KR100816085B1 - Anti-stain solar heat-shield insulating paint composition - Google Patents

Abstract

The present invention relates to a non-polluting solar thermal insulation coating composition, and more particularly, a binder, bubble-shaped spherical inorganic fine particles having an average particle size of 1 to 40 μm, bubble-shaped spherical inorganic fine particles having an average particle size of 50 to 300 μm, and a thin film. Mica pigment of mica component and colored pigment have a certain content ratio, so it has the advantages of excellent solar reflection effect and heat insulation and excellent protection against external contamination, so that it blocks and insulates solar heat for a long time. It relates to a paint composition that can be obtained.

The heat insulating coating composition of the present invention is coated where a heat insulation is required to prevent heat transfer between a part directly exposed to sunlight or an object or an interface to prevent a temperature rise due to the sun's radiant heat, and heat from outside or inside is not transferred to each other. In addition to the ability to prevent thermal insulation, which prevents the coating from being contaminated, the solar shielding and thermal insulation performance can be maintained for a long time.

Non-polluting, sun protection, heat insulation, paint, foam type, inorganic fine particles

Description

Anti-stain solar heat-shield insulating paint composition

Non-polluting solar thermal insulation coating composition, more specifically, a binder, bubble-shaped spherical inorganic fine particles having an average particle size of 1 to 40 ㎛, bubble-shaped spherical inorganic fine particles having an average particle size of 50 to 300 ㎛, thin film mica Mica pigments and pigments of pigments have a certain content ratio, so it has the advantages of excellent solar reflection effect and heat insulation and excellent protection against external contamination. It relates to a paint composition that can be.

In the summer, solar energy in Korea reaches an average of 5,900 Kcal / ㎡, and during the daytime, the surface temperature of the iron plate roof is raised to around 80 ℃. This change in temperature is a phenomenon that occurs due to the movement of heat, and the mechanism of heat transfer is classified into the following three kinds. That is, conduction through which heat moves directly from a high temperature to a low temperature, a convection in which heat is transferred through a flow or movement of a gas or liquid, which is a fluid medium, and not through a separate medium. The radiation of heat emitted directly from a heat source hits the surface of an object, causing vibrations of molecules that generate heat energy.

Sunlight is a type of electromagnetic wave, which varies depending on the season and region, but is divided into 3-7% of ultraviolet light, 47-50% of visible light, and 43-50% of infrared light. At this time, infrared rays, which occupy half of the sun's rays, generate heat energy by touching the surface of the object, causing the vibration of molecules, and due to the heat energy, the temperature of the object rises, and the indoor temperature of the building increases through conduction and convection. It consumes a lot of energy for cooling.

Recently, the energy problem is influenced by the policy supply and demand of oil producing countries and continuous price increase, and if the country relies solely on imports of energy sources like Korea, the necessity of energy saving is absolutely essential.

The function of the insulation is to suppress the flow of heat and to be able to control the movement of heat by conduction and radiation, which can be controlled artificially in everyday life.

Insulation that mainly blocks heat flow can be roughly divided into filling type insulation and reflective type insulating material. The characteristic of filling type heat insulating material has the effect of suppressing the conduction of heat by forming a fine air bubble inside. Type insulation has the effect of suppressing the conversion to thermal energy by reflecting the sunlight reaching the surface of the object.

However, this type of insulation is difficult to use as a final finish due to problems such as time-consuming, expensive, bulky, and inefficient space, as well as appearance, strength, and durability.

In order to solve this problem, an insulating paint using an airtight ceramic filler was developed [US Pat. Nos. 4,623,390, 4,286,013], and the insulating coating has a superior thermal insulation effect and a function of the final finishing material compared to the existing insulating materials. At the same time, space utilization and construction costs are reduced due to volume reduction. However, this insulation paint is effective in the early stages of construction, but as time passes, the surface of the coating is rough and uneven, so it is easily polluted and contaminated within a short period of time in the outdoors, and the function of shielding the sun's heat is drastically deteriorated. I have a problem.

Therefore, the present invention solves the problems of the existing insulating paint and can maintain a good heat insulation effect and solar energy shielding effect for a long time, as well as to provide a convenient and economical solar shield heat insulation coating composition having an external pollution prevention effect. Its purpose is to.

