RU2172504C1 - Optical filter for indicator panel - Google Patents

Abstract

FIELD: indication equipment. SUBSTANCE: invention is related to optical filters used in indicator panels and mounted in front of them to trap electromagnetic waves and cut-off beams of near-infrared spectrum emitted by indicator panel. Optical filter includes filter base and clear conducting film with resistance not more than 3.0 Ohm/sq.cm composed of thin silver films and zinc oxide films which alternate to form multilayer film. Clear film is connected to grounding element manufactured from conducting paste. Technical result of invention lies in transmission by optical filter of visible beams and in entrapment of electromagnetic waves with frequency 30-130 MHz and beams of near-infrared spectrum with wave length 800-1000 nm. EFFECT: low cost, reduced weight and thickness and improved contrast range of filter. 17 cl, 8 dwg

Description

 The present invention relates to an optical filter for an indicator panel (hereinafter referred to simply as an “optical filter”), which is mounted in front of the indicator panel (visual information reproduction panel) to pick up electromagnetic waves emitted by the indicator panel and to cut off the near infrared rays emitted by the same indicator panel.

State of the art
As a display panel used as an image reproducing apparatus, a gas discharge display panel such as a plasma display panel (PIP) is used.

 The PIP is designed so that during an electric discharge between the electrodes, the gas molecules located in the sealed panel are excited, and more specifically, the xenon molecules are mixed, which is mixed with neon to simplify the excitation of the xenon molecules, thus causing the excitation of the fluorescent substance deposited on the internal the surface of the panel, under the influence of ultraviolet radiation, which is accompanied by the emission of visible radiation to reproduce the image, but on the other hand Oron, maintaining the current flowing through the electrodes, generates a magnetic field which causes mainly in the PDP generates electromagnetic waves with a frequency of 30 MHz or less than -130, which are emitted outside the PDP.

 Further, when excited, xenon also generates near-infrared rays in addition to ultraviolet radiation, and since the wavelength corresponding to near-infrared radiation is approximately the central wavelength, approximately 900 nm, of the emission spectrum of the light emitting diode (hereinafter, simply LED), then there is a likelihood of a malfunction in the means of remote control or optical communications due to the influence of the near-infrared rays emitted from the PIP when such equipment operates in near PIP.

 For this reason, to capture ("capture") the electromagnetic waves emitted from the PIP and to cut off the rays of the near infrared spectrum emitted by the PIP, an optical filter is installed in front of the PIP. Such leakage of electromagnetic radiation within a predetermined frequency range is prevented by, for example, forming a layer of a mesh conductor that traps electromagnetic waves on the surface of a filter base made of a synthetic polymer such as polyacrylate.

 In this case, not only the width and pitch of the mesh conductor are determined, but, in addition, the direction of the grid is set diagonally, so that image light emerging from the PIP is not captured. In addition, to cut off near infrared radiation, a layer of glass that absorbs infrared radiation or a filter based on plastic based on infrared radiation is used.

 An optical filter, such as one of the above, is a combination of layers for capturing electromagnetic waves and layers for cutting off near infrared radiation, which are manufactured separately, which poses a problem associated with the high cost of manufacturing such a filter.

 In addition, it is inevitable that the image light is distorted by a layer of a mesh conductor that traps electromagnetic radiation, causing dimming and deterioration of the picture quality (due to the appearance of Newton's rings or blurriness of the image).

 Moreover, an optical filter having a filter base made of a synthetic polymer such as polyacrylate has the problem that the optical filter has a tendency to local deformation due to the heat generated by the indicator panel when it is used to visually reproduce information , this adversely affects the quality of the reproduced picture. In particular, it is known that since the PIP generates heat resulting from an electric discharge to reproduce the image, a large PIP display with a gap between the optical filter and the PIP (for example, a 24-inch (61 cm) PIP display), local deformation or distortion of the optical filter due to the heat associated with the electric discharge in the PIP adversely affects the quality of the reproduced image.

 In addition, if an Ag film is formed by spraying as a transparent conductive film for capturing electromagnetic waves and cutting off near infrared radiation based on a filter, there is a problem that the atomized silver film is susceptible to corrosion due to the presence of water vapor and other similar substances in the air when its surface is open to air.

 The present invention was made in view of the problems described above and its purpose is to obtain an optical filter for a low cost display panel capable of transmitting image light (visible rays) outward from the display panel (e.g., PIP), capturing electromagnetic waves in the frequency range 30 - 130 MHz coming out of the indicator panel, and cutting off the near infrared radiation emitted by the indicator panel with wavelengths of 800 - 1000 nm.

 An additional object of the present invention is to reduce the weight and thickness of the optical filter, so that the optical filter does not undergo local deformations due to the heat generated from the display panel in order to prevent corrosion of the transparent conductive film (especially silver film) made on a transparent basis, under the influence of water vapor contained in air to prevent a decrease in contrast due to deviation (refraction) of external light in order to adjust the colors generated by panel to prevent the appearance of Newton’s rings (the appearance of alternating bright and dark concentric rings), to prevent the glass base used as a transparent base from being scattered into pieces, if it breaks, so that the created structure can easily be installed on the display panel, etc.

