KR101145276B1 - Dyeing coating type rays of the sun reflection film using sublimate disperse dyes and matal chelate compound and method for manufacture thereof - Google Patents

Abstract

The present invention is a sublimable disperse dye-metal, characterized in that a coating sol of a sublimable disperse dye-metal chelate compound having a dyeing property capable of reflecting the infrared region distributed in sunlight is coated on one surface of the base layer of the synthetic resin film The present invention relates to a dye-coated type solar reflective film using a chelating compound and a method of manufacturing the same, wherein a wet coating forms a reflective thin film that exhibits solar reflective properties at the same time as the dye is deposited on a substrate, and the visible light region occupies 95% of the solar energy distribution. By effectively blocking the 780nm ~ 1700nm area that reflects from the near-infrared to the near-infrared, it is a reflective film, not a heat-absorbing film of the conventional solar absorption type, that the heat rays are transferred to the inside of the building during the day when the sun is strong Type solar thermal barrier film can be provided.
In addition, the carrier compound contained in the sublimable disperse dye-metal chelate compound serves to completely dissolve the sublimable disperse dye at a high concentration, and also relaxes the molecular arrangement of the surface of the synthetic resin film base layer to increase the dyeing speed. In addition to the addition of leveling agents and organic solvents to the sublimable disperse dye-metal chelate compounds, they exhibit excellent optical properties, as well as cracks or spots caused by high surface tension differences from the substrate surface. It is possible to alleviate or eliminate the occurrence of light and the like to provide a good dyeing effect without color difference variation, and the sublimable disperse dye-metal chelate compound according to the present invention is prepared by the Reflux synthesis method, so as a conventional simple equipment It is possible to synthesize and lower the manufacturing cost and chelate compounds with high solubility It is an advantage of being able to.

Description

Dyeing COATING TYPE RAYS OF THE SUN REFLECTION FILM USING SUBLIMATE DISPERSE DYES AND MATAL CHELATE COMPOUND AND METHOD FOR MANUFACTURE THEREOF}

The present invention is coated with a coating sol of a sublimable disperse dye-metal chelate compound having a dyeing property capable of reflecting the infrared region distributed in sunlight to one side of the base layer of the synthetic resin film to form a dye-coated solar reflective layer, Using a sublimable disperse dye-metal chelate compound, a wet coating is formed on the substrate to form a reflective thin film that exhibits solar reflection characteristics and blocks the visible light from the near infrared far infrared to have a high thermal barrier effect. It relates to a dye-coated solar light reflecting film and a method of manufacturing the same.

In today's world, various projects have been established to establish policy measures to simultaneously solve two opposing purposes: environmental pollution prevention measures due to the use of fossil fuels and energy saving measures due to the finite nature of fossil fuels. The heat shield film, which is a functional film, has been used as a means of controlling heat energy in buildings and vehicles that provide a comfortable and comfortable environment by reducing living energy by proper control of the energy.

On the other hand, sunlight, which is an unlimited supply of heat energy from nature, is composed of visible light, ultraviolet light, and infrared light, and double visible light is a wavelength related to human vision, and ultraviolet light is also called actinic light and is a wavelength acting on a chemical reaction. have. In addition, infrared rays are called heat rays because most of the radiant heat emitted by the sun or objects consists of infrared rays. The energy distribution values for the full wavelength of sunlight are in the range of 380 nm to 780 nm visible light and 780 nm in the range of wavelengths due to thermal energy in the solar field as mentioned in KS L 2016 (film for window glass). The infrared region of ~ 2200nm occupies more than 95%, and the wavelength of the solar region is blocked by using a thermal barrier film, but due to the inability to control visible light, which is the limit of the conventional transparent thermal barrier material, It shows a limit. In other words, all of the thermal barrier materials used in the conventional transparent thermal barrier film are absorbing materials, so it is difficult to obtain a high thermal barrier effect because it actually absorbs heat energy incident from the outside and radiates back to the interior after a certain time. Therefore, there is an urgent need for the development of a film that completely reflects thermal energy or light energy in order to achieve a complete thermal barrier effect indoors and outdoors.

Therefore, when looking at the patents for the thermal barrier film developed to control the solar energy as described above, one of the polyurethane-based, epoxy-based or modified acrylic-based paints on the PET film in Korea Patent Publication No. 10-0861146 The silver reflecting film and the method for manufacturing the silver reflecting film are formed by applying and forming a pretreatment film and forming a silver film on the top thereof. However, when preparing the silver reflecting film, a pretreatment coating layer is first formed on the substrate, and a silver film is formed thereon. As a method of forming, it is not a film that adds color tone by simple silver film formation, and it is not a film showing a certain visible transmittance like a film used in construction and vehicles because it is a mirror-like shape with a complete view shielding. There was a problem in that the manufacturing cost and productivity drop due to the complex manufacturing process to be formed.

In addition, using a laminating method in Korean Laid-Open Patent Publication No. 1997-0025942, the dye-coated film coated on the base of the metal-bonded base film is laminated and pressed, and then adhered with an adhesive to decolorize the dye or desorb the metal. Although a reflective solar control film is known to have excellent adhesion and preventive properties, the above patents require an expensive facility for depositing metal on a substrate, have a low production speed, and have a high defect rate. In addition, the manufacturing process is complex, and the overall thickness of the final film is high, so when the user is installed in the window, such as air bubbles, foreign matter, layer separation, the edge (edge) curl phenomenon was quite difficult problem.

