KR20000046731A - Composition for insulating paint - Google Patents

Abstract

PURPOSE: A composition for insulating paint is provided, which has insulation and heatproof efficiency of paint itself. The composition is used to steam pipe, boiler, hot-water tank, car and vessel, so it obtains corrosion prevention and insulation efficiency. CONSTITUTION: A composition for insulating paint comprises; 45-70wt% of an emulsion of thermoplastic resin, 1-10wt% of a ceramic powder, 3-13wt% of fire-resistant material, 4-12wt% of limestone, 3-5wt% of zeolite and 10-30wt% of beeswax.

Description

Insulation paint composition

The present invention relates to a composition for insulating paint, and more specifically, 45-70% by weight emulsion of thermoplastic resin, 1-10% by weight of ceramic powder, 3-13% by weight of refractory material, 4-12% by weight of limestone and zeolite 3 It relates to a composition for heat-insulating paint that contains -5% by weight and 10-30% by weight of beeswax to impart fire resistance, heat insulation and condensation resistance to the paint.

An object of the present invention is to provide a composition for use in heat-insulating paint to have a heat-insulating and heat-resistant effect even in the paint itself by the heat insulation and heat resistance of the ceramic powder.

Another object of the present invention is to provide a composition for heat-insulating paint in which a component having a porous structure absorbs moisture to prevent condensation.

Still another object of the present invention is to provide a composition for insulating paint having fire resistance.

Still another object of the present invention is to provide a composition for insulating paint which can be used for steam pipes, refrigerators, boilers, hot water tanks, automobiles, ships, etc., which are difficult to use conventional heat insulating materials.

In general, in the construction of buildings, heat insulation is carried out to save the heat energy emitted to the outside due to severe temperature difference inside and outside the building, and generally low thermal conductivity such as styropol, sponge, asbestos, and glass fiber on the inside and outside walls of the building. Insulation construction is carried out using a material containing air as a heat insulating material. However, these materials have a problem in that there is a lot of secondary holes due to the difficulty of connecting the insulation and attaching to the building wall due to the weakness of the connection of the insulation, such a gap occurs in the adhesive portion of the insulation and the temperature and humidity difference As a result of condensation inside the insulation and mold generation, not only is it unsanitary but also the insulation effect is reduced, which leads to an increase in energy loss and due to the volume of the insulation itself. In addition, styropol plate, which is mainly used as a heat insulator, is very weak and easily damaged due to careless handling during construction, and is highly flammable and ignitable, so when a fire occurs, the heat insulator itself acts as an accelerator to promote ignition. Heavy asbestos and glass fibers have been found to be carcinogenic and have been used worldwide.

In addition, steam pipes, refrigerators, boilers, hot water tanks and automobiles, ships, etc. need to be insulated in order to save energy, there was a problem that can not use conventional insulation materials such as styropol or asbestos.

The present inventors have studied to solve the above problems of the conventional heat insulator, and as a result, a ceramic material having high heat insulation, heat resistance and body stability together with a thermoplastic resin emulsion, limestone and beeswax is made of a fire-resistant material such as magnesium oxide and porous material. In the case of preparing a paint by putting a zeolite that absorbs moisture by having a structure, the ceramic powder component has a heat insulating property that prevents internal heat from leaking to the outside and reflects it, while magnesium oxide and magnesite impart fire resistance and the zeolite is resistant to heat. By providing condensation, the inventors have found that fire resistance can be obtained at the same time as having a higher heat insulating effect than a conventional heat insulating material.

The composition for insulating paint of the present invention is 45-70% by weight emulsion of thermoplastic resin, 1-10% by weight of ceramic powder, 3-13% by weight of refractory material, 4-12% by weight of limestone, 3-5% by weight of zeolite and beeswax It consists of 10-30% by weight.

The emulsion of the thermoplastic resin used in the present invention is an emulsion polymerized thermoplastic resin, which is used as a colorant to disperse the pigment of the paint, which is 45-70% by weight based on the total composition, preferably 50-65 It is preferred that weight percent be used.

Examples of the thermoplastic resin used in the emulsion include styrene-butanediene copolymers, polyethylenes, vinyl chloride-vinyl chloride copolymers, polyvinyl acetate, and acrylic resins, which are produced by emulsion polymerization. . The emulsion of such a thermoplastic resin is also called latex.

The ceramic powder used in the present invention is obtained by calcining a raw material at 1,150 ° C.-1,300 ° C. and then pulverizing it to a particle diameter of 300 mesh or more. For example, the ceramic used in the present invention is alumina, silica, titania, zirconia. These are used in the paint composition of the present invention to impart heat insulation and heat resistance to the paint, in particular, titania also serves as a pigment (white) of the paint. Such ceramic powder is used 1-10% by weight based on the total composition, preferably 1-5% by weight is used. In addition, diatomaceous earth may be used in place of these ceramic powders as a component for the insulation effect.