Disclosure of Invention
The optical filter according to the present invention is an optical filter that is located in front of the display panel and contains a filter base and a transparent conductive film for capturing electromagnetic waves and cutting off near infrared radiation, while the transparent conductive film is formed of thin silver films and thin films of zinc oxide, in layers alternating so that visible rays are transmitted, but electromagnetic waves are captured in the frequency range 30 - 130 MHz and the rays are cut off the lower infrared spectrum within the wavelength range of 800 - 1000 nm.

 A transparent conductive film allows visible rays to exit the display panel and propagate, but it picks up electromagnetic waves coming out of the display panel and cuts off the near-infrared rays emitted by the panel. Moreover, when the transparent conductive film is made in the form of a multilayer film formed by layer-by-layer alternation of thin silver films and thin films of zinc oxide, the cost of manufacturing it can be made lower than the cost of a transparent film known from the prior art, which is made by combining separately made layers that capture electromagnetic waves, and layers that cut off near infrared radiation.

When a transparent conductive film is formed from layer-by-layer alternating thin silver films and thin zinc oxide films, its transmittance for image light (visible rays) emerging from the display panel can be set above a predetermined value (for example, 60%), and by setting the surface resistance of the transparent conductive films of 3 Ohm / cm ³ (3 Ohm per 1 square cm) or less, not only the capture effect (attenuation effect) of electromagnetic waves in the frequency range 30 - 130 MHz can be set higher than the specified about the value (for example, 10 decibels), but also the transmittance of the near-infrared rays having a wavelength in the range of 800 - 1000 nm can be set below the set value (for example, 10%).

 An electromagnetic wave can be effectively captured by using the grounding of a transparent conductive film through a grounding electrode connected to it, to discharge (drain) an electric charge induced in a transparent conductive film.

 The weight and thickness of the optical filter can be reduced by making a synthetic polymer filter backbone.

 The manufacturing process of a transparent conductive film based on a synthetic polymer can be simplified by attaching a transparent film to a base of a synthetic polymer after securely attaching a film that captures electromagnetic waves and a film that cuts off near infrared radiation on the surface of the transparent film.

 Local deformation or distortion of the optical filter caused by the heat generated by the display panel can be eliminated by using the glass base of the filter, thereby also deteriorating the quality of the reproduced image.

 Through the use of a reinforced glass filter backing, a reduction in the thickness of the filter backing and the optical filter itself can be obtained.

 When the base of the filter is glass or reinforced glass, it can be processed more easily by performing a bevel (oblique sharpening) of the angle formed between its surface and its side surface.

 White balance can be more easily maintained with a color (tinted) film so that the colors obtained on the display panel can be adjusted.

 The color film for adjusting the colors obtained on the display panel is firmly attached to the surface of the filter base and its edges are chamfered so that they exactly extend the beveled corner of the filter so that the color film does not tear off during processing of the filter base.

 The anti-reflection film, to prevent reflection of external light by the surface of the color film, is performed on the surface of the color film so that the color film performs the function of adjusting the colors obtained on the display panel and the function of preventing a decrease in contrast due to reflection of external light.

 To protect the transparent conductive film (especially a thin silver film) from corrosion by the action of water vapor contained in air, a film may be made which is a moisture resistant film covering the exposed surface of the transparent conductive film.

 Deterioration of contrast due to reflection of external light or image light can be prevented by applying an anti-reflection film.

Brief Description of the Drawings
FIG. 1 is a schematic diagram illustrating an optical filter according to a first embodiment of the present invention installed in a PIP display.

 FIG. 2 is an enlarged view of the optical filter shown in FIG. 1.

 FIG. 3 is an enlarged view of a portion of the circuit shown in FIG. 1, and also on an enlarged scale, is part of a first enlarged image.

 FIG. 4 is an enlarged sectional view of the main part of the transparent conductive film shown in FIG. 2.

 FIG. 5 shows transmission characteristics of visible and near infrared rays for a transparent conductive film in the case shown in FIG. 1 - FIG. 4.

 FIG. 6 is a diagram illustrating an optical filter for a display panel according to a second embodiment of the present invention installed in a PIP display.

 FIG. 7 is a part of the circuit of FIG. 6 is an enlarged view.

 FIG. 8 is a partial zoomed-in image representing an optical filter for a display panel according to a third embodiment of the present invention installed in a PIP display.

BEST MODES FOR CARRYING OUT THE INVENTION
The present invention will be described in detail with reference to the accompanying drawings.

 First, with reference to FIG. 1 - FIG. 5, an optical filter for a display panel according to a first embodiment of the present invention will be described.

