KR101019498B1 - Insulation Film contained Tungsten Bronze Compound and Method of Manufacturing The Same - Google Patents

Abstract

The present invention relates to a thermal barrier film in which a heat _shield layer using an infrared shielding agent is formed, in particular, A (B _(X≤0.67) , B ' _{(1- X ≥ 0.33)} ) O ₃ , A (B _{(X ≤ 0.33)} , B ' _{(1-X ≥ 0.67)} ) Tungsten bronze compound forming a _pervosky structure of the form of O ₃ synthesized, thus synthesized tungsten bronze compound By utilizing the fine particle size of less than 20nm, the dispersion sol having an average dispersion particle size of 30 ~ 40nm and the coating sol using the same are formed and coated on the base layer, which shows no haze, high transparency, and high infrared ray blocking property. It relates to a thermal barrier film containing a tungsten bronze compound having a method for producing the same.

Thermal barrier film, tungsten bronze, pervoskyite structure

Description

Insulation Film contained Tungsten Bronze Compound and Method of Manufacturing The Same}

The present invention relates to a thermal barrier film in which a heat _shield layer using an infrared shielding agent is formed, in particular, A (B _(X≤0.67) , B ' _{(1- X ≥ 0.33)} ) O ₃ , A (B _{(X ≤ 0.33)} , B ' _{(1-X ≥ 0.67)} ) Tungsten bronze compound forming a _pervosky structure of the form of O ₃ synthesized, thus synthesized tungsten bronze compound By utilizing the fine particle size of less than 20nm, the dispersion sol having an average dispersion particle size of 30 ~ 40nm and the coating sol using the same are formed and coated on the base layer, which shows no haze, high transparency, and high infrared ray blocking property. It relates to a thermal barrier film containing a tungsten bronze compound having a method for producing the same.

In general, inorganic oxides used as thermal barrier materials have excellent durability and high thermal barrier properties, but their application range is limited due to their low visible light transmittance. Inorganic oxides include antimony tin oxide (ATO), indium tin oxide (ITO), silica dioxide (SiO ₂ ), alumina trioxide (Al ₂ O _{3 ),} molybdenum trioxide (MoO ₃ ), and niobium pentoxide (Nb ₂ O). ₅ ), vanadium pentoxide (V ₂ O ₅ ), tungsten bronze (Tungsten Bronze), etc. are used. Among them, the most commonly used inorganic oxides having good infrared blocking properties are antimony tin oxide (ATO) and indium tin oxide. (ITO) and Tungsten Bronze.

ATO is cheaper than ITO and is generally used in thermal barrier films requiring visible light transmittance. However, the near-infrared absorption characteristic starts absorbing at 1500nm and tilts up to 2000nm, and it is not possible to block infrared rays completely. That is, the amount of input is limited in order to show high visible light. If the filling amount is increased to show high near-infrared rays, the visible light drops considerably to 40-50%, and the excessive inorganic content causes secondary problems of the thermal barrier coating layer (coating layer: crack, adhesion loss, cloudiness, change over time). Cause As described above, even in the case of ATO having a particle size of 10-20 nm, there is a problem in that the near-infrared ray blocking characteristic compared to visible light has its limitations, and thus it cannot be used for the application range and the manufacture of high-performance thermal barrier film.

ITO shows higher visible light transmittance and infrared ray blocking properties than ATO. However, indium prices are well known as the world's most expensive raw materials, and many IT companies are finding a substitute for ITO, and using such expensive raw materials in thermal barrier film production is a big burden. There is a problem.

In addition, ITO and ATO nanoparticles are prepared through a very difficult process for the synthesis of inorganic oxides, in particular, indium tin oxide (ITO (OH)) and antimony tin hydroxide (ATO (ATO) prepared by the sol-gel method and the atutoclave method. OH)) must be fired. Firing takes place a total of two times. Specifically, first firing is performed in the air at 300 to 400, and then secondary hydrogen reduction firing. At this time, hydrogen gas (gas) and an inert gas are mixed to reduce the firing. In this case, even if a little oxygen is added, the possibility of explosion is very high, which may lead to a large accident. Equipment Gas-fired kilns are also quite expensive. As described above, the production of antimony tin oxide (ATO) and indium tin oxide (ITO) always has a problem of stability, and equipment also has a problem that requires expensive special equipment.

Tungsten bronze is a tungsten trioxide, its basic structure is a wide band gap oxide. It is known that there is little absorption of light in the visible region and no free electrons exist in the structure. Accordingly, a form in which a small amount of oxygen is reduced, or a form in which a positive element such as Na is added to tungsten trioxide generally has a perboscatite structure (ABO ₃ ). Tungsten bronze has a strong absorption of light of more than about 800nm wavelength, but light in the wavelength range of human sense of about 380 ~ 780nm wavelength is weak absorption is being studied as a visible light transmission material. Tungsten bronze compound is known to about 50,000 kinds, tungsten bronze compound showing the dual infrared blocking properties in the form of A _x W ₁ O _y , A _x is Group 1 ~ Group 2 Alkali and alkaline earth metal elements, W ₁ is Tungsten, O _y consists of oxygen. However, in most patents and literature, the particle size is less than 100 nm, which means the primary particle size, which is 100 nm or more when the primary powder is 100 nm. Dispersing sol of 100nm or more has a haze and shows the scattering phenomenon clearly, and when it is made into the final film, it appears to be cloudy as scattering phenomenon. Therefore, there is a need for a high-quality thermal barrier film having high transparency or no haze in a thermal barrier film using tungsten bronze.

In the method of synthesizing tungsten bronze, coprecipitation and solid phase reaction are most common. The solid-phase reaction method is the most typical method for preparing perovskite compounds. The solid material is simply mixed in a solid state with a raw material containing a tungsten element and a raw material of a compound containing carbonic acid and an inert element having a positive element and calcining at a high temperature. It is obtained by melting two compounds at high temperature. This method cannot be a quantitative elemental compound, and is usually obtained in the form of a lump larger than the micron size. In general, optical materials require very precise quantitative ratios of elements, and if there is a slight error, most of them exhibit different characteristics or do not have target characteristics, so the solid-phase reaction cannot solve this problem. There is a problem.

In the method of synthesizing tungsten bronze, the coprecipitation method is a method in which a starting material is dissolved in a specific solvent to be in a solution state, and different elements are present in the solution and coprecipitation is simultaneously performed by charge or solubility difference. At this time, the elements present in the solution also contain elements that appear to be impurities in the starting material, so it is difficult to remove these impurities, and it is difficult to control the particle size so that they cannot become nanoparticles, and the quality of the final product is degraded. There is a problem.

The present invention has been made to solve the above problems,

An object of the present invention is a thermal barrier film having a thermal barrier layer formed on one surface of the base layer, the thermal barrier layer comprises a tungsten bronze compound, the tungsten bronze compound is A (B _(X≤0.67) , B ' _{(1- X ≧ 0.33)} ) O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1-X ≧ 0.67)} ) O _{3 to} form a _pervoskyte structure, wherein A comprises an alkali metal to an alkaline earth metal The B and B 'is to provide a thermal barrier film containing a tungsten bronze compound having no haze, excellent optical properties and environmentally friendly by including at least one element or compound selected from transition metals.

