KR19980031794A - Anti-Doming Composition of Shadow Mask and Method of Making the Same - Google Patents

Abstract

Anti-doming compositions of shadow masks comprising zeolite and electron reflecting materials, such as vehicles and bismuth oxides, and shadow masks for color cathode ray tubes coated with the compositions block heat transfer to inhibit the temperature rise of the shadow masks, thereby reducing the doming incidence rate from about 30 to It can be reduced by 50%, while being inexpensive and easy to process.

Description

Anti-Doming Composition of Shadow Mask and Method of Making the Same

[Industrial use]

The present invention relates to an anti-doming composition of a shadow mask and a method of manufacturing the shadow mask, and more particularly, to a shadow mask by coating an anti-doming composition comprising a mixture of an electron reflecting material such as bismuth oxide and zeolite on a shadow mask for cathode ray tubes. It is providing the anti-doming composition of the shadow mask which can suppress the temperature rising of and its manufacturing method.

[Private Technology]

A typical shadow-mask-type CRT tube has three electron beams, red, green, and blue, which are irradiated by an electron beam launcher, focus through a hole in the shadow mask and then focus on a panel. Each electron beam collides (lands) on red, green, and blue phosphors formed on an inner phosphor screen to reproduce a predetermined image.

As such, the shadow mask used for the color cathode ray tube performs a color screening function for selecting the electron beam irradiated from the electron beam, and is mainly a method of corrosion by applying photolithography to A / K (aluminum-killed) steel of pure iron material. It is common to make hundreds of thousands of holes on the surface of the fabric.

The general manufacturing process of such a shadow mask is described in more detail as follows.

Roller leveling of the A / K steel gives plastic deformation to the mask plate, imparting flatness and work hardening, and then forming into a uniform form by pressing. After the foaming is completed, the mask plate is subjected to a degreasing process of removing foreign substances such as contamination and fingerprints, and then a hole is formed to pass through the electron beam. The process of forming a hole in the mask plate is performed by a method using photolithography, in which the photoresist is applied to the mask plate on which degreasing is completed, exposed, developed, and then etched. When the etching process is completed, a hole for passing a predetermined electron beam is formed in the shadow mask. In this way, the shadow mask is manufactured by applying a blackening process as a means for preventing the doming to the shadow mask in which the hole is formed.

Meanwhile, about 20% of the electrons irradiated from the electron gun and arrive at the shadow mask emit light through the shadow mask, and about 80% are absorbed by the shadow mask to induce thermal expansion of the shadow mask. Is raised to about 80-90 ° C. This phenomenon of thermal expansion of the shadow mask is called doming, which causes each hole on the shadow mask to move, resulting in a different light emission position, and even other colors to emit light, thereby lowering the purity of the cathode ray tube. Becomes Therefore, efforts are being made to develop an anti-doming method in order to prevent such a doming phenomenon.

As described above, the manufacturing technology of cathode ray tube using Invar steel as a shadow mask to prevent the color purity deterioration by doming is disclosed in Japanese Patent Laid-Open Nos. 59-15861, US Pat. Nos. 647924 and 4528246. Is disclosed. Invar steel is widely used as a material for shadow masks for high-definition cathode ray tubes of 15 inches or more because the thermal expansion coefficient of the A / K steel is 11.7 × 10 ^-6 / K, which is very small at about 1/10 and the effect of reducing doming is excellent. Although used, there are problems such as high price and difficult processability.

In addition, Korean Patent Application No. 86-1589 discloses that a heavy metal such as lead (Pb), bismuth (Bi), tungsten (W) and the like is applied to the electron gun side of a shadow mask to apply an electron reflection film to reduce heating by an electron beam. The technique to make is disclosed. However, these heavy metal films are not easy to apply, and only about 30% of the dope reduction effect can be obtained, and it is difficult to apply them to the actual mass production process. In addition, in the case of tungsten film, since oxidation generally occurs at a temperature of 300 ° C. or more, there is a problem that severe oxidation occurs at a temperature of about 450 ° C. of the firing and sealing process.

The present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to reduce the temperature rise of the shadow mask to reduce the dominant incidence of about 50% or more, at the same time, the price is cheap, easy It is to provide an anti-doming composition of a shadow mask and a method for producing the same for preventing doming with workability.

In order to achieve the object of the present invention as described above, the present invention provides an anti-doming composition and a vehicle, a bismuth oxide (Bi ₂ O ₃ ), lead (Pb), tungsten, including a vehicle and a zeolite (zeolite) as a heat insulating material. An anti-doming composition of a shadow mask comprising an electron reflecting material such as oxide (WO ₃ ) and zeolite, and a steel sheet for shadow mask including a plurality of holes through which an electron beam passes, and a coating film formed of the anti-doming composition. It provides a shadow mask comprising a. Here, the zeolite is included in 10 to 90 parts by weight based on the total weight of the composition, the coating film is preferably formed to a thickness of 3 to 30㎛ using a silk screen printing method.

In addition, the present invention is a bismuth oxide, lead on the coating film formed of an anti-doming composition comprising a zeolite and a steel sheet for a shadow mask including a plurality of holes for passing the electron beam and the zeolite powder And it provides a shadow mask comprising a coating film formed of an anti-doming composition comprising a powder of an electron reflecting material such as tungsten oxide. Here, each of the coating film is preferably formed to a thickness of 3 to 30㎛ using a silk screen printing method.