 In FIG. Figure 1 shows an example of an optical filter used in a display with a small PIP (for example, a 21-inch display (53.34 cm) with a PIP). Position 1 denotes the PIP, position 2 - the optical filter PIP (hereinafter referred to simply as the "optical filter"), 3 - the front of the casing and 4 - the back of the casing. One side of the fixing metal element 7 is adjacent to the peripheral part of the optical filter 2, and the other side of the fixing metal element 7 is firmly attached to the locking stop 5 with a screw 6, so that the optical filter 2 is fixedly attached to the front part 3 of the casing. PIP 1 is fixedly attached to the rear part 4 of the casing with a screw 9 through the locking stop 8, and the rear part 4 of the casing is fixedly attached to the front part 3 of the casing, due to which the peripheral part of the PIP 1 rests on the fixing metal element 7 so that the fixing metal element 7 comes into contact with the peripheral part of the optical filter 2 with a clamp.

 As shown in FIG. 2 and FIG. 3, the optical filter 2 contains a filter base 11 made of a colored base of a synthetic polymer, a transparent conductive film, which is a sprayed film 12, attached to one surface (surface from the PIP side 1) of the filter base 11 with a binder (or glue) (hereinafter also applied), AO film (antireflection film) 13, attached to another surface of the filter base 11 with a binder, AN film (“against Newton’s rings”) 14, attached to the surface of a transparent conductive film, which 12 is a sprayed film by a binder and a ground electrode 15 made by the method of printing a metal conductor within the outer region AH film corresponding to the peripheral region of the transparent conductive film, which is sprayed film 12.

 The filter base 11 is made of a colorless transparent synthetic polymer having sufficient impact resistance, such as polyacrylate or polycarbonate mixed with pigment, which is a selective filter capable of absorbing the red component to adjust the colors created by PIP 1 by absorbing the red component, which with low intensity, it appears along with the blue color generated by the fluorescent base used to generate the blue color. More specifically, (filter base 11) is made in the form of a substrate having a specific thickness (for example, 2 mm thick) of polyacrylate or polycarbonate mixed with a particular pigment by melting.

), обеспечивающую поверхностное сопротивление примерно 2.7 Ом/см² (2.7 Ом на 1 квадратный см), с прозрачной ПЭТ (полиэтилен терфталат) пленкой 12a и многослойной пленкой, содержащей тонкие пленки 12b серебра (Ag) и тонкие пленки оксида цинка (ZnO), нанесенные путем напыления, которые послойно чередуются на одной поверхности прозрачной ПЭТ пленки так, что тонкая пленка 12c оксида цинка образует самый наружный слой. В этом случае, чем больше число слоев тонких пленок 12b серебра и тонких пленок 12c оксида цинка, тем меньше поверхностное сопротивление, что вызывает увеличение величины улавливаемого электромагнитного излучения и уменьшение пропускания видимых лучей, но в то же время, чем меньше число слоев тонких пленок 12b серебра и пленок 12c оксида цинка, тем больше пропускание видимых лучей, но больше поверхностное сопротивление, которое приводит к уменьшению величины улавливаемого электромагнитного излучения. По этой причине поверхностное сопротивление устанавливается примерно 2.7 Ом/см² для того, чтобы улавливать электромагнитные волны на таком уровне, который требуется в соответствии со стандартом безопасности, но и сохранять пропускание для видимых лучей на заданном уровне (например, 60%) или более.As shown in FIG. 4, the transparent conductive film being the sprayed film 12 is configured to have a thickness (e.g., about 100

), providing a surface resistance of approximately 2.7 Ohm / cm ² (2.7 Ohms per square cm), with a transparent PET (polyethylene terphthalate) film 12a and a multilayer film containing thin films of silver (Ag) 12b and thin films of zinc oxide (ZnO), applied by spraying, which alternate layer by layer on the same surface of a transparent PET film so that a thin film of zinc oxide 12c forms the outermost layer. In this case, the larger the number of layers of silver thin films 12b and zinc oxide thin films 12c, the lower the surface resistance, which causes an increase in the amount of absorbed electromagnetic radiation and a decrease in the transmission of visible rays, but at the same time, the smaller the number of layers of thin films 12b silver and zinc oxide films 12c, the greater the transmission of visible rays, but the greater the surface resistance, which leads to a decrease in the amount of trapped electromagnetic radiation. For this reason, the surface resistance is set to approximately 2.7 Ohm / cm ² in order to pick up electromagnetic waves at a level that is required in accordance with the safety standard, but also to keep the transmission for visible beams at a given level (for example, 60%) or more.

 AO film 13 is designed to prevent reflection of external light and contains, for example, a transparent film whose surface is coated with vapor deposited materials that have different refractive indices, or a transparent film whose surface is coated with a fluorine-containing polymer, so that external light such like incident light, it is refracted in a complex way in order to prevent its reflection to the greatest extent possible, to prevent the deterioration of contrast.

