KR20010084244A - shadow mask for coler cathod ray tlbe - Google Patents

Abstract

PURPOSE: A shadow mask for color cathode ray tube is provided, in which frit glass having a low coefficient of thermal expansion is employed as an adhesive, to thereby decrease doming of shadow mask. CONSTITUTION: A shadow mask(7) includes a surface where reflector film consisting of an electron reflecting agent, thermal radiation agent, adhesive and organic substances, is attached. The reflector film is formed by using frit glass as an adhesive, wherein the frit glass has coefficient of thermal expansion of 85 x 10¬-7/°C. The frit glass has an ingredient at least one of beta-eucryptite, titanate lead, cordierite or zircon, and contained in 20 to 80 weight%.

Description

Shadow mask for color cathode ray tube {shadow mask for coler cathod ray tlbe}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shadow mask for a color cathode ray tube, and more particularly, to an improvement in the dominance reduction effect by appropriately forming a low thermal expansion frit glass when forming an electron reflection film that reflects an electron beam on the shadow mask surface.

In the color cathode ray tube, as shown in FIG. 1, a panel 1 having a fluorescent film formed on an inner surface thereof and a funnel 2 coated with conductive graphite on an inner surface thereof are fused with glass, and a neck portion 4 of the funnel 2 is formed. An electron gun 6 for generating an electron beam 5 is mounted on the inside of the panel 1, and a shadow mask 7, which is a color-selective electrode, is supported by the frame 8, and an electron beam is provided on the outer circumferential surface of the funnel. A deflection yoke 9 for deflecting from side to side is mounted.

In the cathode ray tube configured as described above, when the image signal is input to the electron gun, hot electrons are emitted from the cathode of the electron gun, and the emitted electrons are accelerated and focused toward the panel by the voltage applied from each electrode of the electron gun. The propagation path of the electron beam is adjusted by the magnetic field of the magnet mounted on the neck of the funnel, and the adjusted electron beam is scanned on the inner surface of the panel by the deflection yoke 9, and the deflected electron beam is shadow mask coupled to the inner frame of the panel. Color selection is performed while passing through the thin slot (7), and the selected electron beams collide with each fluorescent film on the inner surface of the panel to emit light to reproduce an image signal.

In order to prevent the electron beam from deflecting under the influence of the geomagnetism, the electron beam passes through a thin slot of the shadow mask to reach the fluorescent film, and the geomagnetic shield structure behind the frame where the shadow mask 7 is coupled to the panel. An inner shield 10 is attached.

In this structure, the electron beam does not pass through all the thin holes of the shadow mask, but only about 30% passes and the remaining 70% impinges on the shadow mask surface and is converted into heat, and the converted heat is transferred to the shadow mask surface. As the thermal mask's thermal expansion occurs due to the increase in temperature, the position of the first shadow mask hole is shifted so that the position of the electron beam that passes through the shadow mask hole and reaches the fluorescent film does not reach the exact color that the original electron beam is trying to reach. Not only that, but in severe cases, the fluorescence film of a different color is reached, and when the screen is implemented, a dominant phenomenon that causes color bleeding occurs.

Since the doming phenomenon causes a fatal defect in optical characteristics of various color cathode ray tubes such as white uniformity, bright uniformity, color purity, contrast, and luminance, various methods have been proposed to solve this problem.

Conventionally, the length of the spring supporting the frame 8 and the panel 1 and the welding point are changed to move the shadow mask toward or away from the fluorescent film to adjust the distance between the fluorescent film and the shadow mask. I tried to compensate for the domming of the mask.

However, as described above, the compensation of the shadowing of the shadow mask is performed at the time when the shadow mask is thermally expanded to complete the domming.

In order to prevent the doming phenomenon as described above, it is conventionally disclosed that the material of the shadow mask is made of Invar alloy steel, disclosed in US Patent Application Nos. 647,934 and 4,528,246, and Japanese Patent Application Publication No. 59-15861. have.

In the case of using Inba alloy steel as described above, there is an advantage of reducing thermal expansion of the shadow mask, but there are disadvantages in terms of price and processing.

In addition, as a method of reducing thermal expansion of the shadow mask, a method of applying a material such as lead, borate or the like with less thermal expansion to the surface of the shadow mask is known from EP 013979. As another method of preventing the doming phenomenon, a method of coating a thermal insulating material having excellent thermal insulation is known. This method prevents the heat transferred by the electron beam to the shadow mask. At this time, a ceramic material is mainly used as the insulating material.

Another method is to increase the thermal radiation rate by coating a material having excellent thermal radiation on the surface of the shadow mask or by blackening the shadow mask and according to Korean Patent No. 86-1598 filed in Korea by Philips. There is known a method of applying an aqueous suspension containing an electron reflecting substance to the.

As another method, the spray method and the sputtering method are commonly used to coat materials such as thermal insulation materials and thermal radiation materials on shadow masks or electron gun surfaces, even if the spray process is finely controlled. Part of the hole of the shadow mask surface is often clogged, the coating surface formed by this method is not uniform, the thickness of the coating layer is thin, there is a problem that the deposition equipment is expensive, the production efficiency is low.

