KR100924899B1 - Light filter for plasma display panel with anti-electromagnetic radiation light-filtering functions - Google Patents

Abstract

An optical filter for a plasma display panel having electromagnetic radiation prevention and light filtering functions includes a glass substrate, an electromagnetic radiation prevention / light filtering coating coated on the surface of the glass substrate by continuous magnetron sputtering, and an oxidation / corrosion compounded with the coating. A resistive plastic film layer and a thin metal film in contact with the coating to extract the electrode. The coating comprises 13 or 17 film layers made of repeated coatings of TiO ₂ / AZOY, ITO / Ag / AZOY, or ITO / TiO ₂ . Optical filters can be produced at low cost and high production rates. The light filter has high strength, high transmittance, the best effect of anti-electromagnetic radiation and light filtering and long life.

Optical Filters, Glass Substrates, Electromagnetic Radiation Proof / Light Filtering Coatings, Thin Metal Films

Description

LIGHT FILTER FOR PLASMA DISPLAY PANEL WITH ANTI-ELECTROMAGNETIC RADIATION LIGHT-FILTERING FUNCTIONS}

The present invention relates to a display light filter, and relates to an optical filter for a plasma display panel having an electromagnetic radiation prevention and light filtering function.

The anti-reflective, electromagnetic radiation-resistant and light filtering functions of the optical filters of currently available plasma display panels combine the plastic film on the outer surface of the glass piece formed by the sputtering and form two plastic layers on the other side of the glass. Obtained by bonding an electromagnetic anti-radiation / light filtering film. One of the plastic layers includes a conductive metal grid formed in the film by photo etching or a metal grid layout to provide electromagnetic radiation protection. Such films with metal wires or metal grids are formed with film layers formed by color film brushing and bonding of infrared plastic films. Both films offer electromagnetic radiation protection and light filtering. Due to the high standard properties of the bonding and synthesis techniques for producing each of a plurality of films with different functions by the lamination method, mechanical continuous productivity is difficult to obtain, among other disadvantages including high cost, low yield and low permeability of the product. .

Chinese Patent Publication No. CN 1509490A, entitled “LIGHT FILTER FOR PLASMA DISPLAY PANEL”, discloses a variety of films and transparent substrates including antireflective films, near-infrared shielding films, electromagnetic interference shielding (EMI) shielding films laminated to a substrate. do. These functional films are tall films for optical filters, which are individually coated on a plastic base or plastic film, and the functional films are laminated on the transparent substrate layer in layers. The transparent substrate is formed by laminating at least two glass layers and at least one adhesive layer between the resin layers.

The individual lamination method of the laminate subsequent to the film provides a small improvement over the above-described method, but has the disadvantages of low efficiency, low yield and high cost. Good product ratios are greatly reduced because residual volatiles of the bonding agent between the solvent and the layer in the bubbles are possible.

Chinese Patent Application No. 200410069275, entitled “LAMINATION AND LIGHT FILTER FOR DISPLAY USING THE SAME”, is resistant to oxidation or corrosion of a thin silver film layer of an EMI shielding film, which is one of the most important films of an optical filter. Teach the approach. Corrosion is referred to herein as "solidification of silver atoms in a thin silver film layer" and "white spot" is a phenomenon of corrosion in a thin silver film layer. In order to improve the transmittance, a protective layer is provided on the outermost of the three thin silver film layers having high reflectance, and the protective layer includes a polymer bonding agent and inorganic particles.

The inorganic particles are preferably oxides, more preferably silicon oxides, tin oxides, zinc oxides, indium oxides, antimony trioxides, aluminum oxides or zirconium oxides, and most preferably antimony oxides and tin monooxides or antimony oxides. And a compound of tin oxide.

The bonding agent and the inorganic particles are dissolved by the solvent or solution while the inorganic particles are dispersed. The mixed solution is applied to a film composed of a thin silver film layer and a permeability improving high reflective thin film layer. In essence, the mixed solution is applied to the highly reflective thin film to form the final protective layer. This application suggests a clear and surprising prevention of "white spots".