Another object of the present invention is to produce a tungsten bronze compound containing a tungsten bronze compound according to the present invention, by producing a tungsten bronze compound by a polyol synthesis method using a microwave as a heat source to shorten the synthesis process time, reduce the organic solvent It is possible to provide a thermal barrier film containing a tungsten bronze compound, which can be eco-friendly and obtains uniform nano-sized particles.

Still another object of the present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, wherein the tungsten bronze compound is subjected to primary calcination at a temperature of 200 to 500 ° C. to remove hydroxyl groups, and the hexagonal of the tungsten bronze compound. It is to provide a thermal barrier film containing a tungsten bronze compound characterized by forming a crystallinity.

It is still another object of the present invention to provide a tungsten bronze compound containing a tungsten bronze compound according to the present invention, wherein the tungsten bronze compound is subjected to secondary reduction firing by adding a liquid reducing agent to induce crystal defects of the tungsten bronze compound in the working phase. It is to provide a thermal barrier film containing a tungsten bronze compound characterized by reducing the risk and utilizing existing plastic equipment.

Another object of the present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound is formed in the form of a tungsten bronze compound dispersion sol, the tungsten bronze compound dispersion sol is 0.5 ~ 1 weight %, Organic solvent 70 ~ 80% by weight, tungsten bronze compound powder containing 20 ~ 30% by weight of the thermal barrier film containing a tungsten bronze compound, characterized in that it exhibits excellent optical properties and does not gel with sufficient stability To provide.

Another object of the present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound dispersion sol is formed in the form of a tungsten bronze compound coating sol, the tungsten bronze compound coating sol is a tungsten bronze compound Tungsten bronze, characterized by including 40 to 50% by weight of the dissolving sol, 40 to 50% by weight of the photopolymer, and 10 to 20% by weight of the organic solvent to enhance the bonding strength with the base layer and to finely control the thickness of the coating film. It is to provide a thermal barrier film containing a compound.

Another object of the present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound coating sol is any one of the microgravure coating, knife coating and roll-to-roll coating method on the substrate layer To provide a thermal barrier film containing a tungsten bronze compound, characterized in that to be coated with, UV irradiation to form a thermal barrier layer to obtain a flat coating surface and improve productivity.

Still another object of the present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, wherein the thermal barrier layer further includes a pressure-sensitive adhesive layer on a surface not in contact with the substrate layer, such as in a glass of a building or a vehicle. It is to provide a thermal barrier film containing a tungsten bronze compound, characterized in that the adhesion.

Still another object of the present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, wherein the adhesive layer may further include a release paper on a surface not in contact with the thermal barrier layer to protect an external surface. It is to provide a thermal barrier film containing a tungsten bronze compound characterized by.

Another object of the present invention is to use A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1-X≥ 0.67)} step of preparing a tungsten bronze compound for preparing a tungsten bronze compound having a perovskite structure of the O ₃ form, and calcining the tungsten bronze compound at a temperature of 200 ~ 500 ℃ to remove the hydroxyl group and hexa of the tungsten bronze compound After the first calcination step to form the gonal crystallinity, the second reduction firing step to induce the crystal defect of the tungsten bronze compound by injecting a liquid reducing agent to the tungsten bronze compound from which the hydroxyl group is removed, and the second reduction firing step A tungsten bronze compound dispersing sol manufacturing step of preparing tungsten bronze compound powder in the form of a dispersion sol, a tungsten bronze compound coating sol manufacturing step of preparing the tungsten bronze compound dissolving sol in a form of a sol, and the tongue The thermal barrier layer coating step of forming a thermal barrier layer by coating the surface of the base layer with a sten bronze compound coating sol can produce a thermal barrier film containing a tungsten bronze compound having no haze, excellent optical properties, and environment-friendly. It is also to provide an economical method of manufacturing thermal barrier films containing tungsten bronze compounds by reducing operational risks and utilizing existing firing equipment.

Another object of the present invention is a method for producing a thermal barrier film containing a tungsten bronze compound according to the present invention, the polyol synthesis method used in the tungsten bronze compound manufacturing step is 120 seconds ~ 180 using a microwave wave as a heat source The method of manufacturing a thermal barrier film containing a tungsten bronze compound, characterized in that it can shorten the synthesis process time and reduce the organic solvent by irradiating in the range of seconds to obtain eco-friendly, uniform nano-sized particles. To provide.

Another object of the present invention is a method for producing a tungsten bronze compound containing tungsten bronze compound according to the present invention, the tungsten bronze compound dispersion sol in the manufacturing step of the tungsten bronze compound dispersion sol dispersing agent 0.5 ~ 1% by weight, organic solvent By providing 70 to 80% by weight, tungsten bronze compound powder 20 to 30% by weight to provide a method for producing a thermal barrier film containing a tungsten bronze compound, characterized in that it exhibits excellent optical properties and does not gel with sufficient stability. It is.

Another object of the present invention is a method for producing a tungsten bronze compound containing a tungsten bronze compound according to the present invention, the tungsten bronze compound coating sol in the tungsten bronze compound coating sol manufacturing step is tungsten bronze compound dispersion sol 40 ~ 50 weight Thermal barrier containing tungsten bronze compound, characterized in that it can improve the bonding strength with the substrate layer and finely control the coating film thickness by including%, 40-50% by weight, 10-20% by weight of the organic solvent It is to provide a method for producing a film.

Still another object of the present invention is a method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention, further comprising a pressure-sensitive adhesive layer coating step of forming an adhesive layer on a surface not in contact with the base layer of the thermal barrier layer. It is to provide a method for producing a thermal barrier film containing a tungsten bronze compound, characterized in that the adhesion to glass, such as buildings or vehicles by including.

Still another object of the present invention is a method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention, further comprising a release paper attaching step of attaching a release paper to a surface not in contact with the thermal barrier layer of the adhesive layer. The present invention provides a method for producing a thermal barrier film containing a tungsten bronze compound, which can protect the outer surface of the adhesive layer.

The thermal barrier film containing the tungsten bronze compound and its manufacturing method for achieving the above object of the present invention includes the following configuration.

According to an embodiment of the present invention, the thermal barrier film containing a tungsten bronze compound according to the present invention in the thermal barrier film formed with a thermal barrier layer on one surface of the base layer, the thermal barrier layer comprises a tungsten bronze compound, The tungsten bronze compound is a _{ferrite in the form} of A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1-X ≧ 0.67)} ) O ₃ Form a boscaite structure, wherein A includes an alkali metal to an alkaline earth metal, and B and B 'include one or more elements or compounds selected from transition metals.

According to another embodiment of the present invention, the tungsten bronze compound in the thermal barrier film containing the tungsten bronze compound according to the present invention is characterized in that the polyol synthesis method.

According to another embodiment of the present invention, in the thermal barrier film containing the tungsten bronze compound according to the present invention, the polyol synthesis method is characterized by using a microwave wave as a heat source.

According to another embodiment of the present invention, in the thermal barrier film containing the tungsten bronze compound according to the present invention, the polyol synthesis method is characterized in that for irradiating the microwave wave in the range of 120 seconds to 180 seconds.

According to another embodiment of the present invention, in the thermal barrier film containing the tungsten bronze compound according to the present invention, the tungsten bronze compound is subjected to primary calcination in the temperature range of 200 ~ 500 ℃ to remove the hydroxyl group and the It is characterized by forming hexagonal crystallinity.