The present invention is 10 to 80% by weight of binder, 1 to 45% by weight of bubble-shaped spherical inorganic fine particles having an average particle size of 1 to 40 μm, 5 to 50% by weight of bubble-shaped spherical inorganic fine particles having an average particle size of 50 to 300 μm, thin film A non-polluting sunscreen coating composition comprising 1 to 40% by weight of a mica component of the phase mica component and 0.1 to 35% by weight of a coloring pigment is characterized by the above-mentioned.

This invention will be described in more detail.

The present invention is a non-polluting solar thermal barrier that can obtain a long-term continuous solar heat shielding effect and thermal insulation effect by securing a composite film surface heat reflection function, thermal insulation function of the fine bubble layer, pollution prevention function by the dense inorganic particulate layer on the surface of the coating film It relates to an insulating paint composition. Insulating coating composition of the present invention contains the bubble-shaped spherical inorganic fine particles and particle-like mica pigments having different particle sizes reflects most of the solar heat, thereby inhibiting the absorption and transmission of thermal wavelengths, thereby fundamentally preventing conversion to heat. In addition, the fine pores of different sizes are distributed in a large amount inside the coating film to properly block the movement of heat into or out of the coated workpiece.

In the non-polluting sunscreen thermal insulation paint composition according to the present invention, preferably, the binder 20 to 70% by weight, the particle size of 1 to 40 ㎛ foaming spherical inorganic fine particles 10 to 40% by weight, the particle size of 50 to 300 ㎛ foam Spherical inorganic fine particles comprise 10-35 weight%, 5-30 weight% of thin film mica pigments, and 2-30 weight% of coloring pigments.

Referring to the composition of the non-polluting heat shield coating composition of the present invention in more detail as follows.

There is no separate limitation to the binder that can be used in the present invention, and any binder that has been applied to all the paint compositions known in the art can be applied, so that it can be appropriately selected and used according to the purpose and purpose. For example, as the binder, resins of all kinds of binders including alkyd, amino, epoxy, phenol, urethane, silicone, nitrocellulose, rubber chloride, vinyl, acrylic, and the like can be used. Such binders are used in the composition of the present invention in the range of 10 to 80% by weight, preferably in the range of 20 to 70% by weight. If the content of the binder is less than 10% by weight, the fluidity is insufficient, making the coating difficult, and the strength of the coating is weak.When the content of the binder is used more than 80% by weight, the particulate bubble layer in the coating is reduced, and the binder is exposed to the surface of the coating. Increasingly, the solar reflective layer is reduced, so that the solar reflective effect, insulation effect and non-pollution effect are all reduced.

In the non-polluting heat shield coating composition according to the present invention, inorganic fine particles having different particle size distributions are mixed in a certain content ratio in order to obtain a higher non-polluting effect and a good non-pollution effect. Among the inorganic fine particles used in the present invention, the small particles (1-40 μm) have high hardness characteristics having breakage strength of 10,000 psi or more, preferably 10,000 to 100,000 psi, and have a bubble shape. Use it. When the breaking strength of the inorganic fine particles used is less than 10,000 psi, the coating film hardness is lowered, and the surface of the coating film is easily damaged by external force and the non-polluting effect is lowered. The inorganic fine particles applied to the present invention are borosilicate glass, silicate ceramics, silica alumina ceramics, etc., and use spherical spherical particles because the high-hardness inorganic fine particles suppress the fouling of the film and form spherical bubbles. This is because it improves the sun reflection effect and heat insulation.

Particularly, the present invention uses inorganic fine particles having different particle size distributions together. As a feature of the present invention, high-hardness inorganic fine particles having different particle sizes are densely distributed in the coating film, thereby securing more fine pores inside the coating film. Unevenness and pores on the surface of the coating film can be removed, and the surface arrangement of inorganic hard particles can prevent contamination by foreign matters, so that it can maintain a continuous solar heat shielding effect and insulation effect.