In Korean Patent Laid-Open Nos. 97-29973, 97-63326, 98-66425, 98-71999 and European Patent WO97-29504, the radiation of WO ₃ or Bi ₂ O ₃ is 30-78%, and the thermal radiation as the electron reflection material. Screen coating of carbon, manganese, manganese oxide, and aluminum oxide as a material is applied by screen printing on the shadow mask to reduce the domming and greatly improve the hole clogging phenomenon of the shadow mask generated in the spray coating.

As the screen printing method, as shown in FIG. 2, a paste 13 made of a printing composition is uniformly applied using a scraper 14 onto the screen mesh 12 that is firmly fixed to the rectangular frame 8, and then a printed circuit board. (11) Put the shadow mask (7) to be printed on the top, and then apply a uniform pressure to the squeegee (15) to move the paste to print in the desired form. In the case of using such a method, it is possible to construct a dominant reduction film having a thicker and more uniform film thickness than the spray coating method.

Tungsten (W) or bismuth (Bi), or its oxide, which is a paste material mainly used as an electron reflecting material using the above method, serves to reflect back the electrons that reach the shadow mask surface of the electron beam generated from the electron gun in advance. In order to attach such an electron reflecting material on the shadow mask, glass is used as an adhesive to melt-bond through a high temperature blackening process.

The glass is an insulator, but when heated, it gradually becomes viscous and flows into it. Therefore, it can be said to be a very suitable material to be used in the seal process because it can be combined with these materials by fusing well with metal materials.

The glass adhesive is mainly used in the sealing of the panel of the cathode ray tube and the funnel PbO-ZnO-B ₂ O ₃ type crystalline frit glass (friit a series of glass powder capable of sealing work within 500 ℃ Is called). Such frit glass has a lower coefficient of thermal expansion compared to the shadow mask in addition to the above-mentioned binder, and thus serves to reduce the expansion of the shadow mask due to heat.

In other words, the coefficient of thermal expansion of frit glass has a thermal expansion coefficient of about 95 to 105 × 10 ^-7 / ° C, which is typically lower than that of aluminum killed steel (AK) used in shadow masks. Since the binder is melted and adhered to the shadow mask surface, the binder may have an effect of suppressing thermal deformation of the shadow mask.

However, when the coating composition is coated on the shadow mask in the prior art, several problems occur as described below.

It must contain a large amount of electron reflecting material in order to obtain sufficient electron reflecting effect. Therefore, as the content of the electron reflecting material is less in the overall printing composition paste, the proportion of frit glass is reduced. In this case, since the amount of fritted glass, which is a molten adhesive, is small, when the shadow mask is pressed into a desired shape as the adhesion between the electron reflecting material and the shadow mask decreases, The dropping of the reflective film or the high temperature blackening process causes the electron reflective film to peel off from the shadow mask surface. Therefore, in this case, not only the desired dope effect can be expected, but also foreign materials such as electron reflecting material peeled off from the cathode ray tube may be generated, which may cause a withstand voltage defect.

In addition, another problem that appears due to the low proportion of frit glass in the printing composition is that the amount of frit having a low coefficient of thermal expansion compared to the shadow mask causes the frit glass to heat up the shadow mask. We can expect the effect of performing the role of suppressing deformation.

In addition, in the case of frit glass used in the current technology, the thermal expansion coefficient is about 80% of the shadow mask, so there is no effect of reducing the thermal expansion of the shadow mask. In other words, frit glass having a low coefficient of thermal expansion melts and adheres to a shadow mask surface having a high coefficient of thermal expansion, thereby reducing the dope effect. Therefore, it is preferable to use fritted glass having a low coefficient of thermal expansion. It is a method that can maximize the dope effect by (frit glass).

The present invention is to solve the above-mentioned problems, and to specify a screen printing paste composition using a frit glass with a low coefficient of thermal expansion together with an electron reflecting material as a melt adhesive and doming it by applying it to a shadow mask for cathode ray tubes It is an object of the present invention to provide a face composition for screen printing that can further enhance the reduction effect.

1 is a structural diagram of a color cathode ray tube

2 is a screen printing process diagram for the shadow mask

3 is a state diagram showing a dominant measuring point

Explanation of symbols for main parts of the drawings

1 panel 7 shadow mask 13 paste

The present invention for achieving the above object is an electron reflecting film, an electron reflecting film composed of an electron reflector, a heat radiating agent, a molten adhesive and an organic material attached to the shadow mask surface, the coefficient of thermal expansion is 85 × 10 ^-7 / ℃ or less It is made of a shadow mask for color cathode ray tubes, characterized in that an electron reflection film for reducing dope is formed by using (frit glass) as a molten adhesive.