According to another embodiment of the present invention, in the thermal barrier film containing the tungsten bronze compound according to the present invention, the tungsten bronze compound is added to the liquid reducing agent to make the secondary reduction firing to induce crystal defects of the tungsten bronze compound It is characterized by.

According to another embodiment of the present invention, in the thermal barrier film containing the tungsten bronze compound according to the present invention, the secondary reduction firing is characterized in that the firing for 1 to 2 hours at a temperature in the range of 300 ~ 400 ℃.

According to another embodiment of the present invention, in the thermal barrier film containing the tungsten bronze compound according to the present invention, the tungsten bronze compound is formed in the form of a tungsten bronze compound dispersion sol, the tungsten bronze compound dispersion sol is 0.5 ~ It is characterized by comprising 1% by weight, 70 to 80% by weight of the organic solvent, 20 to 30% by weight of tungsten bronze compound powder.

According to another embodiment of the present invention, in the thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound is formed in a tungsten bronze compound dispersion sol form by a ball mill method using zirconium balls do.

According to another embodiment of the present invention, in the thermal barrier film containing the tungsten bronze compound according to the present invention, the tungsten bronze compound dispersion sol is formed in the form of a tungsten bronze compound coating sol, the tungsten bronze compound coating sol is tungsten 40 to 50% by weight of a bronze compound dispersion sol, 40 to 50% by weight of a photopolymer, and 10 to 20% by weight of an organic solvent.

According to another embodiment of the present invention, in the thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound coating sol is any one of a microgravure coating, knife coating and roll-to-roll coating method on the substrate layer It is coated in the manner of, characterized in that to form a thermal barrier by UV irradiation.

According to another embodiment of the present invention, in the thermal barrier film containing a tungsten bronze compound according to the present invention, the thermal barrier layer further comprises an adhesive layer on a surface not in contact with the base layer, such as a building or a vehicle. It is characterized by being able to adhere to glass.

According to another embodiment of the present invention, in the thermal barrier film containing the tungsten bronze compound according to the present invention, the adhesive layer may further include a release paper on the surface not in contact with the thermal barrier layer to protect the external surface. It is characterized by being.

According to another embodiment of the present invention, the method for producing a thermal _barrier film containing a tungsten bronze compound according to the present invention using the polyol synthesis method A (B _(X≤0.67) , B ' _(1-X≥0.33) A tungsten bronze compound preparing step of preparing a tungsten bronze compound having a _pervosky structure of the form of O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1-X ≧ 0.67)} ) O ₃ , and the tungsten bronze compound Calcination in the temperature range of 200 ~ 500 ℃ to remove the hydroxyl group and to form the hexagonal crystallinity of the tungsten bronze compound, and the liquid reducing agent is added to the tungsten bronze compound from which the hydroxyl group is removed A secondary reduction firing step of inducing crystal defects, a tungsten bronze compound dispersion sol manufacturing step of preparing a tungsten bronze compound powder which has undergone the secondary reduction firing step in the form of a dispersion sol, and the tungsten bronze compound powder And a tungsten bronze-coated sol prepared compound to prepare a coating sol form a sol, and the tungsten bronze-compound coating sol characterized in that it comprises a heat prevention layer coating step of coating the surface of the substrate layer to form the heat prevention layer.

According to another embodiment of the present invention, the polyol synthesis method used in the tungsten bronze compound manufacturing step in the method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention 120 seconds using a microwave wave as a heat source Irradiation in the range of ˜180 seconds.

According to another embodiment of the present invention, the tungsten bronze compound dispersion sol in the manufacturing method of the thermal barrier film containing tungsten bronze compound according to the present invention is a tungsten bronze compound dispersion sol is 0.5 to 1% by weight, It characterized in that it comprises 70 to 80% by weight of the organic solvent, 20 to 30% by weight of tungsten bronze compound powder.

According to another embodiment of the present invention, the tungsten bronze compound coating sol in the tungsten bronze compound coating sol manufacturing step in the method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention is tungsten bronze compound dispersion sol 40 ~ 50% by weight, photopolymer 40 to 50% by weight, characterized in that it comprises 10 to 20% by weight of the organic solvent.

According to another embodiment of the present invention, in the method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention does not contact with the base layer of the thermal barrier layer so as to adhere to the glass, such as buildings or vehicles It characterized in that it further comprises an adhesive layer coating step of forming an adhesive layer on the surface.

According to another embodiment of the present invention, in the method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention in order not to contact the thermal barrier layer of the adhesive layer to protect the outer surface of the adhesive layer. It characterized in that it further comprises a release paper attaching step of attaching the release paper on the surface.

The present invention can achieve the following effects by the configuration, combination, and use relationship described above with the present embodiment.

The present invention provides a heat shielding film having a heat shielding layer formed on one surface of a substrate layer, wherein the heat shielding layer includes a tungsten bronze compound, and the tungsten bronze compound is A (B _{(X ≦ 0.67)} , B ′ _{(1-X≥ 0.33)} forms a _pervosky structure of the form O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1-X ≧ 0.67)} ) O ₃ , wherein A comprises an alkali metal to an alkaline earth metal and B , B 'includes at least one element or compound selected from transition metals to obtain a thermal barrier film containing a tungsten bronze compound having no haze, excellent optical properties, and environment-friendly.

In the thermal barrier film containing the tungsten bronze compound according to the present invention, the tungsten bronze compound is produced by a polyol synthesis method using a microwave wave as a heat source, thereby shortening the synthesis process time and reducing an organic solvent. In order to achieve uniform nano-sized particles.

The present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound is subjected to the first calcination in the temperature range of 200 ~ 500 ℃ to remove the hydroxyl group and to form the hexagonal crystallinity of the tungsten bronze compound To provide the effect.

The present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound is reduced by reducing the operational risk by inducing crystal defects of the tungsten bronze compound by the secondary reduction firing by adding a liquid reducing agent Provides the effect of utilizing the firing equipment of the.

The present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound is formed in the form of a tungsten bronze compound dispersion sol, the tungsten bronze compound dispersion sol is 0.5 to 1% by weight dispersant, organic solvent By including 70 to 80% by weight, tungsten bronze compound powder 20 to 30% by weight to provide excellent optical properties as well as provides the effect of not gelling with sufficient stability.

The present invention is a thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound dispersion sol is formed in the form of a tungsten bronze compound coating sol, the tungsten bronze compound coating sol 40 ~ tungsten bronze compound dispersion sol By including 50% by weight, 40-50% by weight of the photopolymer, 10-20% by weight of the organic solvent can improve the bonding strength with the substrate layer and provides an effect of finely adjusting the coating film thickness.

In the thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound coating sol is coated on the base layer by any one of a microgravure coating, a knife coating, and a roll-to-roll coating method. UV radiation forms a thermal barrier layer, providing a flat coating surface and improving productivity.

The present invention provides a thermal barrier film containing a tungsten bronze compound according to the present invention, wherein the thermal barrier layer may further include an adhesive layer on a surface which is not in contact with the base layer, and may adhere to glass such as a building or a vehicle. Provide effect.

The present invention provides a thermal barrier film containing a tungsten bronze compound according to the present invention, wherein the adhesive layer further includes a release paper on a surface not in contact with the thermal barrier layer, thereby providing an effect of protecting an external surface.