In addition, as a composition for coating a conventional reflective film as described above, a wear-resistant coating composition having excellent dyeing properties containing an aluminum chelate compound is known from Korean Patent Publication No. 10-0442107, but dyeing on a synthetic resin substrate is a conventional technique. In general, a coating layer that can be formed is first formed and then put into a bath containing a disperse dye to obtain a tinted film or fiber. Such a method is used to remove decomposed products and by-products of disperse dyes that are not completely dyed. In many cases it involves a washing process, it is almost impossible to dye the large-area film. In addition, there is a problem in that the basic performance of the dyeing is deteriorated since the dyeing property is reduced when the adhesion, solvent resistance, and durability of the coating layer are deteriorated because the dyeing, not the dyeing on the substrate, that is, the dyeing on the coating layer.

Also, in Korea Patent Publication No. 10-0025964, using a bubble dyed with a disperse dye, a vapor-permeable, waterproof polyurethane coating process is known to prevent dispersing of the disperse dye by first coating a metal oxide or fluoride during polyurethane coating. This is not a complete dyeing coating on the substrate because it is dyeing for the first-coated metal oxide or fluorine compound, and it does not dye properly because it is contrary to the principle of the most basic sublimation dyeing mechanism in the structure of disperse dyes when dyeing the metal oxide or fluorine layer. There is a problem.

On the other hand, representative examples of conventional disperse dyes, dia- or phthalimide-based commercially available CA-Red, CA-Black, Kayaset Yellow TDN, Dianix Yellow F3G-E, Kayaset Red 130, Oil Red DK-99 , Kayaset Blue 136, RTB31, CIDispersion Red 7 (Constitution No. 11150), CIDispersion Red 13 (Constitution No. 11115), Kayaset Black AN, Kayaset Black AH, etc. Diazo-based compounds having sublimation fastness and light fastness are most frequently used. Since general dispersion dyes as listed above are used as a solution in a dispersed state using a dispersant and a surfactant in a polar solvent such as water, it is not suitable to coat the substrate of the film layer, the residual dispersant after sublimation dyeing In order to remove by-products such as surfactants and the like, cleaning and reducing washing are most often required. Also, when a metal layer is simply added to the dispersion system to form a reflective layer, the metal particle thin film on the surface during washing and reducing washing is formed. There were problems with a high probability of extinction.

In general, when the metal component forms a thin film layer in a dispersed state such as nanoparticles and mixed with a polymer binder, it is more conventional to show light energy absorption characteristics than reflection characteristics. If the metal particles are not densely formed even when light is reflected from the metal particle interface, the polymer particles are absorbed again by the polymer around the metal particles, and finally the layer is changed into a total absorbing layer even though the metal particles are distributed.

Therefore, depending on how the metal salt or the metal particles are formed into a thin film, that is, how the metal particles are formed in a continuous layer with density, the surface characteristics show a considerable difference. For example, the characteristics of the surface deposited by vacuum deposition or sputtering using two materials, such as when the same infrared ray blocking material is mixed with a polymer and wet-coated a nano-dispersed solution of representative ITO or ATO together with a polymer It is common to appear completely wrong in light reflection properties. That is, there are many differences in the light reflection characteristics depending on how many free electrons are present in the continuous surface layer of the metal material, which is also closely related to the surface conductivity and the thermal conductivity. For this reason, the present invention was able to complete the present invention due to the efforts of the present inventors to solve the problem of continuously manifesting the metal particles by the wet coating on the surface of the PET layer.

Accordingly, the present invention has been made to solve the above problems, the synthetic resin such as polyester coating sublimation dispersible dye-metal chelate compound having a dyeing property that can reflect the infrared region distributed in sunlight By dye-coating on one side of the base layer of the film to form a solar reflective layer, a metal reflective thin film is formed on one side of the base layer and simultaneously exhibits solar reflection characteristics, thereby blocking the visible light region from the sunlight to the near-infrared region. It is an object of the present invention to provide a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound having a short effect, and a method of manufacturing the same.

In addition, the present invention dissolves a sublimable disperse dye and a metal salt in a carrier compound to synthesize a sublimable disperse dye-metal chelate compound by Reflux synthesis, thereby facilitating the synthesis process, and can be synthesized as a simple facility. Another object is to provide a dye-coated solar reflective film using a sublimable disperse dye-metal chelate compound and a method for producing the same, wherein the metal-free chelate compound without particles can be obtained.

In another aspect, the present invention by coating the coating sol on one surface of the synthetic resin substrate layer by any one of the microgravure coating, knife coating or roll-to-roll coating method, by forming a dye-coated solar reflective layer by hot air and IR drying method The present invention provides a dyeing coating type solar reflective film using a sublimable disperse dye-metal chelate compound and a method of manufacturing the same, which are characterized by obtaining a precise coating dyeing surface and realizing a low manufacturing cost by using an existing coating equipment. Let's do another task.

In addition, the conventional dyeing method requires a cleaning process, but the present invention can be produced by a simple wet coating without the need for the cleaning process, characterized in that the production cost and high productivity than the reflective film produced by the conventional vacuum sputter method Another object of the present invention is to provide a dye-coated solar reflective film using a sublimable disperse dye-metal chelate compound and a method of manufacturing the same.

In addition, the present invention is a leveling agent and organic to the sublimable disperse dye-metal chelate compound sol is composed of a sublimable disperse dye-metal chelate compound and a carrier compound in order to have a uniform dye-coating property Sublimation dispersion characterized by having a good dyeing effect without any color difference by reducing or eliminating the occurrence of craters or spots caused by high surface tension difference from the substrate surface by mixing the solvent. Another object of the present invention is to provide a dye-coated solar reflective film using a dye-metal chelate compound and a method of manufacturing the same.

