 5 is added to compensate for this, the interior and exterior finish 6 of the building structure is applied correctly. At this time, by applying a base material (4) between the heat insulating material (3), the mesh (5), the finishing material (6) is made between the heat insulating material (3), the mesh (5), the finishing material (6). Therefore, according to the finishing work of the building as described above, the durability of the building is secured, and the aesthetics of the building can be decorated using various colors of pigments included in the finishing material (6), and the building of the building through the insulating material (3), etc. It is possible to secure insulation.

The adhesive (2) and the base material (4) is used to mix a mixture consisting of water, resin, methyl cellulose and fillers in the construction site with cement in a volume ratio of about 1 to 1.5, its name and role Despite the difference, they are substantially the same component. However, the base material (4) is used in the form applied to the entire surface of the required portion, the adhesive (2) is different in that it is used in a form separated into the required portion to form a spherical shape. However, in the case of the adhesive (2) or the base material (4) as described above, during curing, as the exothermic hydration reaction of the cement proceeds, voids and bubbles are generated, and thus small holes are generated. Therefore, during the rainy season, when the water is absorbed inside the small hole and stays for a long time without falling out of the wall surface, the adhesive layer may be deteriorated in durability, and in the case of the base layer, the surface layer of the building may be peeled off due to water absorption. There was a losing problem.

On the other hand, the finishing material (6) is used as a mixture of fillers and pigments in the synthetic resin, but the thermal conductivity is large, the thermal insulation is inferior, there is no elastic force and the resistance to cracking due to expansion or contraction, and the temperature of the finishing material (6) Since the change in humidity is large, there is a problem in that the adhesion and durability of the finishing material falls.

Accordingly, the present applicant has applied for a 'insulation finishing material' (application number: 10-2003-0042922) filed as of June 22, 2003 or a 'building material used as a thermal insulation adhesive or a background coating material filed as of July 31, 2003 (application number). : 10-2003-0055347), in order to solve the above problems, a technology related to thermal insulation finishing materials using organic hollow particles having an air layer therein has been presented, but the organic hollow particles have a high price and economical It has a disadvantage of falling, heat resistance and impact resistance weak.

The present invention has been invented in view of the above problems, while maintaining the properties obtainable using conventional organic hollow particles having an air layer therein, using inorganic hollow particles to compensate for the disadvantages of conventional organic hollow particles. An object of the present invention is to provide a composition for building using inorganic hollow particles that can be manufactured at a relatively low cost and excellent in heat resistance and impact resistance.

The building composition using the inorganic hollow particles of the present invention for achieving the above object is characterized in that the inorganic hollow particles are added to the mixture in the building composition comprising a mixture of water, resin, and filler.

When the building composition is used as a lightweight heat insulating finish, the mixture comprises water 7% by weight, resin 22% by weight, pigment 6% by weight, filler 58% by weight, inorganic hollow particles 6% by weight, lightweight When used as a heat insulating adhesive or a base material, the mixture is characterized by comprising 18% by weight of water, 25% by weight of resin, 0.5% by weight of methyl cellulose, 49% by weight of filler, and 7% by weight of inorganic hollow particles. .

On the other hand, the inorganic hollow particles, the main component is a silicic acid having an air layer formed therein, characterized in that the spherical diameter of 120㎛ or less and specific gravity 0.19 or less.

Hereinafter, the configuration and operation of the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view of the inorganic hollow particles used in the present invention.

As shown in the figure, the inorganic hollow particles are spherical and have a main component of silicic acid (Silicic acid) in which the air layer 100 is formed. Since the air layer 100 has a low thermal conductivity, the material to which the inorganic hollow particles to which the air layer 100 is formed is added has excellent thermal insulation. On the other hand, when comparing the organic hollow particles and the inorganic hollow particles proposed in the specification previously filed by the present applicant, the organic hollow particles have an air layer having a lower thermal conductivity, which is excellent in thermal insulation, but the inorganic hollow particles are better in impact resistance and heat resistance. It exhibits excellent properties, and above all, in terms of the unit cost of the material, the unit price of the inorganic hollow particles is only about 10% to 30% of the organic hollow particles.