 As shown in FIG. 3, in an enlarged diagram, the AN film 14 is formed using a colorless transparent film having small irregularities on one of its surfaces (surface from the PIP 1 side), so that the optical film does not come into close contact with the surface of the PIP 1 due to surface irregularities, such Thus, an obstacle arises for the appearance of Newton's rings (the appearance of bright and dark concentric circles) when the optical filter is in contact with PIP 1.

 The surface of the locking stop 5, the inner surface of the front part 3 of the casing, the inner surface of the rear part 4 of the casing, the surface of the locking stop 8 and others are made with a conductive film 20, so that the transparent conductive film 12 of the optical filter 2 is connected to a metal element (grounding element) 1a installed behind the PIP 1, through the grounding electrode 15, the fixing metal element 7 and the conductive film 20, so that the electric charge induced in the transparent conductive discharge to the earth film 12 by electromagnetic waves, emitted by "body" 1b PDP 1.

 As shown in FIG. 1 and FIG. 3, when the optical filter 2 is placed on the front surface of the PIP 1, the image light (visible rays) exiting the PIP 1 passes through the optical filter 2, and the electromagnetic waves “flowing” from the PIP 1 are captured by the optical filter 2, and the rays of the near the infrared spectrum emitted by PIP 2 is cut off by the optical filter 2. In accordance with the experimental results, the amount of electromagnetic radiation captured (attenuation value) by the optical filter is 10 dB (dB μV / m) or more, for the frequency range 30 - 130 MHz. Therefore, when the inherent ability of PIP 1 to capture electromagnetic waves is combined with the possibility of an optical filter, the available ability to pick up electromagnetic waves is large enough to reach the acceptable levels of electromagnetic leakage established by the Law on the Control of Electrical Equipment, CLC (Public Governing Council for Intervention in the affairs of the Department of Electronic Technology and Information Processing Tools (Japan), the FCC (Federal Communications Committee), the EU ( European standards) and others. The transmission characteristic for visible and near infrared rays is shown in FIG. 5. More specifically, the transmittance of visible rays, the wavelength of which is in the range of 400 - 700 nm, is 60%; about 10% (i.e. 90% is cut off) for near-infrared rays with a wavelength of 800 nm; about 10% - 4% (i.e., 90% - 96% is cut off) for the near-infrared rays whose wavelength is in the range of 800 - 850 nm; about 4% (i.e., 96% or more is cut off) for near infrared rays having a wavelength of 850 nm or more. Thus, the influence of infrared rays on the operation of infrared remote control means or optical communication means can be prevented.

 Further, the sprayed film 12, like a transparent conductive film, has a multilayer structure consisting of thin silver films 12b and thin films of zinc oxide 12c alternating in layers, while the small particles of zinc oxide in the thin film 12c diffusely reflect the light incident from the front and the thin silver the film serves as a regular reflector (mirror), thus preventing reflection of the background image.

 That is, when only a thin silver film 12b is used, it is possible to reflect the background image, since the thin silver film 12b acts as a regular reflector, and this (i.e., reflection of the background image) is prevented by the thin film of zinc oxide 12c.

) определяются исходя из того, что требуется получить поверхностное сопротивление примерно 2.7 Ом/см², но настоящее изобретение не ограничивается этим вариантом; например, даже когда число слоев тонких серебряных пленок 12b и тонких пленок 12c оксида серебра и толщина пленок (например, несколько сотен

) определяются исходя из того, что требуется получить поверхностное сопротивление примерно 3.0 Ом/см² или менее, то электромагнитные волны в частотном диапазоне 30 - 130 МГц могут ослабляться на 10 дБ или более, и коэффициент пропускания света изображения (видимых лучей), длина волны которых в пределах 400 - 700 нм, может регулироваться до уровня примерно 60%, а коэффициент пропускания лучей ближнего инфракрасного излучения, длина волны которых в пределах 800 - 1000 нм, может регулироваться до уровня 10% или менее (отсекается 90% или более), так же как в случае вышеописанного варианта. Когда поверхностное сопротивление превышает 3.0 Ом/см², характеристики по улавливанию и отсеканию излучения ухудшаются, но все еще не только электромагнитные волны, имеющие частоту в пределах 30 - 130 МГц, могут улавливаться, но также могут отсекаться и лучи ближнего инфракрасного излучения, имеющие длину волны 800 - 1000 нм.In the above embodiment, for the sprayed film 12, which is a transparent conductive film, the number of layers of thin silver films 12b and thin films of silver oxide 12c (for example 3 layers of thin films 12b and 3 layers of thin films 12c) and film thickness (for example, about 100

) are determined on the basis that it is required to obtain a surface resistance of about 2.7 Ohm / cm ² , but the present invention is not limited to this option; for example, even when the number of layers of thin silver films 12b and thin films of silver oxide 12c and film thickness (for example, several hundred

) are determined on the basis of the fact that it is required to obtain a surface resistance of about 3.0 Ohm / cm ² or less, then electromagnetic waves in the frequency range 30 - 130 MHz can be attenuated by 10 dB or more, and the transmittance of light of the image (visible rays), wavelength which within 400 - 700 nm can be adjusted to a level of about 60%, and the transmittance of near infrared rays, whose wavelength is within 800 - 1000 nm, can be adjusted to a level of 10% or less (cut off 90% or more), same as with of the above option. When the surface resistance exceeds 3.0 Ohm / cm ² , the characteristics of the capture and clipping of radiation deteriorate, but still not only electromagnetic waves having a frequency in the range of 30 - 130 MHz can be trapped, but also near-infrared rays having a length of Waves 800 - 1000 nm.