In addition, the present invention by forming a solar reflective layer by the wet coating, unlike the conventional method, it is excellent in the solvent resistance of the coating layer by dyeing the film base layer without the need for a polymer binder (mainly used for forming a coating layer) It provides a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound and a method for producing the same, characterized in that it can form another coating layer, such as a pressure-sensitive adhesive layer on one surface of the solar reflective layer that is a dye coating layer Let's do another task.

Accordingly, the present invention provides a solar reflective layer using a sublimable disperse dye-metal chelate compound on one side of the adhesive layer and an adhesive layer to be able to adhere to glass such as a building or a vehicle on a surface not in contact with the base layer. A release paper may be further included to protect the outer surface of the adhesive layer.

The present invention for achieving the above object in the solar reflective film formed with a solar reflective layer on one surface of the synthetic resin film base layer,

The solar reflecting layer is formed by a coating sol containing a sublimable disperse dye-metal chelate compound.

And the present invention is a method of manufacturing a solar reflective film,

Step of preparing a sublimable disperse dye-metal chelate compound synthesized by Reflux synthesis (S1),

The coating sol manufacturing step (S2) by mixing a leveling agent and an organic solvent in the prepared sublimable dispersion dye-metal chelate compound,

Coating to form a dye-coated solar reflective layer 20 using a sublimable disperse dye-metal chelate compound on one surface of the synthetic resin film base layer 10 (S3),

Coating a pressure-sensitive adhesive layer 30 that can be adhered to the windows of the building and the vehicle (S4),

Method for producing a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound, characterized in that the step of attaching a release paper 40 that can be separated when the protective layer surface and the coating on the glass (S5) As another means for solving the problem.

In the present invention, it is preferable that the coating sol is mixed with 0.01 to 0.5 parts by weight of a leveling agent and 5 to 10 parts by weight of an organic solvent based on 100 parts by weight of the sublimable disperse dye-metal chelate compound.

In addition, the sublimable disperse dye-metal chelate compound is synthesized by Reflux synthesis by dissolving 1 to 3% by weight of the sublimable disperse dye and 7 to 10% by weight of the metal salt solution in 87 to 92% by weight of the carrier compound. ,

The sublimable disperse dye-metal chelate compound has the structure of Formula R ₁ -MR ₂ ,

R1 and R2 are diazo-based sublimable disperse dyes or phthalimide-based sublimable disperse dyes, respectively, which are sublimable disperse dyes, and R1 and R2 may be the same as or different from each other.

The M is characterized in that one selected from the transition metals Cu, Ag, Au, Zn, Ni or Co,

The carrier compound is diphenylphenol (di-phenylphenol), o-phenylphenol (o-phenylphenol), p-phenylphenol (p-phenylphenol), salicylic acid (salicylic acid), cresol (cresol), benzoic acid, methyl salicylic acid (methylsalicylic acid), monochlorobenzene (mono-chlorobenzene), o-dichlorobenzene (o-di-chlorobenzene) is characterized by forming a coating sol using at least one compound.

In addition, the solar reflective layer further comprises an adhesive layer on the surface not in contact with the base layer to be able to adhere to the glass, such as buildings or vehicles,

The adhesive layer may further include a release paper on a surface not in contact with the solar reflective layer to protect an external surface.

The present invention by the above-mentioned solution to the problem is coated with a coating sol of a sublimable disperse dye-metal chelate compound on one side of the base material layer of the synthetic resin film to form a dye-coated type solar reflective layer, by the wet coating at the same time the sun Reflective thin film is formed to reflect light reflecting characteristics, reflecting 95% in the solar energy distribution to the near-infrared far-infrared region, that is, effectively blocking the 780nm ~ 1700nm region, so that the heat rays in the building during the day It is possible to provide a high-efficiency, energy-saving solar reflective film because it is a reflective film rather than a thermal barrier film of the conventional solar absorption type.

In addition, the carrier compound contained in the sublimable disperse dye-metal chelate compound serves to completely dissolve the sublimable disperse dye at a high concentration, and also relaxes the molecular arrangement of the surface of the synthetic resin film base layer to increase the dyeing speed. In addition to the addition of leveling agents and organic solvents to the sublimable disperse dye-metal chelate compounds, they exhibit excellent optical properties, as well as cracks or spots caused by high surface tension differences from the substrate surface. Alleviates or eliminates the occurrence of light and the like to provide a good dyeing effect without color difference variation.

In addition, the sublimable disperse dye-metal chelate compound according to the present invention may be prepared by a Reflux synthesis method, and thus, the synthesis may be performed even as a conventional simple equipment, thereby obtaining a high solubility chelate compound and a low solubility. The surface of the metal thin film formed by the metal chelate complex salt having solar reflection and electric conductive properties can be applied to the electromagnetic wave shielding film or the touch panel by patterning as described above due to its high conductivity. It is an advantage that can be applied to.

1 is a cross-sectional view of a dye-coated solar reflective film using a sublimable disperse dye-metal chelate compound according to an embodiment of the present invention,
Figure 2 is a block diagram of a method of manufacturing a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound according to another embodiment of the present invention,
Figure 3 is a UV / VIS spectrometer reflection graph of the dye-coated solar reflective film using a sublimable disperse dye-metal chelate compound according to Examples 2 and 3 of the present invention,
Figure 4 is the result of the elemental analysis of the sublimable dispersed dye-metal chelate compound synthesized by the Reflux synthesis method of Example 2.

According to a feature of the present invention for achieving the above effect, the present invention relates to a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound and a manufacturing method thereof, the infrared region distributed in sunlight DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of a solar reflective film and a method of manufacturing the same is described in detail with reference to the accompanying drawings so that a light reflection characteristic of a substantially infrared region can be obtained using a metal salt which is a material capable of reflecting.