Figure 3 (a) is a cross-sectional view of the lightweight insulating finish material to which the present invention is applied, 3 (b) is a cross-sectional view of a lightweight insulating adhesive or ground coating material to which the present invention is applied.

In the case of using the building composition of the present invention as a lightweight heat insulating material, the base resin is used in consideration of the compatibility of the acrylic emulsion, the light-resistant heat insulating material in the acrylic resin film 20 to prevent the aging, reinforcement, increase of the resin (增) The filler 40 applied for the purpose of the amount and the pigment 30 used as a coloring agent are formed, and the inorganic hollow particle 10 is added here. The inorganic hollow particles 10 have a spherical diameter of 120 μm or less and a specific gravity of 0.19 or less. Since the inorganic hollow particles 10 having the diameter and specific gravity as described above have an ultra low density and elasticity, the lightweight insulating finish material using the same has excellent resistance to impact and cracks due to expansion and contraction, and is extremely lightweight. Excellent workability and easy to operate, the heat-insulating function is provided to the finishing material itself, the temperature and humidity change of the acrylic resin film 20 is small, the adhesion and durability excellent than the general finish material.

On the other hand, the lightweight heat-insulating adhesive or ground coating material shown in Figure 3 (b), after mixing water, methyl cellulose and a filler using an acrylic emulsion as a base resin, the inorganic hollow particles (10) is added, the filler 40 is used to prevent the aging of the base resin and at the same time to reinforce and increase the base resin, the methyl cellulose is to increase the viscosity to make the material sticky It plays a role. In general, the lightweight heat-insulating adhesive or ground coating material is blended with cement in a ratio of 1 to 1 to 1.5 in the state in which the inorganic hollow particles 10 are added to the mixture made of water, acrylic resin, filler 40, methylcellulose, and the like. 3 (b), it can be seen that the inorganic hollow particles 10 are added between the cement particles 50 and the silica sand which is the filler 40 and dried to dry. The inorganic hollow particle 10 is to fill the voids between the cement particles 50 to reduce the porosity and permeability to increase the strength and durability of the lightweight insulating adhesive or the base material. In addition, as in the case of the lightweight insulating finish material, the spherical ultra low density and elastic inorganic hollow particles 10 have excellent resistance to cracking and expansion of fluidity due to expansion and contraction even in the lightweight insulating adhesive or undercoat material. Construction and operability are increased.

Table 1 below shows the characteristics of the lightweight insulating finisher and general finish applied to the present invention, Table 2 shows the results of the applicant's own experiments measured the properties of the lightweight insulating adhesive and the general adhesive applied to the present invention by comparison .

    division     Lightweight insulation finish     General finish     Remarks    Thermal Conductivity (W / m.K)       0.17       0.30 Thermal conductivity is extremely low, about 35% of general finish materials Hardness change after 500 hours of weather-0-meter       125%       150% Excellent weather resistance of lightweight insulation finishes

    division     Lightweight Insulation Adhesive     General adhesive     Remarks    Thermal Conductivity (W / m.K)       0.19       0.31 Extremely low thermal conductivity of 58% of general adhesives     4.5mm thickness      No cracks   Minute cracking Lightweight insulation adhesive is resistant to cracks      Water resistance      Very good       Excellent Excellent water resistance of the lightweight insulating adhesive

As can be seen in Table 1, the lightweight thermal insulation finishing material to which the present invention is applied is only about 35% of the thermal conductivity compared to the general finishing material is given a thermal insulation function to the finish itself, thereby increasing the weather resistance by being insensitive to temperature. . In addition, as can be seen in Table 2, the lightweight heat insulating adhesive to which the present invention is applied has only a thermal conductivity of about 58% compared to the general adhesive, and thus the heat-insulating function is provided to the adhesive itself. Cracks did not occur until the thickness of 4.5mm was formed, so it was resistant to cracks, and when the sample was soaked in water for 10 days at room temperature, the water resistance was very excellent.

4 is a flow chart of the manufacturing process of the present invention.