The present invention uses polyol synthesis method to obtain A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1-X ≧ 0.67} ) O A tungsten bronze compound preparing step of preparing a tungsten bronze compound having a _three- type pervosky structure, and calcining the tungsten bronze compound at a temperature in the range of 200 to 500 ° C. to remove hydroxyl groups and the hexagonal crystallinity of the tungsten bronze compound The primary calcining step to form, the secondary reducing firing step of inducing a crystal defect of the tungsten bronze compound by injecting a liquid reducing agent into the tungsten bronze compound from which the hydroxyl group is removed, and the tungsten bronze compound powder subjected to the second reducing firing step A tungsten bronze compound dissolving sol manufacturing step of preparing a sol in the form of a dispersion sol, a tungsten bronze compound coating sol manufacturing step of preparing the tungsten bronze compound in a sol form, and a tungsten bronze compound The thermal barrier coating step of forming a thermal barrier layer by coating a water coating sol on the surface of the base layer can produce a thermal barrier film containing a tungsten bronze compound free of haze, excellent optical properties, and environment-friendly. It can reduce the risk of phase and utilize existing sintering equipment to provide an economical manufacturing method of thermal barrier film containing tungsten bronze compound.

The present invention is a method for producing a thermal barrier film containing a tungsten bronze compound according to the present invention, the polyol synthesis method used in the tungsten bronze compound manufacturing step is irradiated in the range of 120 seconds to 180 seconds using a microwave wave as a heat source By shortening the synthesis process, it is possible to reduce the organic solvent to meet the eco-friendly, and provides the effect of obtaining a uniform nano-sized particles.

The present invention provides a tungsten bronze compound-dispersed sol in the manufacturing method of the thermal barrier film containing the tungsten bronze compound according to the present invention, the tungsten bronze compound dispersion sol is 0.5 to 1% by weight of the dispersant, 70 to 80 weight of the organic solvent %, 20-30% by weight of tungsten bronze compound powder to provide excellent optical properties as well as provide the effect of not gelling with sufficient stability.

The present invention is a method for producing a thermal barrier film containing a tungsten bronze compound according to the present invention, the tungsten bronze compound coating sol in the tungsten bronze compound coating sol manufacturing step is 40 to 50% by weight tungsten bronze compound dispersion sol, photopolymer By including 40 to 50% by weight, 10 to 20% by weight of the organic solvent can improve the bonding strength with the substrate layer and provides an effect of finely adjusting the thickness of the coating film.

The present invention is a method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention, by further comprising a pressure-sensitive adhesive layer coating step of forming a pressure-sensitive adhesive layer on the surface not in contact with the base layer of the thermal barrier layer Or it provides an effect that can be bonded to the glass, such as a vehicle.

The present invention provides a method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention, further comprising a release paper attaching step of attaching a release paper to a surface not in contact with the thermal barrier layer of the adhesive layer of the adhesive layer Provides the effect of protecting the external surface.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of a thermal barrier film and a method for producing the tungsten bronze compound according to the present invention will be described in detail.

1 is a cross-sectional view of a thermal barrier film containing a tungsten bronze compound according to an embodiment of the present invention, Figure 2 is a cross-sectional view of a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention, Figure 3 Is a cross-sectional view of a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention.

Referring to Figure 1, the thermal barrier film containing a tungsten bronze compound according to an embodiment of the present invention in the thermal barrier film formed with a thermal barrier layer 20 on one surface of the base layer 10, the thermal barrier layer 20 ) Includes a tungsten bronze compound, wherein the tungsten bronze compound includes A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1- X≥0.67)} ) O ₃ form a _pervoskyite structure, wherein A includes an alkali metal to an alkaline earth metal, and B and B 'include one or more elements or compounds selected from transition metals Shall be.

The base layer 10 is coated with a heat shield layer 20 on one surface thereof to support and protect the heat shield layer 20. The base layer 10 may include PET, polycarbonate, nylon, PP and the like are used, but preferably PET is used. In general, when the thermal barrier layer 20 is coated on the base layer 10 and subjected to hot air drying and UV irradiation, the substrate passes through a temperature of 120 or more. In this case, the general plastic substrate has a heat deformation temperature and the substrate is above the heat deformation temperature. There is a problem with the transformation itself. Therefore, PET is most preferred as the plastic substrate having the highest heat deflection temperature.

The thermal barrier layer 20 is coated on one surface of the base layer 10 to prevent radiant heat from being introduced or released. In the present invention, the thermal barrier layer 20 includes a tungsten bronze compound, and the tungsten bronze The compound is a _{pervoskyite in the form} of A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1-X ≧ 0.67)} ) O ₃ Form a structure, wherein A comprises an alkali metal to an alkaline earth metal, and B and B 'are transition metals (Mg, Zr, Cr, Mn, Fe, Ru, Co, Rh, Ir, Ni, Pd, Pt, Cu). It is characterized in that it comprises at least one element or compound selected from Ag, Au, Zn, Cd, Al, Ga, In, Ti, Si, Ge, Sn, Pb, W. As mentioned in the prior art section, the existing basic structure of the tungsten bronze compound is in the form of A _x W ₁ O _y , A _x is a group 1 to 2 group, alkali and alkaline metal elements, W ₁ is tungsten, O _y Consists of oxygen. However, in most patents and literature, the particle size is less than 100 nm, which means the primary particle size, which is 100 nm or more when the primary powder is 100 nm. Dispersing sol of 100nm or more has a haze and shows the scattering phenomenon clearly, and when it is made into the final film, it appears to be cloudy as scattering phenomenon. Therefore, there is a need for a high-quality thermal barrier film having high transparency or no haze in a thermal barrier film using tungsten bronze. However, in the present invention, the basic structure is A (B _(X≤0.67) , B ' _(1-X≥0.33) ) O ₃ , A (B _(X≤0.33) , B' _(1-X≥0.67) ) O ₃ By choosing from, it has an elemental composition that enriches free electrons and exhibits optimal infrared blocking properties. Conventional It is a molecular structure formula proposed in the view that it is easier to control electron resonance and energy bend by adding transition metal in addition to W ₁ tungsten element in A _x W ₁ O _y structure. Therefore, it has a higher visible light transmittance and an infrared ray blocking rate than conventional ATO and ITO nanoparticles, and is 20-30 nm which is much lower than the conventional 100 nm in particle size control which is known as the biggest disadvantage of the conventional tungsten bronze compound. It is possible to manufacture tungsten bronze compound having the size of 100%, thereby eliminating the haze generated at 100nm level, thereby producing high quality thermal barrier film, improving productivity of tungsten bronze compound synthesis, lowering manufacturing cost, and saving energy. Edo will have a fairly high effect.

In addition, in the synthesis of tungsten bronze compounds, polyol synthesis may be used. The polyol synthesis method is a simple method for synthesizing a desired inorganic compound at high pressure and relatively low temperature, and the reactor uses an autoclave device. Microwave waves can be used. In the heat transfer method of polyol synthesis method using microwave waves, a microwave wave is irradiated to a liquid material having a relatively weak binding force, and the dipole of the liquid molecules rotates or translates at a high speed as the polarity changes according to the frequency of the microwave wave. Because of the movement, frictional heat is generated between molecules, and this heating is called dielectric heating. Therefore, in composites with a high or low dielectric constant, microwave waves can selectively penetrate into liquid materials with high dielectric constants and heat them up to the inside of the composites quickly, reducing synthesis time and energy costs, as well as selective heating characteristics. Due to the organic solvent content can be reduced, it can be said to be a very environmentally friendly way to synthesize a solvent.

