TW590886B - Anti-glaring and anti-reflecting film - Google Patents

Abstract

A method for forming an anti-glaring and anti-reflecting film is disclosed in this invention. According to this invention, an anti-glaring and anti-reflecting film can be produced by a single coating process. Therefore, according to this invention, the manufacture of the anti-glaring and anti-reflecting film can be simplified, and the yield thereof can be improved. Preferably, the anti-glaring and anti-reflecting film of this invention further comprises the functions of anti-fouling and hard-coating. Accordingly, the design of this invention can provide a more powerful anti-glaring and anti-reflecting film.

Description

590886 V. Description of the Invention (1) Yu Guan is a film formed by a special method. 1 The thin-field method of light-seeking technique of the seed film has a direct effect on the glare and resistance of the anti-correspondence system. -311, 2. [Previous technology] The display has become indispensable in modern people's lives. A missing tool. With the advancement of science and technology, people's requirements for the quality of the display are becoming higher and higher. In order for the display to exhibit better image quality, anti-glare and anti-reflection functions with anti-glare and anti-reflection functions play a very important role in the components of the display. In the conventional art, particles are usually added to the resin to make use of the scattering of light by the particles to produce anti-glare functions. As for anti-reflection, the conventional technique is to use two to three layers of resin stacks with different refractive indices to cause interference, thereby reducing the reflectivity. The first figure is a schematic diagram of an anti-glare anti-reflection film in the conventional art. Referring to the first figure, there is an antiglare layer 120 and an antireflection layer 140 on a substrate 100. In the conventional art, it is generally formed by adding particles having a particle diameter of about 1 to 100 nin or 3 0 to 3 0 0 nm to a resin and coating the surface of the substrate 1 0 0 above. The anti-glare layer 1 2 0. The above-mentioned anti-reflection layer 14 0 is formed by coating two (or more) high refractive index resins on the anti-glare layer 120 to reduce the reflectance. In the conventional anti-glare anti-reflection film, it has to go through 2 times or even more

590886 V. Description of the invention (2) The purpose of anti-glare and anti-reflection can be achieved by multiple coating processes. Because of this, this method will not only increase the difficulty of the process, but also cause a decline in yield. In addition, the thickness of the anti-glare anti-reflection film after many coatings will be greatly improved. Therefore, as the requirements for display quality increase, the anti-glare and anti-reflective films mentioned above will gradually lose their competitiveness in the market. Therefore, in view of the various deficiencies in anti-glare anti-reflection films in the conventional art, how to provide an anti-glare anti-reflection film method that can effectively improve the product yield and reduce the difficulty in the process has been an urgent research. Topic. III. [Summary of the Invention] In view of the above-mentioned background of the invention, the conventional techniques have many disadvantages in forming an anti-glare anti-reflection film. One of the main objects of the present invention is to provide a method for forming an anti-glare anti-reflection film. A single coating method is used to form the anti-glare anti-reflection film to reduce the difficulty of the process of the anti-glare anti-reflection film. Another object of the present invention is to provide a method for forming an anti-glare anti-reflection film. According to the design of the present invention, the anti-glare anti-reflection film can be formed by a single coating method to improve the yield of the anti-glare anti-reflection film. Another object of the present invention is to provide a method for forming an anti-glare anti-reflection film. The above-mentioned anti-glare anti-reflection film can be selected by using particles having a special particle size, so that the anti-glare anti-reflection film can have both by a single coating process.

Page 7 590886 V. Description of the invention (3) Anti-glare and anti-reflection effects. Another object of the present invention is to provide a method for forming an anti-glare anti-reflection film. The above-mentioned anti-glare anti-reflection film can be obtained by selecting particles with special materials to obtain an anti-glare anti-reflection film having both antifouling and hard film effects. According to the above-mentioned object, the present invention provides a method for forming an anti-glare and anti-reflection film. The method for forming an anti-glare anti-reflection film at least includes the steps of providing a substrate, and forming an anti-glare anti-reflection layer on the substrate. The anti-glare and anti-reflection layer includes at least a resin and a plurality of particles having a particle diameter of about 50 to 450 nm. According to the design of the present invention, an anti-glare anti-reflection film can be formed by a single coating to simplify the process of the anti-glare anti-reflection film and improve the yield of the anti-glare anti-reflection film. More preferably, in addition to the anti-glare and anti-reflection functions, the anti-glare anti-reflection film according to the present invention can have anti-fouling and hard film characteristics. Compared with the anti-glare anti-reflection film in the conventional art, the present invention can form the anti-glare anti-reflection film by a single coating method. In addition to the anti-glare and anti-reflection functions, the anti-glare anti-reflection film designed according to the present invention can also have anti-fouling and hard film functions. In other words, compared to the conventional anti-glare anti-reflection film, the design of the present invention can not only form an anti-glare anti-reflection film by a single coating to simplify the process and improve the yield, but also provide a ratio The anti-glare anti-reflection film of the conventional art is more functional. Even better, the anti-glare anti-reflection film according to the present invention can achieve