First, in the raw material weighing step, when preparing a lightweight insulating finish material, water, resin, filler, pigment, inorganic hollow particles, etc. are prepared. About 22%, TiO ₂ , CaCO ₃ and silica sand used as pigments and fillers are about 6%, 8% and 50%, respectively. (Thickener, Deformer, Preservation, etc.) On the other hand, in the case of lightweight insulating adhesive or ground coating material, water, resin, methyl cellulose, filler, inorganic hollow particles, etc. are prepared. 49% silica sand, inorganic hollow particles 7%, methylcellulose 0.5% and other materials (NH ₄ OH, deformer, etc.) is included.

When the raw material is weighed, the raw materials are put into the mixing tank. The lightweight insulating finish material is added in the order of water, TiO ₂ , acrylic emulsion resin, inorganic hollow particles, CaCO ₃ , and silica sand. It is added in the order of cellulose, acrylic emulsion resin, inorganic hollow particles, and silica sand. In the feeding step, stirring is performed at a speed of about 30 rpm, and when all the raw materials are put into the mixing tank, the mixing step is performed for 30 minutes at a speed of about 60 rpm.

After the mixing step, after checking the color, viscosity, pH, etc. in the inspection step, the product is packaged by the packaging unit in the packaging step.

When the product manufactured as described above is used in the actual work site, the heat insulating finisher is dried for 8 to 24 hours at room temperature after the work, and the heat insulating adhesive or base material is dried for 24 to 48 hours at room temperature after the work.

As described above, according to the composition for construction using the inorganic hollow particles of the present invention, by using the hollow particles in a building finishing material or an adhesive used in the prior art, the thermal insulation function is provided and the impact is strong, so that cracks are generated by expansion and contraction. It is excellent in resistance to the light weight and excellent in workability and easy to operate. In particular, by using inorganic hollow particles instead of organic hollow particles, it is excellent in heat resistance and impact resistance and can be manufactured relatively inexpensively. .

1 is a view schematically showing an outer wall insulation structure of a conventional building,

Figure 2 is a cross-sectional view of the inorganic hollow particles used in the present invention.

Figure 3 (a) is a cross-sectional view of the lightweight insulating finishing material applied to the present invention, 3 (b) is a cross-sectional view of the lightweight insulating adhesive or ground coating material applied to the present invention,

4 is a flow chart of the manufacturing process of the present invention.

<Description of Main Parts of Drawing>

10 inorganic hollow particles 20 acrylic resin coating film

30 Pigment 40 Filler

50: cement particle 100: air layer

Claims (10)

A building composition comprising water, a resin and a filler mixture, wherein the inorganic hollow particles are added to the mixture. The method of claim 1, wherein the mixture is composed of 7% by weight of water, 22% by weight of resin, 6% by weight of pigment, 58% by weight of filler, and 6% by weight of inorganic hollow particles. Composition. The building composition according to claim 2, wherein the inorganic hollow particles are composed mainly of silicic acid having an air layer formed therein. The building composition according to claim 2, wherein the inorganic hollow particles are spherical in shape and have a diameter of 120 µm or less and specific gravity of 0.19 or less. The composition according to any one of claims 2 to 4, which is applied for finishing the interior and exterior walls of the building and dried at room temperature for 8 to 24 hours, which is used as a lightweight insulating finishing material using a building composition. Way. The method of claim 1, wherein the mixture, 18% by weight of water, 25% by weight of resin, 0.5% by weight of methyl cellulose, 49% by weight of filler, and 7% by weight of inorganic hollow particles using inorganic hollow particles, characterized in that Architectural composition. 7. The building composition according to claim 6, wherein the inorganic hollow particles mainly include silicic acid having an air layer formed therein. The building composition according to claim 6, wherein the inorganic hollow particles have a spherical shape and have a diameter of 120 µm or less and a specific gravity of 0.19 or less. The composition according to any one of claims 6 to 8 is blended with cement in a volume ratio of 1: 1 to 1.5, and separated and applied at regular intervals for adhesion between materials on the inner and outer walls of the building at room temperature. Method for use as a lightweight insulating adhesive using a building composition, characterized in that drying for 24 to 48 hours. The composition according to any one of claims 6 to 8 is blended with cement in a volume ratio of 1: 1 to 1.5, and applied to the entire surface in order to strengthen the bonds between the materials on the inner and outer walls of the building at room temperature. Method for using as a lightweight base material using a building composition, characterized in that drying for 24 to 48 hours.