On the other hand, in synthesizing the precursor of the tungsten bronze compound, the microwave irradiation time is preferably irradiated in the range of 100 seconds to 300 seconds in order to induce sufficient binding and synthesis of the respective precursor compounds, the irradiation time is 100 seconds If less than that, the reactants are properly bonded to prevent nuclear growth, so that the unreacted material may remain, and when it is more than 300 seconds, the nuclear growth of the precursor may increase due to an excessive heat source, thereby preventing the desired nanoparticles from being obtained. It can be irradiated in the range of 120 to 180 seconds.

The tungsten bronze compound thus synthesized is in the state of having a hydroxyl group (-OH), and undergoes primary calcination to completely remove the hydroxyl group and water molecules and form crystallinity of the tungsten bronze compound. At this time, the calcination temperature is preferably maintained in the range of 200 ~ 500 ℃, when the calcination temperature is less than 200 ℃ can not remove the complete hydroxyl group and water molecules, the hydroxyl group and water molecules may remain and become hexagonal crystal phase none. This is because when the particle growth is more than 500 ℃ can not be obtained nanoparticles to provide a cause that can cause haze in the final product, more preferably the primary calcination can be made in the 300 ~ 400 ℃ range.

In addition, the tungsten bronze compound may induce crystal defects of the tungsten bronze compound by adding a liquid reducing agent to secondary reduction firing, and the secondary reduction firing does not use an explosion gas, and there is no explosion risk. Reducing by adding liquid reducing agents (hydrazine, NaBH ₄ , LiAlBH ₄ , hydrazine hydrate, formaldehyde) to give oxygen deficiency to the tungsten bronze compound to form a crystal defect, the final tungsten bronze compound powder is formed in a dark blue do. The use of hydrogen gas not only requires expensive special equipment to inject gas, but if the hydrogen gas injection conditions are not met, it can lead to a big explosion with a little oxygen, which can cause a big accident. Therefore, it is desirable to use the liquid reducing agent in such a way that it is possible to reduce the operational risk and to simply use the existing firing equipment.

In the powder of the tungsten bronze compound according to the present invention, one particle thereof is a nanoparticle, but aggregates with each other, and thus does not exhibit optical properties. Therefore, it should be dispersed only as nanoparticles, but the optical properties will appear. Therefore, it is necessary to prepare a dispersion sol, the composition of the dispersion sol in the present invention comprises a tungsten bronze powder, a dispersant, an organic solvent, the content of tungsten bronze powder in the dispersion sol is preferably 20 to 30% by weight. When the tungsten bronze powder is less than 20% by weight, sufficient optical properties are not exhibited at low thickness during the final coating film formation, and when the tungsten bronze powder is more than 30% by weight, the solids do not have sufficient storage stability due to high solid content, and thus the dispersion sol itself changes with time. There is a disadvantage of gelation. In addition, the dispersant content in the dispersion sol is preferably added to 0.5 to 1% by weight. When the dispersant is less than 0.5% by weight, sufficient dispersing sol cannot be obtained, and when the dispersant is 1% by weight or more, the dispersant may remain on the surface during secondary processing and may cause surface defects.

In addition, the dispersion sol of the tungsten bronze compound according to the present invention may be prepared by a ball mill method, in which the powder and the solvent (organic solvent) to be dispersed are put in a predetermined container, a dispersant is added thereto, and then zirconium beads are added. Zirconium beads, which are put in a very simple and easy way for mass production by turning, apply friction or shear stress to the powder to separate or separate the agglomerated powder from the primary particles little by little.

Meanwhile, the tungsten bronze dispersion sol is formed in the form of a tungsten bronze coating sol before being coated on the base layer 10. The tungsten bronze coating sol according to the present invention includes a tungsten bronze dispersion sol, a binder, and an organic solvent, and a tungsten bronze compound It is preferable to contain 40-50 weight% of dispersion sol, 40-50 weight% of photopolymers, and 10-20 weight% of the organic solvent. If less than 40% by weight of the dissolving sol is reduced the optical properties, while if too much of the binder ratio is lowered because the coating film adhesion or surface scratch resistance may be reduced. In the tungsten bronze sol, the binder facilitates bonding with the plastic film as a base material and also serves to control the thickness of the coating film. The binder used in the present invention is composed of oligomers and monomers and photoinitiators which cause photopolymerization by UV irradiation as photopolymers. In the tungsten bronze coating sol, the organic solvent is methyl ethyl ketone, toluene, ethyl acetate, isopropyl alcohol, ethyl cellosolve, isobutyl alcohol, dimethylformide, ethanol, butyl cellosolve, xylene, 1-octanol, di It may consist of one or two or more selected from ethylene, glycol, nitrovanzene.

The tungsten bronze compound coating sol according to the present invention is coated on the base layer 10 by any one of a microgravure coating, a knife coating and a roll-to-roll coating method, and forms a thermal barrier layer by UV irradiation. In the case of coating through the microgravure coating equipment, the microgravure coating equipment has the advantage of showing the flattened coating surface in the large area coating and the productivity is higher than that of other equipment. The coating film thickness is most preferably 3 ~ 4㎛. When the coating film thickness is 3㎛ or less, the optical properties are not expressed, and the surface scratch resistance is inferior, and when the coating film thickness is 4㎛ or more, a hard UV coating layer is formed, so that the adhesive strength with the substrate may be reduced. Because there is.

Referring to FIG. 2, in the thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention, an adhesive layer 30 is added to a surface of the thermal barrier layer 20 that is not in contact with the base layer 10. Including as it can be bonded to the glass of a building or a vehicle.

The adhesive layer 30 is formed on one surface of the thermal barrier layer 20 serves to bond the thermal barrier film according to the present invention to a glass such as a building or a vehicle, the adhesiveness of the adhesive layer 30 Silver depends mainly on the molecular weight of the polymer chain, the molecular weight distribution, or the amount of molecular structure present, and in particular, it is preferable that the acrylic copolymer has a weight average molecular weight of 800,000 to 200,000. On the other hand, it is preferable that the methacrylate monomer which has a C1-C12 alkyl group is contained by 90 to 99.9 weight% in an acryl-type copolymer. This is because when the methacrylate monomer is less than 90% by weight of the acrylic copolymer, there is a problem in that the initial adhesive strength is lowered, and when it exceeds 99.9% by weight, problems in durability may occur due to the decrease in cohesion.

Referring to FIG. 3, in the thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention, a release paper 40 is added to a surface which is not in contact with the thermal barrier layer 20 of the adhesive layer 30. Including as it can protect the outer surface.

The release paper 40 is formed on one surface of the adhesive layer 30 and serves to protect the outer surface of the adhesive layer 30 until it is adhered to glass such as a building or a vehicle, and the release paper 40 is preferable. PET-based silicone coated film is used. If the silicon coating process is not performed, the release paper 40 is separated when the final thermal barrier film is constructed on glass, because the adhesive layer 30 and the release paper 40 are not separated.

Figure 4 is a block diagram of a method of manufacturing a thermal barrier film containing a tungsten bronze compound according to the present invention, Figure 5 is a block diagram of a method of manufacturing a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention. 6 is a block diagram of a method of manufacturing a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention.