The use of solvents or solutions to form thin film layers composed of metal oxides and bonding agents creates problems with environmental protection and contamination during processing. The thickness and visible light transmittance of the thin film are difficult to control. Quality testing cannot be performed on the manufacturing line. Yield is low and uncontrolled. The thin film is unstable and the surface resistance of the outermost surface of the film layer is increased after the provision of the protective layer because of the polymer resin which worsens the EMI shielding effect. That is, even if the "white spot" problem is fixed, the EMI shielding effect of the three thin silver film layers is worsened. This document refers to a control method for reducing corrosion and reducing "white spots" of thin silver film layers. However, by providing a protective film on the transparent layer, the high reflectivity thin film layer on the outermost surfaces of the three silver thin film layers provides an EMI shielding film having insufficient properties. The surface resistance is at most 2 mW / cm 2 and below the standard value of 1.5 mW / cm 2 for household products. This patent application discloses a method or proposal for providing three thin film layers of metal oxide (or four if four thin film layers are used) between three thin silver film layers and a transparent high reflectivity thin film layer. Does not disclose or suggest a method or suggestion for continuous magnetron sputter deposition, and does not include indium tin oxide (ITO), aluminum tin oxide (AZOY) films and near infrared, far-infrared and ultraviolet light filtering, as well as visible light transmission, Three or four layers of metal oxides, such as other organic synthesis of ITO or AZOY / Ag / TiO ₂ films to improve corrosion protection properties and EMI shielding effects.

Chinese patent application 01804419.0 discloses an optical filter for display. The optical filter includes a transparent conductive layer (D) deposited on one or both surfaces of the polymer thin film (B). The transparent conductive layer (D) is a synthesis unit of the high reflectivity transparent thin film layer (Dt) and the thin metal film layer (MD). The high reflectivity transparent thin film layer (Dt) is deposited on the top layer after two to four depositions. The high reflectivity transparent thin film layer (Dt) comprises at least an oxide layer mainly composed of at least one of indium, tin and zinc. The thin metal thin film comprises at least a silver or silver alloy layer. This application also proposes a single layer of antireflective film layer of transparent conductive layer (D) having a surface resistance of 0.01 to 30 mW / cm 2 as well as the air side (ie, the viewer side) of the polymer thin film (B). . Practically, the seven layers of films obtained after two to four depositions of Dt / Dm thin films have a surface resistance of at least 5 mW / cm 2 and do not meet the standard of 1.5 mW / cm 2 of home television. That is, the method disclosed in this application is not practical. Although this method is available, the transparent conductive layer D utilizes an EMI shielding net made of copper boards or metal wire cloths by etching and synthesis disclosed in the aforementioned patent application. Such EMI shielding nets do not absorb or block ultraviolet light, near infrared light and infrared light. The thin polymer films disclosed in this application are suitable for bonding to fluorescent screens of displays.

The above-mentioned patent application discloses the use of silver as the main film layer in which a transparent metal oxide film layer is deposited between the silver layer and the TiO ₂ layer in order to protect the silver layer in which the high reflectivity TiO ₂ film layer is deposited and its stable anti-oxidation property or Do not teach. At the same time, the film layer is a nano-sized thin film capable of absorbing infrared light, and the synthesis of this film layer and the TiO ₂ film layer improves the absorption and blocking performance of ultraviolet light, near infrared light and far infrared light. The aforementioned patent application also states that five film layers of metal oxides and TiO ₂ are deposited on both sides, and the five layers have a surface resistance of less than 1.5 mW / cm 2 and can filter ultraviolet light and near infrared light. The use of the silver layer as a base has not been disclosed, which can be repeated three to five times to form the structure of two film layers.

In order to overcome the above disadvantages, the present invention utilizes a method for producing an optical filter by continuous magnetron sputtering in order to have a high production rate and to greatly reduce the cost. The light filters produced thus have the highest performance and long life of high intensity, high transmittance, electromagnetic radiation protection and light filtering.