First, the technical idea according to the present invention, the present invention is a way to form a continuous thin film of metal particles on the surface of the synthetic resin film base layer, the thin film by dyeing the metal particles to the synthetic resin film base layer through a dyeing technique As a technology of forming in a form, it is possible to apply the existing coating equipment as it is, while having a vacuum deposition or sputtering effect, it is possible to obtain a film that is colored and reflective properties due to one dye coating.

Also characteristic of the present invention, there are a number of methods for the fiber dyeing method, and among them, a dyeing technique based on a synthetic resin film using a sublimable disperse dye, a conventional method is to disperse the disperse dye solute in a polar solvent such as water It is common to obtain dyes by adding zirconia beads to a dispersing equipment such as a ball mill and dispersing them to submicron units using a dispersant, a dispersing aid or a surfactant. In the ink market, the solution thus prepared is mainly referred to as a sublimable ink. The dispersion dye concentration of the sublimable ink is usually not more than 1.5%, while the inventors of the present invention find that the disperse dye is dissolved at a high concentration of 2% or more in a solvent such as m-cresol, which is a kind of carrier in the carrier salt method, There is no need for a conventional dispersant or surfactant, and a dyeing solution along with a sublimable dyeing mechanism is obtained, which is finally coated on a resin film to confirm that the surface of the resin is dyed after thermal drying. A thin coating of a coating sol mixed with a material such as silver salt, which shows well, was applied to a synthetic resin film having a large area to prepare a dye-coated solar reflective film.

1 is a cross-sectional view of a dye-coated solar reflective film using a sublimable disperse dye-metal chelate compound according to an embodiment of the present invention.

Referring to Figure 1, the solar reflective film according to an embodiment of the present invention, in the solar reflective film in which the solar reflective layer 20 is formed on one surface of the synthetic resin film base layer 10,

The solar reflective layer 20 is a dye-coated solar reflective film using a sublimable disperse dye-metal chelate compound, characterized in that formed by a coating sol containing a sublimable disperse dye-metal chelate compound.

The synthetic resin film base layer 10 is a structure that serves to support and protect the solar reflective layer 20 is coated with a solar reflective layer 20 on one surface, PET as the synthetic resin film base layer 10 , Polycarbonate, nylon, PP and the like are preferred, but since heat is applied to form the solar reflective layer 20, it is more preferable to use PET, which is the plastic substrate having the highest heat distortion temperature.

For reference, the thickness of the synthetic resin film base layer 20 is preferably 25 to 100 μm, and the thickness of the synthetic resin film base layer 20 is not necessarily limited to the above-mentioned range, and is required by the consumer or the manufacturer. If necessary, it can be adjusted to suit the design conditions.

In addition, the solar reflective layer 20 may be formed on one surface of the synthetic resin film base layer 10 as a heat shield layer, and may be formed of a synthetic resin film base layer 10 by a sublimable dispersion dye in a sublimable disperse dye-metal chelate compound. Is dyed on one side of the block the visible light region of the solar energy distribution. In addition, due to the light reflection characteristic of the metal thin film contained in the metal chelate compound, it has the effect of simultaneously blocking the near infrared region in the range of 780nm to 1700nm.

In the present invention, the thickness of the solar reflective layer 20 is preferably 0.1 to 0.5 μm, and when the thickness of the solar reflective layer 20 is less than 0.1 μm, there is a fear that the solar light reflecting effect may be lowered. When the thickness of the reflective layer 20 exceeds 0.5 μm, the visible light transmittance may decrease as the metal thin film becomes thicker.

The coating sol for forming the dye-coated solar reflective layer 20 is a mixture of 0.01 to 0.5 parts by weight of a leveling agent and 5 to 10 parts by weight of an organic solvent based on 100 parts by weight of a sublimable disperse dye-metal chelate compound. desirable.

When the mixing amount of the leveling agent and the organic solvent in the coating sol is less than the range defined above, the viscosity of the coating sol is high, there is a fear that the thin film on the surface of the substrate layer is uneven due to the deterioration of workability, the leveling agent and the organic solvent When the amount of the mixture exceeds the range defined above, the sublimable disperse dye-metal chelate compound may be precipitated.

The leveling agent used in the present invention is a conventional leveling agent, such as silicone diacrylate, silicone polyacrylate compound, and the like, NMP, DMF, MIBK, EC, IPA and the like can be used.

The sublimable disperse dye-metal chelate compound is a compound synthesized by Reflux synthesis by dissolving 1-3 wt% of the sublimable disperse dye and 7-10 wt% of the metal salt solution in 87-92 wt% of the carrier compound. In addition, the sublimable disperse dye-metal chelate compound is characterized in that the particle size of the sublimable disperse dye is bonded as a metal salt and a ligand in a completely dissolved state.

When the amount of the sublimable dispersed dye and the metal salt solution in the sublimable dispersed dye-metal chelate compound is less than the range defined above, the solar reflective layer 20 formed on one surface of the base layer 10 may not be properly colored. Or the metal thin film may not be formed properly, and when the dissolution of the sublimable disperse dye and the metal salt solution exceeds the above-defined range, the solar reflectance is improved due to the strong coloring and the thickness of the metal thin film. There exists a possibility that a transmittance | permeability may fall.

In addition, the metal salt solution is preferably dissolved 2 to 3 parts by weight of the metal salt in 100 parts by weight of ethanol. If the dissolved amount of the metal salt is less than 2 parts by weight, the metal coating film may not be properly formed in the coating film of the solar reflective layer 20. If the dissolved amount of the metal salt exceeds 3 parts by weight, Although light reflectance improves, there exists a possibility that the transmittance | permeability of visible light may fall.