 In the above embodiment, the ground electrode is configured so that a portion of the transparent electrode film of the transparent conductive film 12 is connected to it to provide grounding, so that an electric charge induced in the transparent electrode film of the transparent conductive film 12 can drain to the ground, but the present invention does not limited to this option; for example, this option is also applicable for the case when this part of the transparent conductive film 12 is not grounded due to the lack of a grounding electrode.

 In the above embodiment, a transparent conductive film, like the sprayed film 12, is first formed into a multilayer film containing thin silver films 12b and thin films of zinc oxide 12c alternating in layers, this film is made on one side of the PET film 12a, and then the PET film 12a is attached to the surface of the filter base 11 to simplify the process of providing a transparent conductive film to the filter base 11, but the present invention is not limited to this embodiment; for example, a multilayer film, with layer-by-layer alternation of thin silver films 12b and thin films of zinc oxide 12c, can be formed as a transparent conductive film directly on the basis of the filter 11, without a PET film 12a.

 In the above-described embodiment, AO film 13 is made to prevent reflection of external light, which causes a decrease in contrast, but the present invention is not limited to this option; for example, the present invention is also applicable for the case when the AO film is absent.

 In the above embodiment, the AN film is made to prevent the appearance of Newton's rings (the occurrence of bright and dark concentric circles), but the present invention is not limited to this option; for example, the present application is also applicable in the case where an AN film is absent.

 In the above embodiment, the filter base is made of a colored (dyed) synthetic polymer, but the present invention is not limited to this option; for example, the present invention is also applicable in the case where the filter base is made only of a transparent synthetic polymer. Moreover, the present invention is applicable for the case when the filter base is made of a transparent synthetic polymer combined with a color filter designed to adjust the color generated by the PIP 1.

 Next, with reference to FIG. 6 and FIG. 7, a second embodiment of the present invention will be described.

 In FIG. 6 and FIG. 7 structural elements identical with those shown in FIG. 1 and FIG. 3 are denoted by the same reference numerals and symbols in order to avoid re-describing them. In FIG. Figure 6 shows an example of a large PIP device (for example, a 42-inch (107 cm) PIP device) with an optical filter included. In FIG. 6 position 1 indicates PIP; 2A — optical filter (hereinafter referred to simply as “optical filter”); 3A - front of the casing; 4A - back of the casing. The peripheral part of the optical filter 2A from the PIP 1 is in close contact (pressed) with the elastic part of the fixing spring 21, the closest part of the fixing spring 21 to the attachment point is securely fixed to the conductive stop 23 with a nut 22, and the conductive stop 23 is made protruding inward front of the casing 3A. PIP 1 is fixedly attached to the rear part 4A of the casing with screws through the locking stop 8 in order to provide clearance for the optical filter.

 As shown in FIG. 7, the optical filter 2A comprises a filter base 11A made of reinforced glass, a transparent conductive film 12A, and an electrode 24 fixedly mounted on one surface (surface on the PIP side 1) of the filter base 11A, a reflection-resistant film 26 (anti-reflection film), is firmly attached using a transparent binder 25 to the upper surface of the transparent conductive film 12A and the upper surface of the electrode 24, and a color film 28, anti-reflection, firmly attached using a binder 27 to another surface of the filter base 11.

The filter base 11A is made of a reinforced glass plate with a thickness of about 3 mm (e.g., 3.2 mm thick), which is first heated to about 600 ^° C and then cooled by an air stream to increase durability and is suitable as an economical and relatively light weight optical filter base . For filter base 11A, there is no restriction that it must necessarily be manufactured using an air flow cooling process; it can be made of chemically reinforced glass and its thickness is not limited to a mandatory thickness of about 3 mm.

 The corners of the filter base 11A, which are formed between its wider surface and the side surface, are chamfered to form chamfered surfaces 11Aa and 11Aa. These beveled surfaces prevent damage to the base 11A when it interacts with other objects during processing.