Referring to FIG. 4, a method of manufacturing a thermal _barrier film containing a tungsten bronze compound according to the present invention is A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , using a polyol synthesis method. A tungsten bronze compound preparation step (S1) of preparing a tungsten bronze compound having a _pervosky structure of A (B _{(X ≦ 0.33)} , B ′ _{(1-X ≧ 0.67)} ) O ₃ form and the tungsten bronze compound The calcination in the temperature range of 200 ~ 500 ℃ to remove the hydroxyl group and to form the hexagonal crystallinity of the tungsten bronze compound (S2) and the tungsten bronze by adding a liquid reducing agent to the tungsten bronze compound from which the hydroxyl group is removed A secondary reduction firing step (S3) of inducing crystal defects of the compound, a tungsten bronze compound dispersion sol manufacturing step (S4) of producing a tungsten bronze compound powder subjected to the secondary reduction firing step in the form of a dispersion sol, and the tungsten Bronze Compound Dispersion Sol Tungsten bronze compound coating sol manufacturing step (S5) prepared in the form of a coating sol, and the thermal barrier layer coating step (S6) to form a thermal barrier layer 20 by coating the tungsten bronze compound coating sol on the surface of the base layer 10 Characterized in that it comprises a.

The tungsten bronze compound preparing step (S1) is particularly performed using polyol synthesis method A (B _(X≤0.67) , B ' _(1-X≥0.33) ) O ₃ , A (B _(X≤0.33) , B' _{( 1-X ≧ 0.67)} ) A process for preparing a tungsten bronze compound having a _pervosky structure of the form of O ₃ , wherein the tungsten bronze compound is A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , A (B _{(X ≤ 0.33)} , B ' _{(1-X ≥ 0.67)} ) forms a _pervosky structure of the form O ₃ , wherein A comprises an alkali metal to an alkaline earth metal and the B, B' Transition metals (Mg, Zr, Cr, Mn, Fe, Ru, Co, Rh, Ir, Ni, Pd, Pt, Cu, Ag, Au, Zn, Cd, Al, Ga, In, Ti, Si, Ge, Sn, Pb, W) is characterized in that it comprises one or more elements or compounds selected from the detailed description thereof is as described above will be omitted here to avoid overlapping substrates. In addition, the polyol synthesis method used to prepare the tungsten bronze compound is a simple method of synthesizing the desired inorganic compound at high pressure and relatively low temperature. The reactor uses an autocrab device, and the microwave source is used as a heat source. Although the detailed description thereof is also the same as described above, it will be omitted here in order to avoid redundant descriptions.

In the first calcination step (S2), since the tungsten bronze compound synthesized in the tungsten bronze compound production step (S1) exists in the state where hydroxyl group (-OH) exists, the hydroxyl group and water molecules are completely removed, and the tungsten bronze compound In order to proceed to form the crystallinity of, in particular, the calcination temperature is preferably maintained in the range of 200 ~ 500 ℃, the detailed description thereof as described above will be omitted here in order to avoid overlapping substrates.

The secondary reduction firing step (S3) is a process of inducing crystal defects of the tungsten bronze compound by injecting a liquid reducing agent into the tungsten bronze compound to secondary reduction firing, in particular, the secondary reduction firing step (S3) according to the present invention. ) Does not use explosive hydrogen gas and reduces liquid by adding liquid reducing agents (hydrazine, NaBH ₄ , LiAlBH ₄ , hydrazine hydrate, formaldehyde) without explosion risk. It will be formed, the detailed description thereof is also as described above will be omitted here in order to avoid overlapping.

In the tungsten bronze compound dispersing sol manufacturing step (S4), the powder of the tungsten bronze compound according to the present invention is agglomerated with each other, and thus does not exhibit optical properties. In the process, the composition of the dispersion sol in the present invention comprises tungsten bronze powder, dispersant, organic solvent content of 0.5 to 1% by weight of dispersant, 70 to 80% by weight of organic solvent, 20 to 30% by weight of tungsten bronze compound powder It is preferable to include, the detailed description thereof is also as described above, so it will be omitted here in order to avoid overlapping.

The tungsten bronze compound coating sol manufacturing step (S5) is a process of forming the tungsten bronze dispersion sol in the form of a tungsten bronze coating sol before coating on the base layer 10, the tungsten bronze coating sol according to the present invention is tungsten bronze It includes a dispersion sol, a binder, an organic solvent, the content of which is preferably 40 to 50% by weight tungsten bronze compound dispersion sol, 40 to 50% by weight photopolymer, 10 to 20% by weight organic solvent, Since the description is also the same as described above, it will be omitted here in order to avoid duplication.

In the thermal barrier coating step (S6), the tungsten bronze compound coating sol is coated on the base layer 10 by any one of a microgravure coating, a knife coating, and a roll-to-roll coating method, and UV radiation is formed to form a thermal barrier layer. In the process, the detailed description thereof is also as described above, and will be omitted here to avoid duplicated materials.

Referring to FIG. 5, in the method of manufacturing a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention, the base layer 10 of the thermal barrier layer 20 may be adhered to glass such as a building or a vehicle. It characterized in that it further comprises a pressure-sensitive adhesive layer coating step (S7) to form a pressure-sensitive adhesive layer 30 on the surface that is not in contact with.

The adhesive layer coating step (S7) is a process of forming the adhesive layer 30 on the surface not in contact with the base layer 10 of the thermal barrier layer 20, because the adhesive layer 30 is formed The thermal barrier film containing the tungsten bronze compound according to the present invention can be adhered to glass such as a building or a vehicle. Since the description of the adhesive layer 30 is as described above, it will be omitted here to avoid overlapping materials. .

Referring to FIG. 6, in the method of manufacturing a thermal barrier film containing a tungsten bronze compound according to another exemplary embodiment of the present invention, the train of the adhesive layer 30 may be used to protect an outer surface of the adhesive layer 30. It characterized in that it further comprises a release paper attaching step (S8) for attaching the release paper 40 to the surface not in contact with the single layer (20).

The release paper attaching step (S8) is a process of attaching the release paper 40 to a surface not in contact with the thermal barrier layer 20 of the adhesive layer 30, by attaching the release paper 40 to the adhesive layer 30 It is possible to protect the outer surface of the). Since the description of the release paper 40 is as described above, it will be omitted here in order to avoid overlapping substrates.

In order to demonstrate the effect of the thermal barrier film containing the tungsten bronze compound according to the present invention, the applicant shows the size of the tungsten bronze compound particles, nuclear accidental crystallinity of the tungsten bronze compound and the best visible light transmittance and infrared ray blocking rate The conditions were revealed through the following test.