And in the present invention, the sublimable disperse dye-metal chelate compound is a general formula

Is a structure of R ₁ -MR ₂ ,

In addition, R1 and R2 are diazo-based sublimable disperse dyes or phthalimide-based sublimable disperse dyes, respectively, which are sublimable disperse dyes, and R1 and R2 may be the same or different from each other.

The M is characterized in that one selected from the transition metals Cu, Ag, Au, Zn, Ni or Co.

R1 and R2 are diazo-based disperse dyes or phthalimide-based disperse dyes, respectively, which are sublimable disperse dyes. Specifically, sublimable disperse dyes usable in the present invention may be commercially distributed CA-Red (HANGZHOU SUNSHINE). CHEMICAL, CA-Black (HANGZHOU SUNSHINE CHEMICAL), Kayaset Yellow TDN (Nippon kayaku), Dianix Yellow F3G-E (MITSUBISHI CHEMICAL), Kayaset Red 130 (Nippon kayaku), Oil Red DK-99 (Arimoto chemical), Kayaset Blue 136 (Nippon kayaku), RTB31 (MITSUBISHI CHEMICAL), CI Dispersion Red 7 (Constitution No, 11150. Ningbo Huajie Chemical), CI Dispersion Red 13 (Constitution No. 11115, Ningbo Huajie Chemical), Kayaset Black AN (Nippon kayaku), Kayaset Black Nippon kayaku (AH) and the like.

In the present invention, it is more preferable to use Kayaset Yellow TDN, Kayaset Red 130, Kayaset Blue 136 among the above-mentioned sublimable dispersion dyes.

In general, the conventional disperse dyes, such as diazo or phthalimide, are commonly used as the dyes listed above. Among them, diazo-based compounds are most frequently used, and color tone is excellent. Although it has excellent sublimation fastness and light fastness, such conventional disperse dyes are not suitable as coatings because they are used as a solution dispersed in a polar solvent such as water using a dispersing agent and a surfactant, and after the sublimation dyeing, In most cases, washing and reducing washing are necessary to remove by-products such as surfactants. Also, if a reflective layer is added to the dispersion system by simply adding a metal salt, the thin metal particle film on the surface disappears and is damaged during the washing and reducing washing process. Problems arise.

Accordingly, the present invention uses a sublimable disperse dye-metal chelate compound in which a diazo- or phthalimide-based sublimable disperse dye has a ligand bond by chelation reaction with a metal salt. It is a coating sol that does not use an active agent.

The carrier compound, which is a dyeing aid, serves to improve dissolution of the disperse dye and relaxation and dyeing speed of the substrate, and does not form a dispersed particle size as in the conventional disperse dye, but is in the form of a coating sol dissolved in a solvent such as a carrier compound. Therefore, a wet coating forms a thin film on the substrate at the same time as it dyes and reflects the sun's reflection properties, reflecting 95% of the solar energy distribution from near-infrared to near-infrared, that is, effectively blocking the 780nm ~ 1700nm range. It is possible to provide a solar reflective film having a short effect.

Carrier compounds usable in the present invention are diphenylphenol (di-phenylphenol), o-phenylphenol (o-phenylphenol), p-phenylphenol (p-phenylphenol), salicylic acid (salicylic acid), cresol (cresol), benzoic acid, It is preferable to form a coating sol using at least one compound among methylsalicylic acid, mono-chlorobenzene and o-di-chlorobenzene.

In addition to the carrier compounds defined above, the structure of the compound is not known and commercially distributed Latyil carrier (Dupon), Levagal PT (FBy), Palatint M (BASF), Tumescal D, PH (ICI), Velanol TS ( S) can also be used.

That is, m-cresol of the carrier compound used in the present invention has the property of dissolving a sublimable disperse dye, so that the color development is more pronounced than the conventional sublimable ink, dyeing speed and salt The yield is excellent. Due to these characteristics, the molecular structure of m-cresol is particularly similar to that of sublimable disperse dyes among various kinds of carrier compounds, so that the solubility is high. This solubility has a great effect on the reactivity in the molecular structure, and it is easy to form ligands with other metals. Therefore, among the metal salts, silver salts easily show the binding property to the amine group. To form a compound.

As described above, the coating sol according to the present invention is capable of dyeing the surface of the PET film by heat drying after a simple wet coating, without the need for a cleaning process after dyeing the PET film, which is a base film, unlike the conventional dyeing method. On the surface, a metal thin film is formed, and the film which shows colored reflected light can be manufactured. The dye-coated solar reflective film manufactured as described above can be used as a more energy-saving film than the thermal barrier film using a conventional infrared absorber because it can completely reflect infrared rays in the sunlight due to the surface reflection property to block heat energy flowing into the room. Can be.

In general, when manufacturing a colored film, in order to show coloration, the process is performed by dissolving a general dye in a solvent in a dot or adhesive layer, followed by a dot and adhesive coating, while the present invention shows coloration with a single coating and a deposition film. The same effect can be obtained to simplify the manufacturing process to increase the productivity, manufacturing cost can also be a breakthrough manufacturing method. In addition, the surface on which the metal thin film is formed is a high functional film that can be applied to the electronic component or the electronic material industry by being applied to the touch panel by patterning the electromagnetic wave shielding film or the above method due to high conductivity.

1, the dye-coated solar reflective layer 20 using the sublimable disperse dye-metal chelate compound according to another embodiment of the present invention adheres to a surface not in contact with the synthetic resin film base layer 10. In addition, the layer 30 may be further bonded to glass such as a building or a vehicle.