The optical filter for a plasma display panel having an electromagnetic radiation prevention and light filtering function according to the present invention is a glass substrate, an electromagnetic radiation prevention / photofiltering coating coated on one surface of the glass substrate by continuous magnetron sputtering, and the oxidation synthesized with the coating. A corrosion resistant plastic film layer and a thin metal film in contact with the coating for extraction of the electrode. The coating is TiO ₂ / AZOY / Ag / AZOY / TiO ₂ , or TiO ₂ / ITO / Ag / AZOY / TiO ₂ , or TiO ₂ / ITO / Ag / AZOY / TiO ₂ , or TiO ₂ / AZOY / Ag / ITO 13 or 17 film layers made of 3 or 4 repeated sets of / TiO ₂ , the AZOY layer is an oxide film layer doped with zinc oxide and aluminum oxide, and the ITO layer is indium doped with tin It is a film layer of an oxide. The coating of 13 film layers on a glass substrate may comprise a first film layer of TiO ₂ , a second film layer of AZOY or ITO, a third film layer of Ag, a fourth film layer of AZOY or ITO, and a fifth film layer of TiO ₂ . , The sixth film layer of AZOY or ITO, the seventh film layer of Ag, the eighth film layer of AZOY or ITO, the ninth film layer of TiO ₂ , the tenth film layer of AZOY or ITO, the eleventh film layer, A twelfth film layer of AZOY or ITO and a thirteenth film layer of TiO ₂ . The coating of the seventeenth film layer on the glass substrate may include a first film layer of TiO ₂ , a second film layer of AZOY or ITO, a third film layer of Ag, a fourth film layer of AZOY or ITO, and a fifth film layer of TiO ₂ . , The sixth film layer of AZOY or ITO, the seventh film layer of Ag, the eighth film layer of AZOY or ITO, the ninth film layer of TiO ₂ , the tenth film layer of AZOY or ITO, the eleventh film layer, The twelfth film layer of AZOY or ITO, the thirteenth film layer of TiO ₂ , the fourteenth film layer of AZOY or ITO, the fifteenth film layer of Ag, the sixteenth film layer of AZOY or ITO and the seventeenth film layer of TiO ₂ Include. The plastic film layer can be a plastic film having a transmittance of at least 85% or up to 90% and can prevent the coating from oxidizing and corroding. The film not only prevents and delays corrosion and degradation of the EMI shielding coating, but also prevents breakage of the bonded glass substrate. The optical filter has the best performance and is provided as a protective shield for the plasma display panel. In particular, the metal oxide layer of ITO or AZOY is provided between the Ag layer and the TiO ₂ layer to provide an Ag layer with improved resistance to oxidation and corrosion, so that after three or four repeated coatings, Solve the "white spot" problem while meeting the resistance standard. Instead, the surface resistance of the coating is 1.5 kW / cm 2 or less. In addition, production rates are high, coating techniques are standard and common, and costs are reduced.

The thickness of the 13 or 17 film layers of the coating is as follows. The first film layer of TiO ₂ is 10 to 150 nm, the second film layer of AZOY or ITO is 1.0 to 30 nm, the third film layer of Ag is 5 to 30 nm, and the fourth film layer of AZOY or ITO Is 1.0 to 30 nm, the fifth film layer of TiO ₂ is 10 to 200 nm, the sixth film layer of AZOY or ITO is 1.0 to 30 nm, the seventh film layer of Ag is 5 to 30 nm, and AZOY Or the eighth film layer of ITO is 1.0 to 30 nm, the ninth film layer of TiO ₂ is 10 to 200 nm, the tenth film layer of AZOY or ITO is 1,0 to 30 nm, and the eleventh film of Ag The layer is 5 to 30 nm, the 12th film layer of AZOY or ITO is 1.0 to 30 nm, the 13th film layer of TiO ₂ is 10 to 200 nm, and the 14th film layer of AZOY or ITO is 1.0 to 30 nm And the fifteenth film layer of Ag is 5 to 30 nm, the sixteenth film layer of AZOY or ITO is 1.0 to 30 nm, and the seventeenth film layer of TiO ₂ is 10 to 150 nm.

The thin metal film surrounds the glass substrate and is synthesized with the coating through the electrically conductive gel, or the electrically conductive bonding agent surrounds the glass substrate by printing and curing and is synthesized with the coating. The metal film contacts the EMI shielding coating and surrounds the edge of the substrate in a U-shaped fashion or is bonded along the perimeter of the face of the EMI shielding coating. A thin metal film is provided to extract the electrodes and transmits electromagnetic radiation shielded by the EMI shielding coating to ground through the display. Alternatively, the thin metal film can be formed after the printed electrically conductive bonding agent is cured, which is more effective in automation than bonding the thin metal film. The cost is reduced and the bonding and sealing of the EMI shielding coating is more reliable.