Refractory materials used in the present invention are magnesium oxide and magnesite, it is preferable to use 3-13% by weight based on the total composition.

Limestone used in the present invention is a natural decomposition of limestone roasted at a temperature of 700 ℃ or more is preferably used 4-12% by weight based on the total composition. Such limestone serves as an extender in the paint composition according to the present invention.

In addition, the zeolite used in the present invention is a porous mineral having hygroscopicity, and functions to adsorb condensation caused by temperature and humidity differences. Such zeolite may be used in an amount of 3-5% by weight based on the total composition.

Beeswax used in the present invention is used as a brightening agent and a molding agent, by adding it solves the problem of not being able to produce a high gloss, which is a disadvantage of the emulsion-type resin coating material and gives a gloss. 10-30% by weight of the total composition is preferably used, preferably 15-25% by weight.

In the production of the insulating paint composition of the present invention, in order to improve the properties of the paint, a dispersing agent such as an emulsifier of triethanolamine, aluminum stearate, lecithin, polyethylene glycol alkyl ether, or the like may be added to the composition for insulating paint of the present invention.

In order to prepare the paint with the heat-insulating paint composition of the present invention, 45-70% by weight of the emulsion of thermoplastic resin, 1-10% by weight of ceramic powder, 3-13% by weight of refractory material, 4-12% by weight of limestone and zeolite 3-5 It is made by mixing 80% by weight to 80% by weight of solvent water to 10-30% by weight of beeswax and sufficiently stirring at a reaction temperature of 30-50 ° C for 1 hour.

Insulation paint prepared as above has heat reflection effect and thermal barrier effect by ceramic powder component, so it minimizes the internal and external temperature of the building to prevent condensation and has fire resistance by magnesium oxide or magnesite and moisture by porous zeolite component It absorbs and prevents condensation.

In addition, the present invention is an emulsion-type resin coating material that is used by diluting the emulsion of the thermoplastic resin with water, so that it dries quickly, has no smell, exhibits flame retardancy by itself, and has high adhesive strength, so that it adheres perfectly to convex or curved portions and forms a film. The heat loss can be reduced.

Paints produced by the paint compositions of the present invention are used on concrete, slate as well as metal surfaces, and are painted using the methods of brushing, spraying and roll coating. The method of coating varies depending on the characteristics of the material, and it is preferable to coat twice in the vertical direction after 4-5 hours after two coatings in the left and right directions. And the thickness of the paint film which acquires the optimal heat insulation effect is 1.2 mm-1.5 mm.

The present invention will be described through the following examples. These examples do not limit the scope of the present invention, and modifications may be made as appropriate without departing from the scope of the present invention.

A. Comparative Experiment of Insulation Effect

Example 1

50% by weight of the emulsion of thermoplastic resin, 5% by weight of alumina powder, 10% by weight of magnesium oxide, 12% by weight of limestone, 4% by weight of zeolite and 19% by weight of beeswax, and 100% by weight of solvent water were mixed. The paint of the present invention was prepared by sufficiently stirring for 1 hour at 0 ° C., and a copper box having a width of 30 cm, a height of 30 cm, a height of 30 cm, and a thickness of 1.2 mm was prepared. After painting, it was painted twice in the vertical direction and completely dried, and the insulation effect was compared in the following manner.

(a) The external surface temperature was compared when the temperature was no longer changed after 7 hours with the box inside kept at -4 ℃. The temperature of the room was kept constant at 26 ° C. during the experiment.

(b) After 7 hours while hot air was applied to the box surface under the same conditions, the internal surface temperature was compared.

Example 2

Except that the composition for insulating paint of the present invention is composed of 50% by weight of the emulsion of thermoplastic resin, 5% by weight of silica powder, 10% by weight of magnesium oxide, 12% by weight of limestone, 4% by weight of zeolite and 19% by weight of beeswax. In the same manner as in Example 1, the insulating effect of the paint of the composition was compared.

Example 3

Example 1 except that the composition for insulating paint of the present invention comprises 50% by weight of an emulsion of thermoplastic resin, 5% by weight of zirconia powder, 10% by weight of magnesium oxide, 12% by weight of limestone, 4% by weight of zeolite and 19% by weight of beeswax. In the same manner as the heat insulation effect of the paint of the composition was compared.