590886 V. Description of the invention (4) The anti-glare anti-reflection film of the known art has better definition. 4. [Embodiments] Some embodiments of the present invention will be described in detail as follows. However, in addition to the detailed description, the present invention can be widely implemented in other embodiments, and the scope of the present invention is not limited, which is subject to the scope of subsequent patents. Moreover, the different parts of the components in this specification are not drawn to size. Some scales have been exaggerated compared to other related scales to provide a clearer description and understanding of the novel. A preferred embodiment of the present invention is a method for forming an anti-glare anti-reflection film. The method for forming an anti-glare anti-reflection film at least includes providing a substrate, and forming an anti-glare anti-reflection layer on the substrate. In this embodiment, a mixture including a plurality of particles added with a resin can be coated on a surface of the substrate by a single coating method to form the above-mentioned anti-glare and anti-reflection layer. In this embodiment, the anti-glare and anti-reflection layer includes a first part of particles arranged automatically (se 1 f-assemb 1 ing) on the uppermost layer of the anti-glare and anti-reflection layer, and provides an anti-reflection and an anti-smudge (Anti-fou 1 ing) function. On the other hand, in the above-mentioned anti-glare anti-reflection layer, the resin located between the particles of the first part and the substrate and the particles of the second part can provide the functions of anti-glare and hard film. Therefore, according to the design of this embodiment, it is possible to borrow

590886 V. Description of the invention (5) An anti-glare anti-reflection film with anti-glare, anti-reflection, anti-smudge, and hard film functions is formed by a single coating method. Therefore, the design of this embodiment can simplify the manufacturing process of the anti-glare anti-reflection film, and thus can greatly improve the competitiveness in the process of the anti-glare anti-reflection film. Even better, in addition to having stronger functionality, the anti-glare anti-reflection film according to this embodiment has excellent clarity in visual effects. Another preferred embodiment of the present invention is a method for forming an anti-glare anti-reflection film. The second figure is a flowchart for forming the anti-glare anti-reflection film according to the embodiment. Referring to the second figure, a substrate is first provided, as shown in step 220. The aforementioned substrate may be composed of a transparent material. In a preferred example according to this embodiment, the composition of the substrate may include triacetyl cellulose (TAC), polyethylene terephthalate (PET), or other Transparent material. Next, an anti-glare and anti-reflection layer is formed on the substrate, as shown in step 240. The composition of the anti-glare and anti-reflection layer includes at least a plurality of particles having a particle diameter of about 50 to 450 nm and a resin. According to the design of this embodiment, the above-mentioned particles can be added to the above-mentioned resin, and then a mixed solution of the above-mentioned resin and particles can be uniformly coated on one surface of the above-mentioned substrate to form the above-mentioned anti-glare and anti-reflection. Floor. The composition of the particles includes a fluoride. Step 240 can form an anti-glare anti-reflection layer on the substrate by a single coating.

Page 10 590886 V. Description of the invention (6) Then the achievements are made up of a variety of layers, which will automatically flow with the minute itself. Because of the above listed particles, a film forming process (f i 1 m i n g) is performed by using tens of particles in the reflection process to move part of the lipids from the upper layer, as shown in step 260. The film manufacturing process includes at least one heating step. The above heating step can be done in an oven. One of the functions of the force σ thermal step in the above film-forming process is that it can help remove the above-mentioned anti-glare and anti-solvent. In addition, it is better that in the above heating step, the design of each machine is different, it usually takes a few minutes to the heating time, and in the above heating time, due to the above physical properties, There will be a part of the particles in the reflective layer (se 1 f-assemb 1 ing) at the top of the anti-glare anti-reflection layer. The anti-glare anti-reflection layer will form part of the particles from the uppermost layer (the first part). Part of the particles), and other particles (second child) are distributed in the tree structure between the above-mentioned automatically queued particles and the substrate. In this embodiment, the particles automatically arranged in the first part of the uppermost layer of the anti-glare anti-reflection layer can provide an anti-reflection function. The particles and resin in the second portion between the particles in the first portion and the substrate can provide an anti-glare function. Therefore, according to the design of this embodiment, an anti-glare anti-reflection film can be formed by a single coating, which can effectively simplify the process of the anti-glare anti-reflection film and effectively improve the anti-glare anti-reflection film. Yield. In addition, due to the characteristics of the particles used in the anti-glare and anti-reflection layer,