In the present invention, inorganic fine particles having a specific gravity of 0.8 to 1.2 and having a particle size of 1 to 40 μm and inorganic fine particles having a specific gravity of 0.1 to 0.8 and a particle size of 50 to 300 μm are mixed and used. Bubble-shaped spherical inorganic fine particles having an average particle size of 1 to 40 µm are used in the range of 1 to 45% by weight, preferably 10 to 40% by weight, in the total composition. If the effect is lowered and used in excess of 45% by weight, there is a problem that the thermal insulation performance is lowered and the salvability of the coating film is lowered. In addition, the bubble-shaped spherical inorganic fine particles having an average particle size of 50 to 300 µm are used in the range of 5 to 50% by weight, preferably 10 to 35% by weight in the total composition. When used in excess of 50% by weight, the adhesion and non-pollution property of the coating film and paint stability are deteriorated. Preferably, the mixing ratio of the inorganic fine particles having different particle sizes is maintained in the range of 1: 5 to 5: 1 by weight. When the content of the inorganic fine particles having small particle sizes is increased, the non-pollution and solar heat reflection effect is improved. Increasing the content of the inorganic fine particles having a large particle size improves the thermal insulation and light weight of the coating film.

In addition, the paint composition having a higher particle content of the inorganic particles contained in the paint composition according to the present invention having a higher particle size is used as an upper layer, and the paint composition having a higher particle content content is formed as a lower layer. In this case, it is possible to obtain a combined effect of the non-pollution of the upper layer, the solar reflection function and the thermal insulation function of the lower layer.

Mica pigment of the mica component of the thin film piece is used in the range of 1 to 40% by weight, preferably 5 to 30% by weight in the paint composition of the present invention, when the content is less than 1% by weight The reflection and the heat shielding performance of the resin are lowered, and when used in excess of 40% by weight, the density of the coating film is increased, thereby lowering the heat insulating property.

Colored pigments can be used in the range of 0.1 to 35% by weight, preferably in the range of 10 to 30% by weight depending on the color, but in order to minimize the absorption and transmission inside the coating film by reflecting the infrared wavelength of sunlight as much as possible, white pigment as a pigment Among them, a rutile titanium dioxide pigment having a high brightness and a high refractive index is most preferred. Although it is possible to use a small amount of coloring pigments for the aesthetics of the coating film, it is advantageous to select and use a small amount of coloring pigments with excellent infrared reflectance because the reflecting effect is inferior to pure white paints. There is no separate restriction on.

In addition, the coating composition according to the present invention may include a solvent and other additive components that have been conventionally used, these are not particularly limited because they do not exhibit the intended function of the present invention. For example, additives such as pigment wetting agents, dispersants, precipitation inhibitors, color separation agents, film formation inhibitors, antifoaming agents, antifoaming agents, desiccants, curing accelerators, flow inhibitors, plasticizers, coating smoothing agents, electrical resistance regulators, anti-rust agents, sunscreen agents, and the like. However, it can be applied without limitation in the type and usage.

In addition, a solvent can be selected and used according to the kind of binder. For example, all kinds of solvents such as water, oils, aliphatic hydrocarbons, aromatic hydrocarbons, alcohols, esters, ketones, glycols, etc. may be mixed and used in one or more types. It is possible.

Hereinafter, the present invention will be described in more detail as follows, but the present invention is not limited to the following examples.

Example 1

Synthetic resin emulsion non-polluting solar thermal insulation coating composition according to the present invention was prepared by mixing acrylic synthetic resin emulsion resin as a binder in the following raw materials and ingredient ratios.                     

Ingredient Content (% by weight) Raw material name (brand name)  Acrylic Synthetic Resin Emulsion 35.0  Eurex M-500 (Youngnam Hwaseong)  solvent 10.0  Ion exchange water  Coating Melt 7.0  Butyl Cellosolve  Dispersant 0.5  Desperate Wai-Kai (Bi-Kai-Kemi)  corrector 0.5  Ammonia Water (14%)  Pigmentation Pigment 15.0  Rutile Titanium Dioxide  Inorganic fine particles (1-40㎛) 10.0 Sphercell (Porters Industry) ^a)  Mineral Fine Particles (50 ~ 300㎛) 15.0 Skylight K1 (Three M) ^b)  Mica pigment 5.0  Double Maintenance 325 Mica (Once Specialty Minerals)  Thickener 1.0  Acrisol LM-5 (Rohm and Haas)  Cryoprotectants 1.0  Propylene glycol Sum 100.0  a) Break strength 10,000 psi, Bubble spherical borosilicate glass b) Break strength 250 psi, Bubble spherical borosilicate glass

Example 2

A non-water-dispersible acrylic synthetic resin non-polluting solar thermal insulating coating composition according to the present invention was prepared by mixing the non-water-dispersible (NAD) acrylic synthetic resin as a binder in the following raw materials and ingredient ratios.