In the paste composition screen-printed on the surface of the shadow mask for color cathode ray tube, the electron reflecting material, the heat radiating material, and the organic material may be those of the existing composition, and the electron reflecting material may be tungsten (W), bismuth (Bi), or the like. At least one material of the oxides (WO ₃ , Bi ₂ O ₃ ), the thermal radiation material may be one or more materials of carbon, manganese, manganese oxide, aluminum oxide. And the vehicle (Vehicle) is largely composed of organic binder, organic solvent.

The organic binder is mainly used in cellulose, acrylic, vinyl, epoxy resin, acrylic is broken well after firing, vinyl is mainly used for low viscosity, the binder of the cellulose-based is the most used. However, it can be used to change the choice of binder depending on the process.

The organic solvent is a solvent having a low boiling point, a middle boiling point, a high boiling point, which should be selected to have a property of dissolving the organic binder well with workability.

For example, the organic solvents n-Butyl Carbitol and n-Butyl Carbitol Acetate are mixed and ethyl cellulose is added to the stirring blade at a stirring speed of about 300 to 1,000 rpm for about 30 minutes to 2 hours. Stir. Thereafter, in order to remove bubbles generated during stirring, the mixture is stabilized at room temperature for 4 to 12 hours.

The drug used in the vehicle combination has a weight ratio of 5 to 50% of ethicellulose, 5 to 30% of n-Butyl Carbitol, and 40 to 90% of n-Butyl Carbitol Acetate. There is no chemical added during the vehicle combination, but a small amount of antifoaming agent, such as SiO ₂ , may be added in small amounts. When the vehicle is heated to a temperature of 30 to 60% during the vehicle combination, the organic binder is well dissolved in the organic solvent. The vehicle manufactured by such an operation is mixed with the electron reflecting material WO ₃ powder and frit glass, and a stirrer such as Kneeder, Plattery Mixer, and three mill mill is used for the mixing operation.

Examples of the melt adhesive include PbO, B ₂ O ₃ having a low coefficient of thermal expansion, and a negative coefficient of expansion such as β-eucliphite and lead titanate, and cordierite, germanite, and zircon. Frit glass using a ceramic having a low expansion coefficient is used.

The frit glass has a coefficient of thermal expansion of 85 × 10 ⁻⁷ / ° C. or less, and the frit glass addition amount is preferably used in an amount of 20 to 80 wt% in the total composition of the paste.

Fritter glass is composed of seal temperature of 400 ~ 490 ℃ and glass transition temperature of 290 ~ 450 ℃. It is completely fused at a lower temperature than conventional glass, so it is completely fused on the shadow mask. Attached. In addition, the frit manufactured as described above has a coefficient of thermal expansion of 85 × 10 ⁻⁷ / ° C. or lower, so that when the frit is completely adhered to the shadow mask through the blackening process, it is lower than the conventional frit glass. By having a coefficient of thermal expansion, it is possible to have a greater effect in reducing the thermal deformation of the shadow mask. The paste prepared as described above requires a rolling operation to maintain unique properties until actual printing.

[Table 1] shows the results of measuring the amount of domming by applying a paste to the shadow mask surface for color cathode ray tubes through the above-described method. The end dominant amount and the 2/3 point dominant amount shown in [Table 1] are based on the measurement data of a 21 "cathode ray tube, and the end point (b) and the 2/3 point (c) of FIG. ).

Figures in parentheses in Table 1 show the relative proportions of the doses based on the doses of the non-treated comparative products at the same point.

Paste Tip Doming amount 2/3 point Doming amount Invention One Low expansion fritted glass: 40% 39 (40.6%) 41 (38%) WO ₃ 30% Vehicle 30% 2 Low-expansion fritted glass: 50% 44 (45.8%) 46 (43%) WO ₃ 25% Vehicle 25% Comparative invention No treatment on shadow mask 96 (100%) 107 (100%)

As described above, the present invention obtains a shadow mask that can further improve the dominance reduction effect by using frit glass having a low thermal expansion coefficient as a molten adhesive among the electron reflecting materials applied to the shadow mask surface for color cathode ray tubes. .

Claims (6)

In the case where the electron reflecting film composed of an electron reflector, a heat radiating agent, a molten adhesive, and an organic material is attached to the shadow mask surface, electrons are formed using a frit glass having a coefficient of thermal expansion of 85 × 10 ⁻⁷ / ° C. or less as a molten adhesive. Shadow mask for color cathode ray tube, characterized in that the reflective film is formed. The method of claim 1, A shadow mask for color cathode ray tubes, characterized in that the component of frit glass is at least one or more of β-eucliphite, lead titanate, cordierite, wyrite, and zircon. The method according to claim 1 or 2, A shadow mask for color cathode ray tubes, characterized in that the composition of fritted glass is 20 to 80% by weight in the total composition. The method of claim 1, A shadow mask for color cathode ray tubes, characterized in that the electron reflecting material is at least one of tungsten (W), bismuth (Bi) or an oxide thereof. The method of claim 1, Shadow mask for color cathode ray tube, characterized in that the thermal radiation material is at least one of carbon, manganese, manganese oxide, aluminum oxide. The method of claim 1, A shadow mask for color cathode ray tubes, wherein the electron reflection film is formed by screen printing.