) такая, что может быть получено поверхностное сопротивление примерно 2.6 Ом/см². Когда поверхностное сопротивление устанавливается примерно 2.6 Ом/см², величина электромагнитного излучения, выходящего наружу из ПИП 1, может быть ослаблена до уровня, равного или ниже чем уровень, требующийся в соответствии с правилами безопасности или др., но при этом поддерживается требующийся коэффициент пропускания (например, 60%) для видимых лучей, как и в случае первого варианта изобретения.The electrode 24 is made by printing a conductive metal (for example, from a conductive paste) onto the peripheral part of one surface of the filter substrate 11A, and a transparent conductive film 12A is formed by the spraying method, covering almost all of this surface of the filter substrate 11A, except for its peripheral parts, so that the area covered by spraying captures the inner peripheral part of the electrode 24 in order to provide an electrical connection with it. The transparent conductive film 12A is made in a similar manner to the sprayed film 12, which is the transparent conductive film in the first embodiment of the invention. However, unlike the first embodiment, in which the transparent conductive film is made on PET film 12a, thin silver films 12b and thin films of zinc oxide 12c are formed by spraying directly onto one surface of the filter substrate 11A in the form of a multilayer film consisting of thin silver films 12b and zinc oxide thin films 12c, which alternate layer by layer, as shown in FIG. 4, so that a thin film of zinc oxide is the upper layer and the film thickness (for example, about 100

) such that a surface resistance of about 2.6 Ohm / cm ² can be obtained. When the surface resistance is set to approximately 2.6 Ohm / cm ² , the amount of electromagnetic radiation emerging from the PIP 1 can be attenuated to a level equal to or lower than the level required in accordance with safety rules or others, but the required transmittance is maintained (for example, 60%) for visible rays, as in the case of the first embodiment of the invention.

 The reflection preventing film 26 is an optical thin film consisting of a plurality of films made on the surface of a transparent film by evaporation in a vacuum using materials having different refractive indices, or is an optical thin film containing a transparent film and a fluorine deposited thereon -polymer film, which is designed to prevent reflection of reproduced light from PIP 1 or external light.

 The reflection-preventing color film 28 contains a fluorine-based film including pigment additives acting as coloring agents for adjusting the colors generated by the PIP 1 and an optical thin film deposited thereon similar to the “antireflection” film 26 in order to prevent light reflection. The peripheral part of the color antireflection film 28 is beveled so that the beveled surface exactly extends one of the beveled faces 11Aa of the HA filter base so that the film cannot be peeled off during processing.

 As shown in FIG. 6, a conductive film 20 is deposited on the inner surface of the front part 3A of the casing, the inner surface of the rear part 4A of the casing, the surface of the locking stop 8, etc., whereby the transparent conductive film 12A of the optical filter 2A is connected to the metal part 1a (grounding part) on the back side PIP 1 through the ground electrode 24, the fixing spring 21, the nut 22, the conductive stop 23 and the conductive film 20, to discharge to the ground an electric charge induced in a transparent conductive film 12A under the action of electromagnetic x waves emitted by the body 1b PIP 1.

 Then, as shown in FIG. 6 and FIG. 7, when the optical filter 2A is installed in front of the PIP 1, the image light leaving the PIP 1 passes through the optical filter 2A and the electromagnetic waves emitted by the PIP 1 are captured by the optical filter 2A, and the near-infrared rays emitted from the PIP 1 are cut off by the optical filter 2A. According to the results of the experiment, the magnitude of the capture (attenuation) of electromagnetic waves is 10 dB or more (dB μV / m) in the frequency range 30 - 130 MHz. Thus, when the inherent ability of PIP 1 to capture electromagnetic waves is combined with the possibility of an optical filter, the available ability to capture electromagnetic waves is large enough to achieve acceptable levels of leakage of electromagnetic radiation established by the Law on the Control of Electrical Equipment, CLC (Public Governing Council for Interventions in the affairs of the Department of Electronic Technology and Information Processing Tools (Japan), FCC (Federal Communications Committee i), the EU (European Standards), etc. In addition, with regard to visible and near-infrared rays, an optical filter transmits visible rays having a wavelength in the range of 400 - 700 nm, about 60% and passes about 10% ( catching 90% or more) or less of near-infrared radiation, the wavelength of which is 800 - 1000 nm. Thus, the influence of the PIP on the operation of infrared remote control devices or optical communication means installed near the PIP can be prevented.

 Further, the filter base 11A is made of reinforced glass, so that when the optical filter 2A is installed in front of the PIP 1, it does not bend or deform the filter base 11A associated with it due to the heat generated during the operation of the PIP, and therefore may deterioration in the quality of the reproduced picture is prevented.

 Further, the filter base 11A is made of reinforced glass and, therefore, its thickness may be less than the thickness of the filter base made of ordinary glass.

 In addition, by using the antireflection film 26 and the antireflection color film 28 deposited on both surfaces of the filter base 11A, the reflection of the light coming out of the PIP 1 and external light is prevented, respectively, thereby preventing a deterioration in contrast and correcting the colors generated by the PIP 1 , to ensure that white balance is maintained in an easier way, and the spread of broken pieces of PIP 1 is prevented if the PIP is broken.