A plastic film layer synthesized with the coating and preventing the coating from oxidizing and corroding is bonded by a layer of bonding agent to the coating. Optionally, the plastic film layer may be a bonding agent layer for bonding to another substrate to form an optical filter plate or to be bonded to a plasma display panel as an integral member to obtain a thin structure display.

The plastic film layer may be a biaxially oriented polyester (BOPET) film, a polycarbonate (PC) film, a polyvinyl butyral (PVB) film or a polyester (PET) film. Blue dyes can be added into the bonding agent to adjust and reduce yellow light having a wavelength of 596 nm emitted by the display, making the red color more vivid. At least one of the magenta dye, the red dye and the black dye may be added to the bonding agent to control the color temperature and transmittance of the display. If desired, purple light absorbers and antioxidants may be added to the bonding agent.

An antireflective (AR) film layer may be coated on the plastic film layer and includes at least two layers of SiO ₂ and Nb ₂ O ₅ or TiO ₂ . For example, the AR film layer is composed of four layers of SiO ₂ / Nb ₂ O ₅ or TiO ₂ / SiO ₂ / Nb ₂ O ₅ or TiO ₂ . Bonding the plastic film layer coated with the AR film layer on the EMI shielding coating provides an optical filter with better visible light transmittance and increased brightness. One side of the plastic film and the AR film with electromagnetic radiation prevention / light filtering coating can be utilized as the viewer side, which not only provides EMI shielding and light filtering function but also prevents reflection of ambient light. Visual quality is improved.

The AR film layer is coated on the other side of the glass substrate by continuous magnetron sputtering and includes at least two layers of SiO ₂ and Nb ₂ O ₅ or TiO ₂ . As described above, the AR film layer may consist of the four layers described above, and the SiO ₂ / Nb ₂ O ₅ (or TiO ₂ ) layer is prepared by intermediate frequency reactive double magnetron sputtering. For AR film layers formed with four layer coatings, the reflectivity in the visible light band is less than 0.5% depending on the reflectance curve. The reflectivity of the two stacked layers is less than 3%. Importantly, the AR film layer may face the viewer to reduce reflection of the side of the substrate facing the environment. Image quality is improved and many existing serious reflection problems on the viewer side of the plasma display panel are solved.

In the above-described optical filter, the plastic film layer synthesized with the coating of the glass substrate to prevent oxidation and corrosion of the coating was added with a blue dye added to control and reduce yellow light having a wavelength of 596 nm emitted by the display. Bonding agent. The substrate may be bonded with another substrate to form an optical filter. By using the plastic film layer as a layer of the bonding agent, a glass substrate having EMI shielding function and light filtering function can be bonded with other glass substrates by conventional techniques, and the plastic substrate becomes a more functional optical filter.

In the above-described optical filter, the plastic film layer synthesized with the coating on the glass substrate in order to prevent the coating from oxidation and corrosion is utilized as a bonding agent to which a color temperature controlling dye and a purple light absorber are added. Bonding agents are bonded directly to the plasma display panel to reduce the thickness of the display and improve visual quality at wider viewing angles.

The surface resistance of the above-mentioned coating is 1.5 Pa · cm 2 or less.

The glass substrate of the optical filter described above is a cured glass or semi-hardened glass that has been chemically or physically processed to improve the strength. Bonding a high strength plastic film in addition to the EMI coating with electromagnetic radiation protection and light filtering provides both the function of the optical filter and the protective shielding.

On the display viewer side of the optical filter described above, the transmittance of the optical filter is 30% to 70% in visible light having a wavelength of 380 to 780 nm, less than 18% in infrared light having a wavelength of 850 nm, and a wavelength of 950 nm. In infrared light having less than 10%.

In the above-described optical filter, the reflectance on the other side of the glass substrate without the antireflective film layer is less than 6% in visible light having a wavelength of 380 to 780 nm.

In the above-described optical filter, the reflectance at the other side of the glass substrate coated with the antireflective film layer is less than 4% in visible light having a wavelength of 380 to 780 nm.