590886 V. Description of the invention (7) ^ The particles in the first part can provide a function of ^ ′ (a n t i-f 0 u 1 i n g) for the above-mentioned anti-glare anti-reflection film. On the other hand, in one example of this embodiment, the above-mentioned resin may be a hard coat glue (hardcoatresi η). In other words, the above-mentioned resin located between the particles of the first part and the substrate and the second part The particles can further provide a hard-coating effect to the anti-glare and anti-reflection layer. Therefore, in addition to the anti-glare and anti-reflection films, the anti-glare and anti-reflection film according to this embodiment can also have functions such as anti-smudge and hard film. That is, the design of this embodiment can form a more functional anti-glare anti-reflection film by a single coating. Another preferred embodiment of the present invention is a structure of an anti-glare anti-reflection film. The third figure is a schematic diagram of an anti-glare anti-reflection film according to this embodiment. Referring to the third figure, the structure of the anti-glare anti-reflection film according to this embodiment includes at least a substrate 3 0 0 ′ and an anti-glare anti-reflection layer 3 2 0. Among them, the substrate 300 may include triacetyl cellulose (TAC), polyethylene terephthalate (PET), or one of other transparent materials. The anti-glare anti-reflection layer 3 2 0 includes at least one resin 3 4 0 and a plurality of fluorine-containing particles 3 6 0. In one example according to this embodiment, the resin 3 40 may be / a hard coat resin for improving the hardness of the anti-glare anti-reflection film. The above-mentioned fluorine-containing particles 360 have a particle diameter of about 50 to 450 nm. In one example according to this embodiment, the composition of the above-mentioned fluorine-containing particles 360 may include fluoro-containing silica.

Page 12 590886 V. Description of the invention (8) According to the design of this embodiment, a mixed solution containing a resin 3 4 0 and a plurality of fluorine-containing particles 3 6 0 can be coated on the bottom by a single coating process. Material on 3 0 0. Then, a heating process is used to remove the residual solvent in the anti-glare anti-reflection layer 3 2 0. Finally, the above-mentioned anti-glare anti-reflection layer 32 is fixed on the substrate 300 to form an anti-glare anti-reflection film. After the coating process, due to the physical properties of the fluorine-containing particles 360, some fluorine-containing particles 3600 will be automatically arranged on the uppermost layer of the antiglare antireflection layer 3200. Referring to the third figure, the above-mentioned anti-glare anti-reflection layer 3 2 0 includes a first layer 3 2 4 formed by the first portion of fluorine-containing particles 3 6 0 and a second portion of the fluorine-containing particles 3 The second layer 3 2 8 formed by 60 and resin 3 4 0. The second layer 3 2 8 is located between the first layer 3 2 4 and the substrate 3 0 0. According to the design of this embodiment, since particles having a particle diameter of about 50 to 450 nm have excellent light scattering characteristics, in this embodiment, a plurality of particles are automatically arranged on the anti-glare anti-reflection layer 3 2 The first layer 3 2 4 formed by the first part of the uppermost layer 0 of the fluorine-containing particles 3 6 0 can exert an excellent anti-reflection function. On the other hand, the second layer 3 2 8 formed by the second part of the fluorine-containing particles 3 60 and the resin 3 4 0 can exert an anti-glare function. More preferably, due to the characteristics of the fluorine-containing particles 36 in this embodiment, the above-mentioned first layer 3 2 4 may have an anti-staining property. In addition, the second layer 3 2 8 formed by the resin 3 40 and the second portion of the fluorine-containing particles 3 60 can further exert the characteristics of a hard film. In other words, the design according to this embodiment can be achieved by a single coating method.

Page 13 590886 V. Description of the invention (9) Form an anti-glare anti-reflection film with anti-glare, anti-reflection, anti-fouling, and hard film functions. It is found from the results of a study of the present invention that as the fluorine content in the fluorine-containing particles 360 increases, the reflectance and refractive index of the fluorine-containing particles 360 will decrease. In other words, when the weight percentage of fluorine in the fluorine-containing particles 3 60 is increased, the anti-glare and anti-reflection characteristics of the anti-glare anti-reflection film can be improved. In one example according to the present invention, the weight percentage of fluorine in the fluorine-containing particles 360 is about 10% to 30%. In another example, the weight percentage of the fluorine content of the fluorine-containing particles 360 in the molecular weight is about 20%, and the anti-glare anti-reflection film at this time can exhibit excellent anti-glare and anti-reflection functions. In the conventional anti-glare anti-reflection film, it is usually necessary to coat 2 to 3 layers of resins having different refractive indexes on the substrate to produce an anti-reflection effect. In addition, in order to produce anti-glare effects, a layer of resin with particles added is usually coated on the substrate to provide anti-glare functions through the scattering of light by the particles. The refractive index of the particles is relatively close to that of the resin. That is, the anti-glare anti-reflection film in the above-mentioned conventional techniques must use at least two coating processes to produce the anti-glare anti-reflection effect. Therefore, the process difficulty of the anti-glare anti-reflection film of the conventional art will be increased, and the yield of the anti-glare anti-reflection film will be reduced. Compared with the anti-glare anti-reflection film in the above-mentioned conventional art, in the design of the present invention, a layer of added particles can be applied by a single coating method.