(1) Preparation of the Psalms

1) Test Example 1

From a raw material of the tungsten bronze compounds is chloride tungsten, sulfated tungsten, tungsten hydrate, flower alkylation tungsten from was dissolved in 50% by weight chloride tungsten alcohol, chloride, molybdenum in the same transition metal sulfate, molybdenum, molybdenum hydroxide, from the alkylation molybdenum chloride 101.5% by weight of molybdenum was dissolved in alcohol, and 300% by weight of sodium chloride in sodium hydroxide, sodium chloride, sodium sulfate, and sodium nitrate was dissolved in the same alcohol as a positive element, and synthesized by an autoclave apparatus using a microwave heat source. At this time, the microwave capacity is (3kw class laboratory, Korea high frequency applications) and synthesized for 120 ~ 180 seconds with the output 800w, frequency 4GHz. After obtaining the hydrated tungsten bronze compound, it was calcined for about 1 hour at a temperature of 300 ~ 400 for the first calcination. Thereafter, the obtained tungsten bronze compound powder was charged with 180 wt% of hydrazine, which is a liquid reducing agent, for secondary reduction firing, and the temperature was 300 to 400 and the reducing firing time was 1 hour to 2 hours. In order to prepare the powder thus obtained in the form of a dispersion sol, ball milling is performed by adding 0.5 wt% of a dispersant and 80 wt% of an organic solvent to 20 wt% of the reduced calcined powder , and adding 30% of 0.5 mm zirconium beads to the total filling amount. At this time, the dispersion time was carried out for 10 hours, the resulting dispersion sol is 20% by weight of solids. 40 wt% of the dispersion sol was added to 50 wt% of the photopolymer binder, and 10 wt% of MEK was added to the organic solvent to complete the coating sol. The finished coating sol is coated on the PET film as the base layer 10 so that the coating thickness is 3 ~ 4㎛. Forming the adhesive layer 30 to the thickness of 6 ~ 7㎛ on the back surface coated with the thermal barrier layer 20 is laminated with the release paper 40 to complete the final thermal barrier film. Test Example 1 was prepared by cutting the thermal barrier film into a width of 145 mm * length 145 mm.

2) Test Example 2

In Test Example 1, Test Example 2 was prepared under the same conditions as in Test Example 1, except that 300 wt% of cesium chloride was added instead of sodium chloride as a starting material in the tungsten bronze compound powder synthesis process. (In other words, the positive element in the composition of the tungsten bronze compound was replaced with sodium from cesium.)

3) Test Example 3

In Test Example 1, Test Example 3 was prepared under the same conditions as in Test Example 1 except that 101.5% by weight of nickel chloride instead of molybdenum chloride was added as a starting material during the tungsten bronze compound powder synthesis process. (I.e., nickel chloride was added to molybdenum chloride in the transition metal element in the composition of tungsten bronze compound)

4) Test Example 4

In Test Example 1, 101.5% by weight of tungsten chloride, 50% by weight of molybdenum chloride , and 300% by weight of cesium chloride instead of 300 % by weight of sodium tungsten were used as starting materials during the synthesis of tungsten bronze compound powder. Test Example 4 was prepared under the same conditions as in Example 1. (In other words, in the composition of the tungsten bronze compound, the ratio of tungsten chloride and molybdenum chloride in the transition metal element was changed, and the positive element was replaced with sodium from cesium.)

5) Test Example 5

In Test Example 1, Test Example 5 was prepared under the same conditions as in Test Example 1, except that 180 wt% of NaBH ₄ was used instead of hydrazine as the liquid reducing agent in the reducing firing step in the tungsten bronze compound powder synthesis process. (In other words, in the reduction firing step of the tungsten bronze compound, it was replaced with NaBH ₄ from the existing hydrazine.)

6) Test Example 6

In Test Example 1, except that 30 wt% of the reduced fired powder , 0.5 wt% of the dispersant, and 70 wt% of the organic solvent in the process of preparing the tungsten bronze compound dispersion sol were used to make the final dispersion sol solids 30 wt%. Test Example 6 was prepared under the conditions. (That is, to increase the solid content of the tungsten bronze compound dissolving sol from 20% by weight to 30% by weight)

7) Comparative Example 1

In Test Example 1, Comparative Example 1 was prepared under the same conditions as in Test Example 1, except that 151.5% by weight of tungsten chloride was added as a starting material during the synthesis of tungsten bronze compound powder. (In other words, in the composition of the tungsten bronze compound, only tungsten chloride is introduced from the conventional tungsten chloride and molybdenum chloride among the transition metal elements, and unlike the tungsten bronze compound according to the present invention, it has a structure of A _x W ₁ O _y form)

(2) Test 1-Observation of Particle Size

Test purpose: Determination of the particle size of the tungsten bronze compound according to the present invention

-Test condition: The particle observation photograph is a HITACHI (JAPAN) S-2400 scanning electron microscope (SEM) image, taken at 30 0000 times magnification.

-Result Discussion: FIG. 7 is an SEM photograph of the tungsten bronze compound particles synthesized by the polyol synthesis method of Test Example 4, and FIG. 8 is an SEM photograph of the tungsten bronze compound particles synthesized by the polyol synthesis method of Comparative Example 1. As shown in FIG. 7, the particle size of Test Example 4 was 20 to 30 nm, and the particle shape showed a uniform round shape. On the other hand, the SEM image shown in Figure 8 is a particle picture of Comparative Example 1 using only a tungsten single element of the transition metal, the particle size shown in Figure 8 was about 100 ~ 200nm, it could be confirmed that the particle shape is also not constant. . Therefore, it was found that the addition of metal elements other than tungsten had better results in particle size and particle shape.

(3) Test 2-Observation of XRD Crystallinity

-Objective purpose: Confirmation of nuclear accidental crystallinity of tungsten bronze compound according to the present invention

Test conditions: XRD observations were measured using PHILIPS (Netheland), X'Pert-MPD System.

-Result Discussion: FIG. 9 is an XRD graph showing the crystallinity of the tungsten bronze compound synthesized by the polyol synthesis method of Test Example 4. As shown in FIG. 9, Test Example 4 shows hexagonal crystallinity. The XRD values are 2θ27.8 at 2.0.0, 2θ27.23 at 1.0.2, 2θ232 at 1.1.2, and 2θ23.36 at 0.0.2, and other tungsten elements among the transition metal elements of the tungsten bronze compound. It was confirmed that molybdenum was well synthesized with hexagonal crystallinity.

(4) Test 3-Observation of visible light transmittance and infrared ray blocking rate

Test purpose: To compare the visible light transmission and infrared ray blocking properties according to the manufacturing process of tungsten bronze compound, that is, to observe the tungsten

Test conditions: Visible light transmission and infrared blocking observations were measured by setting the baseline in air with a JASCO (JAPAN) 650 UV / VIS spectrometer.

Review of results: The test results are shown in Table 1 below.

division Test Example 1 Test Example 2 Test Example 3 Test Example 4 Test Example 5 Test Example 6 Visible light transmittance% (400-780nm)
65
66
50
78
60
50 Infrared ray blocking rate
(780-2200 nm)
70
73
55
89
60
80

{Visible light transmittance is shown to be 400 ~ 780nm transmittance, infrared blocking rate is shown as 780 ~ 2200 nm transmittance minus 100}

Referring to Table 1, it can be seen that Test Example 2 and Test Example 4 has a good optical characteristics, especially Test Example 4 is the most excellent optical properties. 10 is a UV / VIS transmission graph of the tungsten bronze compound of Test Example 4, wherein the X-axis is a wavelength range, 400-780 nm in the visible light region, which is commonly known, and in the near-infrared region known as the hot ray wavelength. As can be seen in the graph, Test Example 4 has a 550 nm transmittance of 78 to 80%, which is a wavelength of measurement, and a 950 nm transmittance of 10%, which is a representative wavelength of near infrared region. Below, the blocking rate is about 90%, indicating that the optical characteristics are very good. However, the thermal barrier film made of tungsten bronze compound composed of 50% by weight of tungsten chloride, 101.5% by weight of molybdenum chloride, and 300% by weight of sodium chloride as a member of the tungsten bronze compound of Test Example 1 had poor optical properties and had a particle size of 100 nm or more. It was confirmed that the particle shape was also needle-like, Test Example 3 also was not very good optical properties, as the transition metal nickel is added, the crystal defects are not well formed and the electron resonance effect also seems to be inferior. Test Example 5 is a tungsten bronze compound fired at 180% by weight of NaBH4 as a liquid reducing agent, and its reducing property is lower than that of the conventional hydrazine reducing agent. Test Example 6 was prepared with a high concentration dispersing sol, and when added to the same coating sol formulation showed a low visible light transmittance due to the relatively high amount of tungsten bronze compound, while the infrared blocking rate was high.