Ingredient Content (% by weight) Raw material name (brand name)  Non Water Dispersible Acrylic Resin-1 10.0  Akridic A-1302 (Dai's)  Non Water Dispersible Acrylic Resin-2 22.0  Akridic A-1302 (Dai's)  Solvent-1 13.0  Hansol (Southeast Oil Painting)  Solvent-2 3.0  Cocosol 100  Dispersant 0.4  Fuka -44 (Fka chemicals)  Pigmentation Pigment 19.0  Rutile Titanium Dioxide  Inorganic fine particles (1-40㎛) 12.0 Sphercell (Porters Industry) ^a)  Mineral Fine Particles (50 ~ 300㎛) 12.0 Q-Cell 7023 (Picto Australian) ^b)  Mica pigment 8.0  Double Maintenance 325 Mica (Once Specialty Minerals)  Antifoam 0.5  Fuka-20 (Fka chemicals)  Coating film surface modifier 0.1  Biwai-300 Sum 100.0  a) Break strength 10,000 psi, Bubble spherical borosilicate glass b) Break strength 250 psi, Bubble spherical borosilicate glass

Example 3

Styrene-modified alkyd synthetic resin was used as a binder to mix the raw materials and ingredient ratios as shown in Table 3 to prepare a synthetic resin natural drying type alkyd non-polluting solar thermal insulation coating composition according to the present invention.

Ingredient Content (% by weight) Raw material name (brand name)  Natural Dry Alkyd Resin 40.0  Styrene-modified alkyd resins (60% solids)  solvent 10.0  Xylene  Dispersant 0.5  Anti-Terayu (Bikei-Kemi)  Pigmentation Pigment 18.0  Rutile Titanium Dioxide  Inorganic fine particles (1-40㎛) 10.0 Sphercell (Porters Industry) ^a)  Mineral Fine Particles (50 ~ 300㎛) 14.0 Scotchlite K20 (Three M) ^b)  Mica pigment 4.0  Double Maintenance 325 Mica (Once Specialty Minerals)  Plasticizer 2.0  Benzylbutyl phthalate  Surface drying inhibitors 0.3  Methyl ethyl ketoxime  Drying accelerator 1.0  Mixing dryer  Coating film surface modifier 0.2  Biwai-300 Sum 100.0  a) Break strength 10,000 psi, Bubble spherical borosilicate glass b) Break strength 250 psi, Bubble spherical borosilicate glass

Comparative Example 1

A synthetic resin emulsion coating composition was prepared by mixing acrylic synthetic resin emulsion resin as a binder in the following raw materials and ingredient ratios.

Ingredient Usage (% by weight) Raw material name (brand name) Acrylic Synthetic Resin Emulsion 41.0 Eurex M-500 (Youngnam Hwaseong) solvent 11.0 Ion exchange water Coating film adhesive 8.5 Butyl Cellosolve Dispersant 0.5 Disperby Wai-K corrector 0.5 Ammonia Water (14%) Antifoam 0.5 Biwaikei-020 Pigmentation Pigment 20.0 Rutile Titanium Dioxide Sieving Pigment-1 8.0 Aluminum silicate Sieving Pigment-2 8.0 Magnesium silicate Thickener 1.0 Acrisol LM-5 (Rohm and Haas) Cryoprotectants 1.0 Propylene glycol Sum 100.0

Comparative Example 2

A non-water-dispersed acrylic synthetic resin was used as a binder and mixed in the following raw materials and component ratios to prepare a non-water-dispersible acrylic synthetic resin coating composition.