Page 14 590886 Fifth, the refraction of the resin on the bottom of the description of the invention (glaringly anti-fouling and anti-fouling and hard film, the anti-glare and anti-fouling ratio are known. The thickness of the anti-reflection film is better than the anti-reflection ratio of the anti-reflection film. The technology of the reflective film of the invention is that the film does not change the anti-reflection film on the display. It's anti-glare and resistant. In other words, the design is not only easy to make anti-glare anti-reflection, the thickness of the anti-thin film of the present invention, the size becomes a display film, because the added anti-glare anti-reflection becomes anti-refractive reflection, and the anti-glare of the film can be obtained by the way. So more and more added film is integrated above. The formation of the anti-glare and anti-glare layer includes a resin, and the above-mentioned granules can be coated by a single mixed solution. Therefore, the degree of difficulty of the hair is even better. According to the present invention, the glare anti-reflection layer, and the compound can be coated on the cloth at a time. The particle size is a fluorine-containing method, and the above-mentioned substrate can not only improve the anti-glare anti-reflection film glare resistance rate. The work is better than the reflection by a lifting function. When the thinner the burden is, the better the shape is to the substrate. The particles will come up to be able to reduce the anti-reflection. In addition to the reflection, according to the knowledge of the energy, the single-use yield is better. With the limitation and thickness of the clear film, in addition to the present invention, the coating is more technical, and it is more resistant than the present invention. And so on because of clarity. The anti-glare and anti-reflection design of the above-mentioned particles can be formed with an anti-glare anti-reflection method to provide an anti-glare anti-reflection anti-reflection film with anti-glare know-how. Moreover, the present invention can achieve an anti-glare anti-reflection film. The method less includes providing a substrate, and above. The anti-glare and anti-reflection particles of 50 to 450 nm. Its. According to the design of the present invention, the resin and the plurality of particles are described above. The resin anti-glare anti-reflection film is manufactured with a low anti-glare anti-reflection film. Even better is the anti-glare and anti-reflection functions.

Ϊ́ Μ

Page 15 590886 V. Description of the invention (11) In addition, it can also have anti-fouling and hard film characteristics. The above description is only a preferred embodiment of the present invention. This embodiment is only used for illustration, not for limiting the scope of patent application of the present invention. Changes can be made and implemented without departing from the essence of the invention, and such changes should still fall within the scope of the invention. Therefore, the scope of the present invention is defined by the following patent application scope. Participate

Page 590886 Brief description of the drawings 5. Simple description of the drawings The first picture is a schematic diagram of an anti-glare anti-reflection film according to the known art; the second picture is an anti-glare anti-reflection film according to the present invention The flowchart and the third diagram are schematic diagrams of an anti-glare anti-reflection film according to the present invention. Representative symbols of the main parts: 100 substrate 12 0 anti-glare layer 1 4 0 anti-reflection layer 2 2 0 step of providing a substrate 24 0 step of forming an anti-glare anti-reflection layer on the substrate 2 6 0 Steps in the film process 3 0 0 Substrate 3 2 0 Anti-glare anti-reflection layer 324 First layer "3 2 8 Second layer 3 4 0 Resin 3 6 0 Fluoride particles

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Claims (1)

590886 _Case No. 92107793_ YYYY__ VI. Patent Application Scope 7. The method for forming an anti-glare and anti-reflection film according to item 1 of the patent scope, wherein the above resin includes a hard coat resin. 8. The method for forming an anti-glare anti-reflection film according to item 1 of the patent application scope, wherein the above substrate comprises cellulose triacetate (TAC). 9. The method for forming an anti-glare anti-reflection film according to item 1 of the scope of patent application, wherein the above substrate comprises polyethylene terephtha late (PET). 10. The method for forming an anti-glare anti-reflection film according to item 1 of the scope of patent application, further comprising a film-forming process after the step of forming the anti-glare anti-reflection layer. Page 19