 Next, with reference to FIG. 8, a third embodiment of the invention will be described. In FIG. 8 for elements such as those shown in FIG. 6 and FIG. 7, the same numeric positions and symbols are used so as to avoid duplication of their description. In FIG. 8 shows an example of a large PIP with an optical filter. In FIG. 8 numeral 1 indicates PIP; 2B is an optical filter for PIP (hereinafter referred to simply as “optical filter”); 3A is the front of the casing. The elastic part of the fixing spring 21 exerts pressure on the peripheral part of the optical filter 2B from the PIP 1. The proximal end part of the fixing spring 21 is attached to the conductive stop 23 with a nut 22, and the conductive stop 23 protrudes inside the front part 3A of the casing, as a result of which the optical filter 2B is fixedly attached to the front of the casing 3A. A gap is formed between the PIP 1 and the optical filter 2B.

 The optical filter 2B comprises a filter base 11B, a transparent conductive film 12A, and an electrode 24 that are firmly attached to the same surface (from the PIP side 1) of the filter base 2B, the transparent moisture resistant film 31 being firmly attached using a transparent binder 25 on the upper surface of the transparent conductive film 12A and the upper surface of the electrode 24, antireflection film 26 is attached to the upper surface of the moisture-resistant film 31 using a transparent binder (not shown), moisture-proof sealing element nt 32 and antireflection film 28 is color firmly attached to another surface enhanced bases 2B filter using a transparent adhesive 27.

 The filter base 11B has bevels 11Ba and 11Ba, which are similar to bevels in the second embodiment of the invention, and the peripheral part of the antireflection color film 28 also has a bevel 28a, made as an exact continuation of one of the bevels 11Ba. The moisture resistant film 31 is made of a transparent, air-tight film, for example, such as a PET film, and it not only covers the surface of the transparent conductive film 12A, but also “overlaps” the inner peripheral region of the ground electrode 24 corresponding to the periphery of the transparent conductive film 12A.

 The peripheral parts of the transparent binder 25 and the edge along the boundary between the moisture-proof film 31 and the transparent binder 25 are sealed with a sealing element 32, which protects the transparent conductive film 12A (especially a thin silver film) from corrosion by water vapor contained in the surrounding in the air.

 The inner surface of the front part 3A of the casing, the inner surface of the rear part 4A of the casing (not shown in FIG. 8) and the surface of the locking stop 8 (not shown in FIG. 8) are provided with a conductive film 20 deposited by the process of forming the conductive film, thereby making it transparent the conductive film 12A of the optical filter 2B is connected to the metal part (for grounding) 1a (not shown) of the back of the PIP 1 through the grounding electrode 24, the fixing spring 21, the nut 22, the conductive stop 23 and the conductive film 20, for discharge ) To the ground the electric charge induced in the transparent conductive film 12A by electromagnetic waves emitted from PDP 1.

 Then, as shown in FIG. 8, when the optical filter 2B is installed in front of the PIP 1, the image light leaving the PIP 1 is transmitted by the optical filter 2B, and the electromagnetic waves emitted from the PIP 1 are captured by the optical filter 2B, while the near-infrared rays emitted from the PIP 1, also cut off by an optical filter 2B. According to the results of the experiment, as in the case of the second embodiment of the invention, the magnitude of the capture (attenuation) of electromagnetic waves by an optical filter 2B is 10 dB or more (dB μV / m) in the frequency range 30 - 130 MHz. Thus, when the inherent ability of the PIP 1 to capture electromagnetic waves is combined with the possibility of an optical filter, the available ability to capture electromagnetic waves turns out to be large enough to reach the limit of the level of leakage of electromagnetic radiation required in accordance with the Law on the Control of Electrical Equipment, OSA, FKS , EC, etc. In addition, with regard to visible and near infrared rays, as in the case of the first embodiment of the invention shown in FIG. 5, the transmittance of visible rays having a wavelength in the range of 400 to 700 nm is about 60%, and the transmittance of the near infrared spectrum having a wavelength of 800 to 1000 nm is about 10% or less (90% or more is captured ) Thus, the effect on the operation of nearby infrared remote control devices or optical communication means can be prevented.

 Further, all surfaces of the transparent conductive film 12A are coated with a moisture-resistant film 31 so that, by providing sealing by the sealing member 32, the transparent conductive film 12A (especially the thin silver film) is not corroded by water vapor contained in the ambient air.

 Further, since the filter base 11B is made of glass, the filter base 11B installed in front of the PIP 1 will not be distorted due to the heat generated by the PIP 1 for reproducing the image, thus, deterioration in the quality of the reproduced image due to local distortions (deformations) of the optical filter.