In the above, the Applicant has described preferred embodiments of the present invention, but these embodiments are merely one embodiment for implementing the technical idea of the present invention, and any modifications or modifications may be made as long as the technical idea of the present invention is implemented. Should be interpreted as being within the scope.

1 is a cross-sectional view of a thermal barrier film containing a tungsten bronze compound according to an embodiment of the present invention

2 is a cross-sectional view of a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention

3 is a cross-sectional view of a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention

Figure 4 is a block diagram of a method for producing a thermal barrier film containing a tungsten bronze compound according to the present invention

5 is a block diagram of a method of manufacturing a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention.

Figure 6 is a block diagram of a method for manufacturing a thermal barrier film containing a tungsten bronze compound according to another embodiment of the present invention

7 is a SEM photograph of the tungsten bronze compound particles of Test Example 4

8 is a SEM photograph of the tungsten bronze compound particles of Comparative Example 1

9 is an XRD graph showing the crystallinity of the tungsten bronze compound of Test Example 4

10 is a UV / VIS transmission graph of the tungsten bronze compound of Test Example 4

* Explanation of the main symbols used in the drawings

10: base layer 20: thermal barrier layer

30: adhesive layer 40: release paper

Claims (19)

delete In the thermal barrier film formed with a thermal barrier layer on one surface of the base layer, The thermal _barrier layer includes a tungsten bronze compound, and the tungsten bronze compound includes A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{( 1-X≥0.67)} ) O ₃ form a _pervoskyite structure, wherein A includes an alkali metal to an alkaline earth metal, and B and B 'include one or more elements or compounds selected from transition metals, The tungsten bronze compound is a thermal barrier film containing a tungsten bronze compound, characterized in that the polyol synthesis method. 3. The thermal barrier film containing a tungsten bronze compound according to claim 2, wherein the polyol synthesis method uses microwaves as a heat source. 4. The thermal barrier film containing a tungsten bronze compound according to claim 3, wherein the polyol synthesis method irradiates the microwave wave in a range of 120 seconds to 180 seconds. The tungsten bronze compound of claim 2, wherein the tungsten bronze compound is subjected to the first calcination in the temperature range of 200 ~ 500 ℃ to remove the hydroxyl group and forming the hexagonal crystallinity of the tungsten bronze compound, film. 6. The thermal barrier film of claim 5, wherein the tungsten bronze compound is subjected to secondary reduction firing by adding a liquid reducing agent to induce crystal defects of the tungsten bronze compound. The thermal barrier film containing a tungsten bronze compound according to claim 6, wherein the secondary reducing firing is fired for 1 to 2 hours at a temperature in the range of 300 to 400 ° C. The method of claim 6, wherein the tungsten bronze compound is formed in the form of a tungsten bronze compound dispersion sol, the tungsten bronze compound dispersion sol is 0.5 to 1% by weight of dispersant, 70 to 80% by weight of organic solvent, tungsten bronze compound powder 20-30 A thermal barrier film containing a tungsten bronze compound, characterized in that it comprises a weight%. 10. The thermal barrier film containing tungsten bronze compound according to claim 8, wherein the tungsten bronze compound is formed in the form of a tungsten bronze compound dispersed sol by a ball mill method using zirconium balls. The method of claim 8, wherein the tungsten bronze compound dissolving sol is formed in the form of a tungsten bronze compound coating sol, the tungsten bronze compound dissolving sol 40 to 50% by weight, 40-50% by weight photopolymer, organic A thermal barrier film containing a tungsten bronze compound, characterized in that 10 to 20% by weight of the solvent. The tungsten bronze compound coating sol is coated on the base layer by any one of a microgravure coating, a knife coating, and a roll-to-roll coating method, and tungsten is characterized in that the thermal barrier layer is formed by UV irradiation. Thermal barrier film containing bronze compound. The thermal barrier film containing a tungsten bronze compound according to claim 2, wherein the thermal barrier layer further includes an adhesive layer on a surface not in contact with the substrate layer, and thus can be adhered to glass such as a building or a vehicle. . 13. The thermal barrier film according to claim 12, wherein the adhesive layer further includes a release paper on a surface not in contact with the thermal barrier layer to protect an external surface. A (B _{(X ≦ 0.67)} , B ′ _{(1-X ≧ 0.33)} ) O ₃ , A (B _{(X ≦ 0.33)} , B ′ _{(1-X ≧ 0.67)} ) O ₃ form using polyol synthesis method A tungsten bronze compound manufacturing step of preparing a tungsten bronze compound having a perboskate structure, and calcining the tungsten bronze compound in a temperature range of 200 ~ 500 ℃ 1 to remove the hydroxyl group and to form the hexagonal crystallinity of the tungsten bronze compound 1 The secondary calcination step, a secondary reducing firing step of inducing a crystal defect of the tungsten bronze compound by injecting a liquid reducing agent into the tungsten bronze compound from which the hydroxyl group is removed, and the tungsten bronze compound powder subjected to the secondary reducing firing step are dispersed sol Tungsten bronze compound dissolving sol manufacturing step of preparing in the form, tungsten bronze compound dissolving sol manufacturing step of preparing the tungsten bronze compound dissolving sol in the form, and the tungsten bronze compound coating sol Method of manufacturing a thermal barrier film containing a tungsten bronze compound comprising a thermal barrier coating step of forming a thermal barrier layer by coating the surface of the base layer. 15. The method of claim 14, wherein the polyol synthesis method used in the tungsten bronze compound manufacturing step is prepared using a microwave wave as a heat source in the range of 120 seconds to 180 seconds to produce a thermal barrier film containing a tungsten bronze compound Way. 15. The method of claim 14, wherein the tungsten bronze compound dispersion sol in the manufacturing step of the tungsten bronze compound dispersion sol is characterized in that it comprises 0.5 to 1% by weight of dispersant, 70 to 80% by weight of organic solvent, 20 to 30% by weight of tungsten bronze compound powder A method for producing a thermal barrier film containing a tungsten bronze compound. 15. The method according to claim 14, wherein the tungsten bronze compound coating sol in the tungsten bronze compound coating sol manufacturing step comprises 40 to 50% by weight tungsten bronze compound dispersion sol, 40 to 50% by weight photopolymer, 10 to 20% by weight organic solvent Method for producing a thermal barrier film containing a tungsten bronze compound, characterized in that. 15. The tungsten bronze according to claim 14, further comprising an adhesive layer coating step of forming an adhesive layer on a surface of the thermal barrier layer that is not in contact with the base layer so as to adhere to glass such as a building or a vehicle. Method for producing a thermal barrier film containing a compound. 19. The method according to claim 18, further comprising a release paper attaching step of attaching a release paper to a surface which is not in contact with the thermal barrier layer of the adhesive layer to protect the outer surface of the adhesive layer. Method of manufacturing a thermal barrier film.

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