Ingredient Content (% by weight) Raw material name (brand name)  Non Water Dispersible Acrylic Resin-1 12.0  Akridic A-1302 (Dai's)  Non Water Dispersible Acrylic Resin-2 25.0  Akridic A-1302 (Dai's)  Solvent-1 15.0  Hansol (Southeast Oil Painting)  Solvent-2 3.0  Cocosol 100  Dispersant 0.4  Fuka -44 (Fka chemicals)  Pigmentation Pigment 19.0  Rutile Titanium Dioxide  Sieving pigment 5.0  Magnesium silicate  Mineral Foam Pigment (50 ~ 300㎛) 20.0  Q-Cell 7023 (Picto Australia)  Antifoam 0.5  Fuka-20 (Fka chemicals)  Coating film surface modifier 0.1  Biwai-300 Sum 100.0

Comparative Example 3

Styrene-modified alkyd synthetic resin was used as a binder to mix the raw materials and ingredient ratios as shown in Table 6 to prepare a synthetic resin natural dry alkyd coating composition.

Ingredient Content (% by weight) Raw material name (brand name)  Natural Dry Alkyd Resin 47.0  Styrene-modified alkyd resins (60% solids)  solvent 14.0  Xylene  Dispersant 0.5  Anti-Terayu (Bikei-Kemi)  Pigmentation Pigment 20.0  Rutile Titanium Dioxide  Mineral Foam Pigment (50 ~ 300㎛) 15.0  Scotchlite K20 (Three M)  Plasticizer 2.0  Benzylbutyl phthalate  Surface drying inhibitors 0.3  Methyl ethyl ketoxime  Drying accelerator 1.0  Mixing dryer  Coating surface modifier 0.2  Biwaikei-307 Sum 100.0

In order to confirm the characteristic of each coating composition obtained by said Examples 1-3 and Comparative Examples 1-3, the coating film was formed for each composition, and the physical property of the formed coating film was tested as follows.

Test Example 1 Comparative Test of Non-Pollution Effect

In order to evaluate the non-polluting effect, carbon pollutant evaluation test showing test results close to outdoor exposure pollution was conducted. The test conditions were obtained by coating the coating compositions of Examples 1-3 and Comparative Examples 1-3 on a cold-rolled steel sheet having a width of 22 cm and a length of 22 cm, respectively, so as to have a dry coating thickness of 500 µm and drying them for 7 days. Later, 10% carbon black aqueous solution dispersed in water was applied by air spray, and left at 40 ° C. for 1 hour. After washing the contaminated area with soapy water and a washing sponge, the color difference between the initial specimens was confirmed. The results are shown in Table 7 below.

division Example Comparative example One 2 3 One 2 3 Color change (ΔE) 2.11 1.39 2.20 42.58 12.35 9.42

Test Example 2: Comparison of Solar Blocking and Insulation Effects

Insulation boxes of 30 cm in width, height, and height, respectively, were made of gypsum board having a thickness of 1 cm, and the inside of the box was given a insulation function of 5 cm thick styrofoam.

Seal the specimen on the top of the box so that no outside air is circulated, and irradiate nine infrared lamps with a similar effect to the wavelength of the sunlight on the upper 40 cm of the specimen. The temperature change of was measured. At this time, an infrared lamp (GE company, E27 screw base, 250W / 235 ~ 245V / 127 (D) * 85 (L) mm, 500 ~ 3000 nm wavelength) was used.
Table 8 below is a test result confirming the solar thermal barrier and thermal insulation effect on the initial specimens before coating the coating compositions of Examples 1-3 and Comparative Examples 1-3. In addition, Table 9 below is a test in which the coating composition of Examples 1 to 3 and Comparative Examples 1 to 3 were coated on the initial specimen described above to confirm the solar thermal barrier and thermal insulation effect on the specimen. The result is.