According to the invention, the layer below the Ag layer is an ITO layer or an AZOY layer, whereas the layer above the Ag layer is also an ITO layer or an AZOY layer. The ITO layer or AZOY layer according to the present invention can be easily controlled by the coating technology while having high yield, stable optical coefficient and high transmittance. The thickness can be thickened to provide improved protection and oxygen shielding effect for the Ag layer. Importantly, the synthetic ITO layer or AZOY layer on both sides of the Ag layer is assembled with the plasma display panel on both sides of the optical filter while reducing the ability to filter the ultraviolet light wavelength, the near infrared light wavelength and the far infrared light wavelength and shield the EMI. In addition, the film thickness is symmetrically designed such that a repeated structure of three silver layers or four silver layers is obtained through repeated coatings while a four layer coating technique for a single Ag layer is satisfied during coating. Thus, the coating is easy and the equipment cost is thus reduced.

The optical filter according to the invention can be formed by bonding a glass or glass substrate having a thin metal film in contact with the EMI coating to extract the electrodes as well as the EMI shielding coating with a plastic film that prevents oxidation and corrosion of the coating and The basic optical filter for a plasma display panel is formed. Optionally, an AR film may be coated on the plastic film layer to improve the visible light transmittance of the optical filter and to reduce the visible light reflectivity on the viewer side. The optical filter can be assembled on the film bonding side facing the viewer, and the glass is a safety glass. In addition, the AR film can be coated on the other side of the substrate coated with the EMI shielding coating so that the antireflection effect, in particular, the antireflection effect to the ambient light is obtained on the viewer side, thereby improving the image quality. The coating solves the problems of EMI shielding and ultraviolet light, near infrared light and far infrared light, which can only be solved by stacking a plurality of functional film layers in the prior art. In addition, the production ratio is high, the cost is low, the service life is long, and better functionality is obtained.

The optical filter of the present invention has low cost, high production rate, high intensity, high transmittance, best effect of anti-electromagnetic radiation prevention and light filtering, and long life.

Other objects, advantages and features of the present invention will become apparent from the following detailed description with reference to the accompanying drawings.

Example 1:

1 shows an example of an optical filter of a first example according to the present invention. Referring to FIG. 1, the glass substrate 1 is cleaned with deionized water and a coating comprising three (or four) silver films shown in FIG. 2, ie TiO ₂ / ITO or AZOY / Ag / ITO or Is an electromagnetic anti-radiation / light filtering coating (2) (EMI shielding coating) comprising 13 film layers made of a repeated structure of AZOY / TiO ₂ , wherein two adjacent TiO ₂ layers are combined to form a coating Go through the magnetron sputtering production line. The TiO ₂ layer is prepared by medium frequency reactive double magnetron sputtering. The layers of Ag and ITO or AZOY are prepared by flat DC magnetron sputtering. The AZOY layer is an oxide film layer doped with zinc oxide and aluminum oxide. Targets consisting of ZnO and Al ₂ O ₃ can be developed targets and are obtained by the German company GfE Metalle und Materralien Gmbh. The percentage of ZnO and Al ₂ O _{3 in} the material is 99.95% to provide similar performance as the ITO film layer, and high permeability can be obtained under the same thickness. DC pulse magnetron sputtering can be controlled as conventional and provides a state of the art film deposition technique that is 3/4 cheaper than ITO. TiO ₂ / ITO or AZOY / Ag / ITO or AZOY / TiO ₂ TiO ₂ / ITO or AZOY / Ag / ITO or AZOY / TiO ₂ to the additional layer is to form a 4 is a layer structure comprising a 17 film layer In the case of addition to three silver layer structures consisting of, each functional ratio is also guaranteed. In particular, the surface resistance can be lowered to 1.5 Pa · cm 2 or less and 1.3 Pa · cm 2 or less. The performance of the resulting EMI shielding coating is shown in FIG. Visible light transmittance exceeds 76% and is considerably lower in the near infrared band. The yellow light band emitted by the neon of the display at 596 nm is absorbed by the addition of the blue dye. Permeability has a minimum of 30%. Surface resistance R is equal to 1.3 +/- 0.02 kPa * cm <2>. The smaller the surface resistance, the more electromagnetic emissions are blocked. The plastic film layer 4 is bonded by the acrylic ester bonding agent layer 4 to the face of the EMI shielding film layer 2. The plastic film layer 4 is a biaxially oriented polyester (BOPET) film in which the coating can prevent oxidation and corrosion, and has a transmittance of more than 85%. After bonding of the plastic film layer and addition of the blue dye and the dye for color temperature adjustment, a transmittance between 30% and 75% is obtained. The metal film (foil) 5 is bonded by an electrically conductive gel 7 to the side of the substrate coated with the EMI shielding coating at a position spaced from the periphery of the side of the substrate by about 10 mm. The metal film 5 is for contacting the EMI shielding coating and for extracting the electrode. Depending on the presence or absence of an EMI shielding coating of the optical filter facing the plasma display panel 9, the metal film (foil) is in contact with the EMI shielding coating and surrounds the edge of the substrate in a U-shape or the periphery of the side of the EMI shielding coating. Are bonded accordingly. In the case of covering the edges of the substrate in a U-shape, the optical filter may face the plasma panel on both sides when provided only to shield electromagnetic radiation and filter light. The other side of the plastic film and the substrate is coated with an antireflective (AR) film by intermediate frequency reactive double magnetron sputtering. The structure of the anti-reflection film layer is composed of four layers of SiO ₂ / NbO ₅ or TiO ₂ as shown in FIG. The performance curve of the resulting AR film layer has a reflectance R of less than 0.5% in the visible light band as shown in FIG. The reflectance of the two laminated layers is less than 3%. This example utilizes a coating consisting of layers consisting of three or four layers of TiO ₂ / ITO or AZOY / Ag / ITO or AZOY / TiO ₂ repeatedly by continuous magnetron sputtering. Thus, the coatings formed are solid and meet the electromagnetic radiation protection standards of household products, while having high permeability, low surface resistance (less than 1.5 kW · cm 2), high production rate, high yield and low cost. In addition, the quality is improved by providing the antireflection layer. Importantly, the lifetime of the EMI shielding coating is extended.