 Further, the antireflection film 26 and the antireflection color film 28, which are applied to both surfaces of the filter base 11B, respectively prevent reflection of the light of the image generated by the PIP 1 and external light, thereby preventing a deterioration in contrast and adjusting the colors generated by the PIP 1 for more maintaining white balance easily, while also breaking apart broken pieces of the filter base 11B is prevented if it breaks.

 The second and third embodiments of the invention affect cases where a gap is provided between the optical filter 2A and the PIP 1, as well as the optical filter 2B and the PIP 1, but the present invention is not limited to these options; for example, the invention is also applicable for cases where there is no gap between the optical filter 2A and the PIP 1, as well as between the optical filter 2B and the PIP 1, as in the case of the first embodiment. In addition, the invention is applicable for the case when an AN film, similar to that which is in the first embodiment, is applied to the surface of the optical filter 2A, as well as to the surface of the optical filter 2B, from the PIP 1.

 In the above embodiment, a case is considered where the indicator panel is a PIP, but the present invention is not limited to such a case, it is also applicable to indicator panels from which electromagnetic waves or near infrared rays are not necessarily emitted.

Industrial applicability
As described above, the optical filter for the display panel according to the present invention is suitable for installing it in front of the display panel (for example, PIP) of the display, so that the light of the reproduced image (visible rays) coming out of the display panel can pass, and electromagnetic waves emitted from the indicator panels were captured, and the level of electromagnetic wave radiation was reduced to the required limit level of radiation leakage or lower, which is set by the instructions for information processing tools and ., As well as to prevent a negative impact on the work near a remote control means or means of communication, because the emitted from the display panel near-infrared rays.

Claims (18)

1. An optical filter for a plasma display panel, comprising a filter base and a transparent conductive film for capturing electromagnetic waves and for cutting off the rays of the near infrared spectrum, in which said transparent conductive film is capable of transmitting visible rays, but picking up electromagnetic waves having a frequency of 30 - 130 MHz and cut off the rays of the near infrared spectrum having a wavelength of 800 - 1000 nm, while said transparent film contains thin silver films and thin films of zinc oxide, which layer by layer alternate to form a multilayer film, and the surface resistance of the transparent conductive film is set to 3 Ohm / cm ² or less, and the transparent conductive film is connected to a ground electrode made of conductive paste.  2. The optical filter for the plasma display panel according to claim 1, in which the filter base is made of synthetic polymer.  3. The optical filter for the plasma display panel according to claim 2, in which a transparent film having transparent conductive films for capturing electromagnetic waves and cutting off the rays of the near infrared spectrum, firmly attached to its surface, is attached to the surface of the base of a synthetic polymer.  4. The optical filter for the plasma display panel according to claim 3, in which the base of the synthetic polymer is a color base of synthetic polymer made of a transparent synthetic polymer mixed with pigment to adjust the colors generated by the display panel.  5. The optical filter for the plasma display panel according to claim 4, which contains a film against Newton's rings to prevent the appearance of Newton's rings.  6. The optical filter for the plasma display panel according to claim 1, in which the filter base is made of glass.  7. The optical filter for the plasma display panel according to claim 1, in which the filter base is made of reinforced glass.  8. The optical filter for the plasma display panel according to claim 7, which contains a film that prevents Newton's rings, to prevent the appearance of Newton's rings.  9. The optical filter for the plasma display panel according to claim 7, in which the corners of the filter base, each of which is formed between its wider surface and the side surface, are beveled.  10. The optical filter for the display panel according to claim 7, in which to adjust the colors generated by the display panel, a color film is provided.  11. The optical filter for the plasma display panel according to claim 9, in which the color film to adjust the colors generated by the display panel is firmly attached to the surface of the filter base, and the peripheral part of the color film is beveled to accurately continue the bevel of the filter base.  12. The optical filter for the plasma display panel of claim 10 or 11, wherein an antireflection film is provided on the surface of the color film to prevent reflection of external light.  13. The optical filter for the plasma display panel of claim 12, wherein a film for preventing Newton's rings is provided to prevent the appearance of Newton rings.  14. The optical filter for the plasma display panel according to claim 7, wherein a moisture resistant film is provided to cover the exposed surface of the transparent conductive film.  15. An optical filter for a plasma display panel according to one of claims 9, 10 or 11, in which a moisture-resistant film is provided to cover the open surface of a transparent conductive film.  16. The optical filter for the plasma display panel of claim 12, wherein a moisture resistant film is provided to cover the exposed surface of the transparent conductive film.  17. The optical filter for the plasma display panel according to one of p. 10 or 16, in which a film for preventing Newton's rings is provided to prevent the appearance of Newton's rings.  18. The optical filter for the plasma display panel of claim 16, wherein an anti-reflection film is provided to prevent reflection of external light or image light of the display panel. Priority on points:
10/02/1997 according to claims 1, 2, 3, 5, 8, 10, 12, 13, 14, 17;
05/20/1997 (JP-129356) according to claims 4, 6, 9, 11, 15, 16, 18;
05/20/1997 (JP-129355) according to claim 7.

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