The adhesive layer 30 is formed on one surface of the solar reflective layer 20 to form a thermal barrier film formed with a dye-coated solar reflective layer using a sublimable disperse dye-metal chelate compound according to the present invention. The adhesive layer 30 may be adhered to the glass, and the adhesiveness of the adhesive layer 30 mainly depends on the molecular weight of the polymer chain, the molecular weight distribution, or the amount of molecular structure present, and in particular, the acrylic copolymer is determined by the molecular weight. The weight average molecular weight is preferably 200,000 to 800,000. On the other hand, it is preferable that the methacrylate monomer which has a C1-C12 alkyl group is contained by 80 to 90 weight% in an acryl-type copolymer. This is because when the methacrylate monomer is less than 80% by weight of the acrylic copolymer, there is a problem that the initial adhesive strength is lowered, and when the methacrylate monomer is more than 90% by weight, problems in durability may occur due to the decrease in cohesion.

In addition, referring to Figure 1, according to another embodiment of the present invention, the heat-transfer film formed with a dye-coating type solar reflective layer using a sublimable disperse dye-metal chelate compound is the adhesive layer 30 is the solar reflective layer ( 20) it characterized in that it can further protect the adhesive surface by including a release paper 40 on the surface not in contact with.

The release paper 40 is formed on one surface of the adhesive layer 30 and serves to protect the adhesive 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. To use a silicone coated film on the PET substrate. If the silicon coating is not applied, the release paper 40 is separated when the final manufactured solar reflective film is applied to glass, because the adhesive layer 30 and the release paper 40 are not separated.

Hereinafter, a method of manufacturing a dye-coated type solar reflective film using a sublimable disperse dye-metal chelate compound according to the present invention will be described in detail with reference to FIG. 2.

Figure 2 is a block diagram of a method for producing a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound according to the present invention.

Referring to FIG. 2, the present invention provides a leveling agent and an organic solvent to a sublimable disperse dye-metal chelate compound prepared by Reflux synthesis (S1), and the prepared sublimable disperse dye-metal chelate compound. Mixing coating sol manufacturing step (S2), the coating step for forming a dye-coated type solar reflective layer 20 using a sublimable disperse dye-metal chelate compound on one surface of the synthetic resin film base layer 10 (S3), Coating step (S4) of the adhesive layer 30 that can be adhered to the glass window of the building and vehicle and the step of attaching the release paper 40 (S5) that can be separated when the protective layer and the construction on the glass.

In general, when the solar reflective layer 20 is coated on the synthetic resin film base layer 10 and subjected to hot air drying and IR irradiation, when exposed to a temperature of 130 ° C. or higher, the general synthetic resin film base material has a thermal deformation temperature and is thermally deformed. When the temperature is higher than the above, there is a problem that the substrate itself is deformed. Therefore, PET is most preferred as the synthetic resin substrate having the highest heat distortion temperature.

In addition, the sublimable disperse dye-metal chelate compound used in the present invention is a liquid phase, and the sublimable disperse dye and the metal salt are dissolved in a carrier compound to proceed in a reaction temperature range of 0 to 45 ° C. by Reflex synthesis. The sublimable disperse dye is dissolved in the carrier compound, the metal salt is dissolved in alcohol, added thereto, the reaction proceeds for about 5 hours, and then the final sublimable disperse dye-metal chelate compound is synthesized. The synthesis method according to the present invention is to provide a solar reflecting film, characterized in that the synthesis process is easy, and even a conventional simple facility can obtain a uniform metal salt chelate free of advantages and particles.

In this case, 0.01 to 0.5 parts by weight of the leveling agent and 5 to 10 parts by weight of the organic solvent are included with respect to 100 parts by weight of the sublimable disperse dye-metal chelate compound. Existing dyeings show limitations in large area coating methods such as PET films, including post-dyeing washing. Therefore, in the present invention, it is possible to dye by a wet coating method and to supplement the disadvantages in the surface coating by adding a leveling agent and an organic solvent in order to give more precise coating properties.

Since the structural formula of the sublimable disperse dye-metal chelate compound and the components of the coating sol have already been described in detail, the description thereof will be omitted.

The solar reflective coating sol using a sublimable disperse dye-metal chelate 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 hot air drying and IR. By forming the dye-coated solar reflection layer by irradiation, it is possible to obtain a precise coating dyeing surface, and to realize a low manufacturing cost by using a conventional coating equipment, especially when the coating through a microgravure coating equipment Gravure coating equipment has the advantage that it shows the flatst coating surface in the large area coating and productivity is higher than other equipment. In the microgravure coating, the coating sol injected from the coating part has different types of micro cylinders with different volume ratios, and the thread-shaped cells formed on the surface of the cylinders are like fine grooves for collecting the coating liquid and are coated according to the volume ratio of the cells. The amount by which the sol can be coated on the base film is determined. At this time, the volume ratio is determined by the size of the cell groove, so it is most preferable when it is 20.5 ~ 32.2 cm ³ / m ³ .

The dye-coated solar reflecting film according to the present invention prepared by the above method can synthesize the sublimable disperse dye-metal chelate compound by the Reflux method using an existing simple equipment to lower the manufacturing cost It is a highly efficient energy-saving solar reflecting film that can not only obtain a chelate compound with high solubility and solubility, but also effectively block from visible light to near-infrared.

Hereinafter, the dye-coated solar reflective film using the sublimable disperse dye-metal chelate compound according to the present invention will be described in more detail with reference to the following examples, but the scope of the present invention is not limited to the examples.