The thickness of 13 or 17 film layers of this example EMI shielding coating is as follows.

Film layer material (13 layers) Thickness (nm) Film layer material (17 layers) Thickness (nm) Board Board TiO ₂ 25 TiO ₂ 30 ITO or AZOY 5 ITO or AZOY 4 Ag 18 Ag 15 ITO or AZOY 5 ITO or AZOY 4 TiO ₂ 50 TiO ₂ 60 ITO or AZOY 5 ITO or AZOY 4 Ag 18 Ag 15 ITO or AZOY 5 ITO or AZOY 4 TiO ₂ 50 TiO ₂ 60 ITO or AZOY 5 ITO or AZOY 4 Ag 20 Ag 17 ITO or AZOY 5 ITO or AZOY 4 TiO ₂ 25 TiO ₂ 60 TiO ₂ 4 Ag 17 ITO or AZOY 4 TiO ₂ 30

Example 2:

6 shows the structure of Example 2 which is substantially the same as Example 1. FIG. The difference between Example 2 and Example 1 is that there is no antireflective layer coated on the plastic film layer of the EMI shielding coating.

Example 3:

7 shows the structure of Example 3 which is substantially the same as Example 1. FIG. The difference between Example 3 and Example 1 is that there is no antireflection layer on the other side of the substrate. When measuring the surface without the AR film layer, the reflectivity is less than 5% (or less than 4% in four silver layer structures), which meets the requirements of the optical filter. Transmittance and reflectivity are average values of visible light. The optical filter can be mounted on the surface bonded to the plastic film layer facing the viewer. In this case, the reflectivity on the viewer side is less than 3%, while the transmittance is between 30% and 75%.

Example 4:

8 schematically shows the structure of Example 4 which is substantially the same as Example 1. FIG. The difference between Example 4 and Example 1 is that there is no antireflective film layer on the other side of the plastic film or substrate. The light filter utilizes a layer of plastic film that is mounted and free of antireflective film facing the viewer. The transmission of visible light is between 30% and 70% and the reflectance is less than 6% (or less than 4% in four silver layer structures), which meets the requirements of the optical filter. Transmittance and reflectivity are average values of visible light.

Example 5:

9 shows the structure of Example 5. FIG. Referring to Fig. 9, there is a glass substrate 1 having an EMI shielding coating coated on a surface bonded by a plasma display panel and an acrylic ester bonding agent layer 3. The BOPET plastic film 8 is bonded to the viewer side of the substrate 1 to which the antireflection film 6 is bonded. The thickness of the display is reduced. Although the plastic film on the side of the plasma display panel of the above example is replaced with a bonding agent, the electromagnetic radiation prevention and light filtering function is still maintained. In this case, the reflectivity requirement is less than 6%, and this example is reduced in cost by not bonding the plastic film 8 coated with the antireflective film.