Example 4

Example 1 except that the composition for insulating paint of the present invention consists of 50% by weight of an emulsion of thermoplastic resin, 5% by weight of diatomaceous earth powder, 10% by weight of magnesium oxide, 12% by weight of limestone, 4% by weight of zeolite and 19% by weight of beeswax. In the same manner as the heat insulation effect of the paint of the composition was compared.

Example 5

Except that the composition for insulating paint of the present invention comprises 50% by weight of the emulsion of thermoplastic resin, 5% by weight of alumina powder, 10% by weight of magnesite, 12% by weight of limestone, 4% by weight of zeolite and 19% by weight of beeswax. In the same manner, the thermal insulation effect of the paint of the above composition was compared.

Example 6

Example 1 except that the composition for insulating paint of the present invention consists of 59% by weight of an emulsion of thermoplastic resin, 1% by weight of alumina powder, 8% by weight of magnesium oxide, 10% by weight of limestone, 4% by weight of zeolite and 21% by weight of beeswax. In the same manner as the heat insulation effect of the paint of the composition was compared.

Comparative Example 1

The thermal insulation effect was compared in the same manner as in Example 1 except that nothing was painted on the copper box manufactured in Example 1.

Comparative Example 2

The thermal insulation effect was compared in the same manner as in Example 2 except that nothing was painted on the copper box manufactured in Example 1.

Comparative Example 3

The thermal insulation effect was compared in the same manner as in Example 3 except that nothing was painted on the copper box manufactured in Example 1.

Comparative Example 4

The thermal insulation effect was compared in the same manner as in Example 4 except that nothing was painted on the copper box manufactured in Example 1.

Comparative Example 5

The thermal insulation effect was compared in the same manner as in Example 5 except that nothing was painted on the copper box manufactured in Example 1.

Comparative Example 6

The thermal insulation effect was compared in the same manner as in Example 6 except that nothing was painted on the copper box manufactured in Example 1.

Each insulation effect is shown in the following table.

In the following table, the "temperature difference" indicates the difference between the temperature of each example and the temperature of the comparative example (without paint) thereof.

Ingredient Composition ratio (wt%) Experiment A Experiment B External surface temperature (℃) Temperature difference (℃) Internal surface temperature (℃) Temperature difference (℃) Example 1 Emulsion / Alumina / Magnesium Oxide / Limestone / Zeolite / Beeswax 50/5/10/12/4/19 7.0 5.8 48.5 21.9 Example 2 Emulsion / Silica / Magnesium Oxide / Limestone / Zeolite / Beeswax 50/5/10/12/4/19 8.0 6.8 49.4 22.8 Example 3 Emulsion / Zirconia / Magnesium Oxide / Limestone / Zeolite / Beeswax 50/5/10/12/4/19 7.3 6.1 47.3 21.7 Example 4 Emulsion / Diatomite / Magnesium Oxide / Limestone / Zeolite / Beeswax 50/5/10/12/4/19 7.9 6.7 49.3 22.7 Example 5 Emulsion / Alumina / Magnesite / Limestone / Zeolite / Beeswax 50/5/10/12/4/19 7.1 5.9 47.5 20.9 Example 6 Emulsion / Alumina / Magnesium Oxide / Limestone / Zeolite / Beeswax 59/1/8/10/4/21 7.6 6.4 49.1 22.5

From the table, it was found that the paints of the present invention prepared in Examples 1-6 all had excellent heat insulating effects.

The present invention has an anti-corrosion effect without oxidation and corrosion due to the ceramic powder component can be extended when the construction of the building, and as shown in the above table has a high thermal barrier effect to minimize the internal and external temperature difference of the structure . In addition, this prevents condensation in advance, and the bauxite component of the present invention has an advantage that the structure is porous and excellent in hygroscopicity, and thus can have a waterproof effect without a separate waterproofing treatment. In addition, there is an effect of preventing the fire from spreading due to the refractory component.

Insulation paint made of the composition of the present invention is used for roofs or walls made of slate, tin, concrete, etc. to bring heat insulation and thermal shock prevention effect to buildings, and it is difficult to use conventional heat insulators such as steam pipes, refrigerators, boilers, hot water Used in tanks, automobiles, ships, etc., the effect of corrosion protection and insulation can be obtained.

Claims (3)

45-70% by weight emulsion of thermoplastic resin, 1-10% by weight of ceramic powder, 3-13% by weight of refractory material, 4-12% by weight of limestone, 3-5% by weight of zeolite and 10-30% by weight of beeswax Composition for insulating paint, characterized in that. The composition of claim 1, wherein the ceramic powder is one selected from alumina, silica, titania, and zirconia. The composition of claim 1, wherein the refractory material is one selected from magnesium oxide and magnesite.