1. Preparation of Test Piece

(Example 1)

Using a sublimable disperse dye-metal chelate compound coating sol, a solar reflective layer having a thickness of 0.3 μm (dry basis) was formed on one surface of a PET film substrate layer having a thickness of 25 μm, and through hot air and IR irradiation at a temperature of 130 ° C. The coating film was dried and dried to form a blue reflective film. Example 1 was prepared by forming a pressure-sensitive adhesive layer having a coating film thickness of 8 to 10 μm on the rear surface of the solar reflective layer, and then cutting a film having a dye-coated solar reflective layer prepared by laminating release paper to 145 mm by 145 mm in length. .

The coating sol coated on the substrate layer is prepared by first dissolving 2 g of Kayaset Blue 136, which is a sublimable dye, as a starting material of a sublimable disperse dye-metal chelate compound in 90 g of a carrier m-cresol. 0.2 g of the metal compound AgCH ₃ COO in the metal salt was dissolved in 7.8 g of ethanol in another beaker to prepare a solution B, and the solution B was slowly added to the solution B to react with Reflux. At this time, the temperature range was carried out at 0 ~ 45 ℃. During 5 hours of reaction time, the reactants initially appear dark blue to dark brown. After completion of the reaction, 0.01 parts by weight of silicone diacrylate as a leveling agent and 5 parts by weight of MIBK as an organic solvent were added to 100 parts by weight of the resulting solution, followed by stirring to prepare a coating sol.

(Example 2)

In Example 1, Example 2 was prepared under the same conditions as in Example 1, except that Kayaset Red 130 was added instead of the starting material Kayaset Blue 136 in the synthetic manufacturing process of the sublimable disperse dye-metal chelate compound. In other words, the starting material was changed from Kayaset Blue 136 to Kayaset Red 130 in the composition of the sublimable disperse dye-metal chelate compound.

(Example 3)

In Example 1, Example 3 was prepared under the same conditions as in Example 1 except that CuCH ₃ (COO) _{2 was} added instead of AgCH ₃ COO in the metal salt material input process. That is, AgCH ₃ COO was replaced with CuCH ₃ (COO) ₂ instead.

(Example 4)

For Example 1, the sublimable disperse dye - Kayaset Blue 136, instead of the starting material in the synthesis the manufacture of a metal chelate compound added to Kayaset Red 130, and to a metal material In the AgCH ₃ COO instead CuCH ₃ (COO) ₂ Other than Example 4 was prepared under the same conditions as in Example 1. That is sublimable dyes were added In a Kayaset Red 130 instead of the conventional Kayaset Blue 136 in the composition of the starting material of the metal chelate compound, and replaced instead with AgCH ₃ COO CuCH ₃ (COO) _2.

(Example 5)

In Example 1, Example 5 was prepared under the same conditions as in Example 1, except that Kayaset Yellow TDN was added instead of the starting material Kayaset Blue 136 during the synthetic preparation of the sublimable disperse dye-metal chelate compound. That is, the starting material was replaced with Kayaset Yellow TDN from Kayaset Blue 136 in the composition of the sublimable disperse dye-metal chelate compound.

(Example 6)

In Example 1, 3 g of Kayaset Red 130 was added to the starting material Kayaset Blue 136 instead of Kayaset Blue 136 during the synthetic preparation of the sublimable disperse dye-metal chelate compound, and 0.4 g of CuCH ₃ (COO) ₂ was substituted for the metal salt material AgCH ₃ COO. Example 6 was prepared under the same conditions as in Example 1 except that it was added. That is sublimable dyes were added to was adjusted the amount of Kayaset Red 130 instead of the conventional Kayaset Blue 136 of the starting materials in the composition of the metal chelate compound, to adjust the amount of CuCH ₃ (COO) ₂ in place of AgCH ₃ COO.

(Comparative Examples 1 and 2)

A product made by Company M (film thickness of 50 µm, thickness of thermal barrier layer 0.3 µm) was used as Comparative Example 1, and the product of N company (film thickness of 70 µm, thickness of thermal barrier layer 0.3 µm) was applied to the commercially available thermal barrier film. Was compared with the specimen of Example as Comparative Example 2.

2. Evaluation of the Test Piece

The results of evaluating the element identification and infrared reflectance characteristics of the sublimable disperse dye-metal chelate compounds of the test specimens of Examples 1 to 6 and Comparative Examples 1 and 2 according to the following measurement methods are as shown in Table 1 below. .

end. XRD Metal Elemental Analysis

PHILIPS (Netheland), X'Pert-MPD System was used to identify the elements of the sublimable disperse dye-metal chelate compound contained in the coating film.

I. Spectroscopic Near Infrared Reflectance Observation

Spectroscopic infrared reflection observation was compared with infrared reflection characteristics by setting the baseline as a barium sulfate (white plate) with a JASCO (JAPAN) 650 UV / VIS spectrometer.

division Example Comparative example One 2 3 4 5 6 One 2 Visible light transmittance T%
(400 ~ 780nm) 32 28 38 48 56 27 25 24 Infrared reflectance R%
(780-1700 nm) 48 51 15 33 39 37 12 11

According to the contents of Table 1, it was found that in Examples 1 to 6, the visible light transmittance and the infrared reflectance were higher than those of Comparative Examples 1 and 2.

In the case of the embodiment according to the present invention, since the metal salt is contained in the sublimable disperse dye-metal chelate compound to form a metal thin film layer that reflects sunlight in the solar reflective layer, as shown in Table 1, visible light transmittance Although it was high, it was confirmed that infrared reflection characteristics are high.