The above examples provide another extension of the present invention. Nevertheless, these examples are not intended to limit the scope of the present invention. Instead, all techniques based on the above teachings are within the scope of the present invention.

1 is a schematic cross-sectional view of an example of an optical filter according to the present invention;

2 is a schematic representation of an electromagnetic anti-radiation coating having three repeated layers of light filters according to the present invention.

3 is a schematic characteristic diagram showing the shielding and filtering of electromagnetic wavelengths, near infrared light, far infrared light, ultraviolet light and visible light transmittance of the optical filter according to the present invention;

4 is a schematic diagram of a structure of an antireflection film.

5 is a curvature of the limit (R%) of the antireflection film (AR film).

6 illustrates another example of the optical filter according to the present invention;

Fig. 7 shows another example of an optical filter according to the present invention in which antireflection function is not provided on the side of the optical filter.

Fig. 8 shows another example of the optical filter according to the present invention in which the antireflection function is not provided on the other side of the optical filter.

9 shows another example of an optical filter according to the present invention in which an antireflection film is bonded to the viewer side of a substrate.

<Explanation of simple symbols in the drawing>

1: glass substrate

2: electromagnetic radiation resistant / light filtering coating

3: bonding agent layer

4: plastic film layer

5: metal film

6: antireflection film layer

7: electrically conductive gel

Claims (14)