Comparative test results of solar thermal barrier and insulation effect on initial specimen Elapsed time Example Comparative example One 2 3 One 2 3 Early 20.0 ℃ 20.0 ℃ 20.0 ℃ 20.0 ℃ 20.0 ℃ 20.0 ℃ 10 minutes 26.8 ℃ 27.2 ℃ 27.5 ℃ 34.8 ℃ 28.5 ℃ 29.6 ℃ 20 minutes 32.9 ℃ 33.6 ℃ 33.1 ℃ 44.8 ℃ 35.5 ℃ 36.2 ℃ 30 minutes 37.5 ℃ 39.6 ℃ 38.2 ℃ 54.5 ℃ 42.7 ℃ 43.3 ℃ 40 mins 42.8 ℃ 44.9 ℃ 44.1 ℃ 60.8 ℃ 47.1 ℃ 48.1 ℃ 50 minutes 46.7 ℃ 47.8 ℃ 47.5 ℃ 67.1 ℃ 50.9 ℃ 51.7 ℃ 60 mins 49.6 ℃ 51.2 ℃ 52.4 ℃ 71.1 ℃ 54.7 ℃ 55.3 ℃

Comparative test results of solar thermal barrier and insulation effect on specimens with non-polluting coating Elapsed time Example Comparative Example One 2 3 One 2 3 Early 20.0 ℃ 20.0 ℃ 20.0 ℃ 20.0 ℃ 20.0 ℃ 20.0 ℃ 10 minutes 29.1 ℃ 28.2 ℃ 29.5 ℃ 44.8 ℃ 37.5 ℃ 36.2 ℃ 20 minutes 35.7 ℃ 34.6 ℃ 36.1 ℃ 57.3 ℃ 49.8 ℃ 46.5 ℃ 30 minutes 42.2 ℃ 40.6 ℃ 44.2 ℃ 71.6 ℃ 58.9 ℃ 55.7 ℃ 40 mins 47.9 ℃ 46.2 ℃ 50.1 ℃ 82.3 ℃ 66.2 ℃ 62.3 ℃ 50 minutes 53.2 ℃ 51.8 ℃ 56.1 ℃ 93.4 ℃ 75.6 ℃ 70.5 ℃ 60 mins 59.3 ℃ 57.4 ℃ 62.1 ℃ 104.1 ℃ 84.2 ℃ 78.4 ℃

As described above, the non-polluting solar thermal insulation coating composition according to the present invention is superior to the conventional solar thermal insulation coating composition, as well as excellent in the solar heat shielding effect and thermal insulation effect, and excellent resistance to contamination, the existing technology is Compared to the degradation of performance due to the contamination of the coating film, it can be seen that it is possible to effectively maintain the excellent solar heat shielding and thermal insulation effect even in the outdoors directly exposed to sunlight.

As a result, the composition according to the present invention can be confirmed that it can exert excellent performance for a long time by applying to various buildings, facilities, equipment, parts, etc. that require the blocking and insulation of sunlight.

Claims (6)

delete 10 to 80 wt% binder; 1 to 45% by weight of bubble-shaped spherical inorganic fine particles having an average particle size of 1 to 40 µm and a high hardness of 10,000 to 100,000 psi of breaking strength; 5 to 50% by weight of bubble-shaped spherical inorganic fine particles having an average particle size of 50 to 300 µm; Mica pigment 1-40 weight% of the mica component of a thin film piece; And 0.1-35 weight% of pigmented pigments; Non-polluting heat shield heat insulating coating composition, characterized in that it comprises a. The non-polluting sunscreen coating composition according to claim 2, wherein the inorganic fine particles are selected from borosilicate glass, silicate ceramics, and silica alumina ceramics. The non-polluting sunscreen coating composition according to claim 2, wherein the coloring pigment is a rutile titanium dioxide pigment. 10 to 80 wt% binder; 1 to 45% by weight of bubble-shaped spherical inorganic fine particles having an average particle size of 1 to 40 µm and a high hardness of 10,000 to 100,000 psi of breaking strength; 5 to 50% by weight of bubble-shaped spherical inorganic fine particles having an average particle size of 50 to 300 µm; Mica pigment 1-40 weight% of the mica component of a thin film piece; And 0.1-35 weight% of pigmented pigments; Non-polluting heat shield thermal insulation coating, characterized in that the coating with a paint composition comprising a. The non-polluting solar heat according to claim 5, wherein the coating composition having a higher proportion of the inorganic fine particles of 1 to 40 µm and the coating composition having a higher proportion of the inorganic fine particles of 50 to 300 µm are separately prepared and coated in a multilayer. Barrier insulation coating.