For reference, FIG. 3 is a UV / VIS spectrometer reflection graph of a dye-coated solar reflective film using a sublimable dispersion dye-metal chelate compound according to Examples 2 and 3 of the present invention, and in FIG. 3, A is a sublimable dispersion. Example 2 of the dye-metal chelate compound, B shows the reflection curve of this Example 3.

4 shows that silver salt is contained as a result of elemental analysis of the sublimable disperse dye-metal chelate compound synthesized by the Reflux synthesis method of Example 2, and thus, another embodiment using the same metal salt was used. Even in the examples, it can be estimated that the sublimable disperse dye-metal chelate compound contains silver salt.

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.

The dye-coated solar reflective film according to the present invention is capable of synthesizing a sublimable disperse dye-metal chelate compound by the Reflux method using an existing simple facility, and thus has a high solubility and high solubility. A chelate compound can be obtained, and the sublimable disperse dye-metal chelate compound is coated on one surface of the base layer of the synthetic resin to form a dye-coated solar reflective layer, thereby effectively blocking the visible light region from the near infrared far infrared region, The surface of the metal thin film formed by the metal chelate complex salt having high efficiency and energy-saving solar reflecting film, and also having the solar reflecting and electrical conductive properties is patterned by the electromagnetic shielding film or the above method due to the high conductivity. Can be applied to touch panels, etc. It can be widely applied to electronic parts or materials industry.

10 base material layer 20 solar reflective layer
30: adhesive layer 40: release paper

Claims (12)

In the solar reflective film formed with a solar reflective layer on one surface of the synthetic resin film base layer,
The dyeing coating type solar reflecting film using a sublimable disperse dye-metal chelate compound, characterized in that the solar reflective layer is formed by a coating sol containing a sublimable disperse dye-metal chelate compound.
The method of claim 1,
The coating sol is a dye using a sublimable disperse dye-metal chelate compound, characterized in that 0.01 to 0.02 parts by weight leveling agent, 4 to 8 parts by weight of an organic solvent is mixed with respect to 100 parts by weight of a sublimable disperse dye-metal chelate compound. Coated solar reflective film.
The method of claim 2,
The sublimable disperse dye-metal chelate compound may be synthesized by Reflux synthesis by dissolving 1 to 3 wt% of the sublimable disperse dye and 7 to 10 wt% of the metal salt solution in 87 to 92 wt% of the carrier compound. A dye-coating type solar reflective film using a sublimable disperse dye-metal chelate compound.
The method of claim 3, wherein
The metal salt solution is a dye coating coating solar reflection film using a sublimable disperse dye-metal chelate compound, characterized in that 2 to 3 parts by weight of the metal salt is dissolved in 100 parts by weight of ethanol.
The method of claim 3, wherein
The sublimable disperse dye-metal chelate compound has the structure of Formula R ₁ -MR ₂ ,
R1 and R2 are diazo-based sublimable disperse dyes or phthalimide-based sublimable disperse dyes, respectively, which are sublimable disperse dyes, and R1 and R2 may be the same as or different from each other.
Wherein M is one of the transition metal Cu, Ag, Au, Zn, Ni or Co is selected from the dye-coating type solar reflective film using a sublimable disperse dye-metal chelate compound.
The method of claim 3, wherein
The carrier compound is diphenylphenol (di-phenylphenol), o-phenylphenol (o-phenylphenol), p-phenylphenol (p-phenylphenol), salicylic acid (salicylic acid), cresol (cresol), benzoic acid, methyl salicylic acid (methylsalicylic acid), mono-chlorobenzene, o-dichlorobenzene (o-di-chlorobenzene) using a sublimable disperse dye-metal chelate compound, characterized in that the coating sol was formed using one or more compounds Dye-coated solar reflective film.
The method according to any one of claims 1 to 6,
The solar reflective layer further includes an adhesive layer on a surface not in contact with the substrate layer, so that the solar reflective layer can be adhered to a glass such as a building or a vehicle. Solar reflective film.
The method of claim 7, wherein
The adhesive layer is a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound, characterized in that to further protect the outer surface by including a release paper on the surface not in contact with the solar reflective layer.
In the manufacturing method of the solar reflective film,
Step of preparing a sublimable disperse dye-metal chelate compound synthesized by Reflux synthesis (S1),
The coating sol manufacturing step (S2) by mixing a leveling agent and an organic solvent in the prepared sublimable dispersion dye-metal chelate compound,
Coating to form a dye-coated solar reflective layer 20 using a sublimable disperse dye-metal chelate compound on one surface of the synthetic resin film base layer 10 (S3),
Coating a pressure-sensitive adhesive layer 30 that can be adhered to the windows of the building and the vehicle (S4),
Method for producing a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound, characterized in that the step of attaching a release paper 40 that can be separated when the protective layer surface and the coating on the glass (S5) .
The method of claim 9,
The coating sol is a dye using a sublimable disperse dye-metal chelate compound, characterized in that 0.01 to 0.5 parts by weight of a leveling agent, 5 to 10 parts by weight of an organic solvent is mixed with respect to 100 parts by weight of a sublimable disperse dye-metal chelate compound. Method of manufacturing a coated solar reflective film.
The method of claim 10,
The sublimable disperse dye-metal chelate compound is a sublimable disperse dye, a metal salt is dissolved in a carrier compound and a sublimable disperse dye-metal chelate compound synthesized by the Reflux synthesis method -Production method of dye coating type solar reflective film using a metal chelate compound.
The method of claim 9,
The dye-coated solar reflective layer is coated on the base layer 10 by a coating facility using a coating sol, dye-coated by hot air and IR irradiation A method for producing a dye-coated solar light reflecting film using a sublimable disperse dye-metal chelate compound, characterized by forming a sun reflecting layer.

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