It is an optical filter for plasma display panel having electromagnetic radiation prevention and light filtering function, A glass substrate 1; An electromagnetic radiation prevention / light filtering coating (2) coated on the surface of the glass substrate (1) by continuous magnetron sputtering; An oxidation / corrosion resistant plastic film layer (4) combined with the coating (2); A thin metal film (5) in contact with the coating (2) for extracting electrodes; The coating 2 is TiO ₂ / AZOY / Ag / AZOY / TiO ₂ , or TiO ₂ / ITO / Ag / AZOY / TiO ₂ , or TiO ₂ / ITO / Ag / ITO / TiO ₂ , or TiO ₂ / AZOY / 13 or 17 film layers made of 3 or 4 repeated sets of Ag / ITO / TiO ₂ , The AZOY is a film layer of an oxide doped with zinc oxide and aluminum oxide, the ITO layer is a film layer of indium oxide doped with tin, The coating 2 of the 13 film layers on the glass substrate 1 comprises a first film layer of TiO ₂ , a second film layer of AZOY or ITO, a third film layer of Ag, a fourth film layer of AZOY or ITO, A fifth film layer of TiO ₂ , a sixth film layer of AZOY or ITO, a seventh film layer of Ag, an eighth film layer of AZOY or ITO, a ninth film layer of TiO ₂ , a tenth film layer of AZOY or ITO, An eleventh film layer of Ag, a twelfth film layer of AZOY or ITO and a thirteenth film layer of TiO ₂ , The coating of the seventeenth film layer on the glass substrate 1 may include a first film layer of TiO ₂ , a second film layer of AZOY or ITO, a third film layer of Ag, a fourth film layer of AZOY or ITO, a TiO ₂ Fifth film layer, sixth film layer of AZOY or ITO, seventh film layer of Ag, eighth film layer of AZOY or ITO, ninth film layer of TiO ₂ , tenth film layer of AZOY or ITO, agent of Ag 11 film layer, 12th film layer of AZOY or ITO, 13th film layer of TiO ₂ , 14th film layer of AZOY or ITO, 15th film layer of Ag, 16th film layer of AZOY or ITO and agent of TiO ₂ 17 film layers, The oxidation / corrosion resistant plastic film layer 4 is combined with the coating 2 via a layer of bonding agent, The plastic film layer 4 may be a biaxially oriented polyester film, a polycarbonate film or a polyvinyl butyral film, and in the bonding agent to control and reduce yellow light having a wavelength of 596 nm emitted by the display. Blue dye may be added, and at least one of magenta dye, red dye and black dye is added to the bonding agent to adjust the color temperature and transmittance of the display. . The film layer of claim 1, wherein the 13 or 17 film layers of the coating (2) have a thickness from the bottom film layer to the top film layer along the lamination direction, and the first film layer of TiO ₂ is 10 to 150 nm. , The second film layer of AZOY or ITO is 1.0 to 30 nm, the third film layer of Ag is 5 to 30 nm, the fourth film layer of AZOY or ITO is 1.0 to 30 nm, and the fifth film of TiO ₂ The layer is 10-200 nm, the sixth film layer of AZOY or ITO is 1.0-30 nm, the seventh film layer of Ag is 5-30 nm, the eighth film layer of AZOY or ITO is 1.0-30 nm and , The ninth film layer of TiO ₂ is 10 to 200 nm, the tenth film layer of AZOY or ITO is 1.0 to 30 nm, the eleventh film layer of Ag is 5 to 30 nm, and the twelfth film of AZOY or ITO and the layer is 1.0 to 30 ㎚, and the second film layer 13 is from 10 to 200 ㎚, and the film layer of claim 14 AZOY or ITO is from 1.0 to 30 ㎚ of TiO _2, the film layer 15 of Ag is 5 If 30 ㎚ and, AZOY or claim 16, the film layer of the ITO is 1.0 to 30 ㎚, the 17th film layer is 10 to 150 ㎚ The optical filter for a plasma display panel having the electromagnetic radiation protection and the optical filtering of TiO _2. 2. The glass substrate according to claim 1, wherein the thin metal film 5 surrounds the glass substrate 1 and is bonded with the coating 2 through the electrically conductive gel 7, or by printing and curing of the electrically conductive bonding agent. (1) An optical filter for a plasma display panel having electromagnetic radiation prevention and light filtering functions surrounding and combined with a coating. delete delete Any one of claims 1 to A method according to any one of claim 3, including an anti-reflection film layer 6 is coated on the plastic film layer (4) further and wherein the anti-reflective film layer (6) is SiO ₂ and Nb ₂ An optical filter for a plasma display panel having an electromagnetic radiation prevention and light filtering function comprising O ₅ , or at least two layers of SiO ₂ and TiO ₂ . Article according to any one of the preceding claims, wherein the glass substrate (1) further comprising an anti-reflection film layer 6 is coated on the other side, and the anti-reflection film layer (6) is SiO _2, and An optical filter for a plasma display panel having an electromagnetic radiation prevention and light filtering function comprising Nb ₂ O ₅ or at least two layers of SiO ₂ and TiO ₂ . 4. The oxidation / corrosion resistant plastic film layer 4 combined with the coating 2 of the glass substrate 1 is a bonding agent and is released by the display. A blue dye is added to adjust and reduce yellow light having a wavelength of nm, and the substrate 1 is for a plasma display panel having an electromagnetic radiation prevention and light filtering function bonded to another substrate to form the optical filter. Optical filter. The light filter according to any one of claims 1 to 3, wherein the optical filter is bonded directly to the plasma display panel by a plastic film layer 4 serving as a bonding agent, and dyes and purples for adjusting color temperature and transmittance An optical filter for a plasma display panel having an electromagnetic radiation prevention and light filtering function in which a light absorbent is added to a bonding agent. The light filter according to any one of claims 1 to 3, wherein the coating (2) has a surface resistance of 1.5 Pa · cm 2 or less. The plasma display panel according to any one of claims 1 to 3, wherein the glass substrate 1 of the optical filter is a cured glass or semi-hardened glass chemically or physically processed. Optical filter. The transmittance at the viewer side of the optical filter is 30% to 70% in visible light with a wavelength of 380 to 780 nm, and 18% in infrared light with a wavelength of 850 nm. An optical filter for plasma display panel having an electromagnetic radiation prevention and light filtering function of less than 10% in infrared light having a wavelength of 950 nm. The method according to claim 7, wherein the reflectivity of the surface of the glass substrate 1 without the anti-reflective film layer 6 is less than 6% in visible light having a wavelength of 380 to 780 nm. Optical filter for plasma display panels which have. 8. The electromagnetic radiation prevention and light filtering function according to claim 7, wherein the reflectivity of the surface of the glass substrate 1 coated with the antireflection film layer 6 is less than 4% in visible light having a wavelength of 380 to 780 nm. An optical filter for plasma display panel having a.

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