In another aspect, the present invention provides a shadow mask comprising a method of producing an anti-doming composition of a shadow mask comprising a step of mixing a vehicle and a zeolite and a process of mixing a zeolite and an electron reflection material such as vehicle, bismuth oxide, lead and tungsten oxide In a method for producing a shadow mask to provide a method for producing an anti-doming composition of the present invention, to form a coating film using the anti-doming composition prepared to prevent doming in the steel sheet for shadow mask comprising a plurality of holes for passing the electron beam In the anti-doming composition, an anti-reflective material, such as bismuth oxide, lead, tungsten oxide, and / or zeolite provides a method of manufacturing a shadow mask, characterized in that the. In addition, in the manufacturing method of the shadow mask to form a coating film by using an anti-doming composition prepared to prevent doming in the steel sheet for shadow mask including a plurality of holes for passing the electron beam, the anti-doming composition described above It provides a manufacturing method of a shadow mask comprising a bismuth oxide and a zeolite, respectively, to form a coating film containing a zeolite after forming a coating film containing a zeolite. Here, each of the coating film is preferably formed to a thickness of 3 to 30㎛ using a silk screen printing method.

EXAMPLE

Representative Example

After mixing zeolite with an electron reflecting material such as bismuth oxide, lead, tungsten oxide, etc., an epoxy-based vehicle is added to prepare an anti-doming coating composition of a shadow mask in a paste state, and an appropriate amount of Low melting frit is added to prevent particles from leaving after blackening or firing. Zeolite is represented by the composition formula of Na ₁₂ [(AlO ₂ ) ₁₂ (SiO ₂ ) ₁₂ ] · XH ₂ O. It is a commonly used clay mineral and has very fine pores. In the present invention serves as a heat insulating material to prevent the heat generated by the collision of electrons to be transferred to the shadow mask. In addition, since bismuth oxide has a high electron reflection coefficient, the bismuth oxide reflects a large amount of electron beams before being incident on the shadow mask to suppress the temperature rise of the mask. Screen coating may be used as a coating method for coating the coating composition on the shadow mask having completed the annealing process. As such, the shadow mask of the present invention is manufactured by further improving the anti-doming property through the blackening process of the shadow mask on which the coating layer is formed to prevent the doming.

Preferred Embodiment

Preferred examples and comparative examples of the present invention are described. However, the following examples are merely examples of the present invention showing the constitution and effects of the present invention, and the present invention is not limited to the following examples.

Example 1

A vehicle was prepared by adding 4 g of epoxy resin to 16 g of butyl carbitol. 20 g of zeolite was added to 40 g of bismuth oxide powder, and 20 g of frit was added thereto to prepare a mixed powder. The mixed powder was added to the vehicle to prepare an antidoming composition of the present invention. A coating film having a film thickness of 20 μm was formed on the shadow mask in which the prepared anti-doming composition was annealed by a silk screen method. Thus, the shadow mask for the color cathode ray tube of the present invention was manufactured by further heating the anti-domming property by heating the shadow mask having the coating layer formed therein to prevent minging at 570 ° C. through a blackening process.

Example 2

A vehicle was prepared by adding 4 g of epoxy resin to 16 g of butyl carbitol. 10 g of zeolite was added to 50 g of lead powder, and 20 g of frit was added thereto to prepare a mixed powder. The mixed powder was added to the vehicle to prepare an antidoming composition of the present invention. A coating film having a film thickness of 20 μm was formed on the shadow mask in which the prepared anti-doming composition was annealed by a silk screen method. Thus, the shadow mask for the color cathode ray tube of the present invention was manufactured by further heating the anti-domming property by heating the shadow mask having the coating layer formed therein to prevent minging at 570 ° C. through a blackening process.

Example 3

A vehicle was prepared by adding 4 g of epoxy resin to 16 g of butyl carbitol. 10 g zeolite was added to 60 g tungsten oxide powder, and 10 g frit was added thereto to prepare a mixed powder. The mixed powder was added to the vehicle to prepare an antidoming composition of the present invention. A coating film having a thickness of 15 μm was formed on the shadow mask in which the prepared anti-doming composition was annealed by a silk screen method. Thus, the shadow mask for the color cathode ray tube of the present invention was manufactured by further heating the anti-domming property by heating the shadow mask having the coating layer formed therein to prevent minging at 570 ° C. through a blackening process.

Example 4

A vehicle was prepared by adding 4 g of epoxy resin to 16 g of butyl carbitol. 40 g of zeolite was added to 40 g of frit to prepare a mixed powder. A mixed powder was prepared by adding 16 g frit to 64 g bismuth oxide powder. Each of the mixed powders was added to the vehicle to prepare an anti-doming composition of the present invention. The coating film having a thickness of 10 μm was formed on the shadow mask in which the zeolite-containing composition of the prepared anti-doming composition was annealed by a silk screen method, and then a coating film was formed on the composition containing bismuth oxide. Thus, the shadow mask for the color cathode ray tube of the present invention was manufactured by further heating the anti-domming property by heating to a shadow mask having a double coating layer for preventing ming through blackening process.

Example 5

A vehicle was prepared by adding 4 g of epoxy resin to 16 g of butyl carbitol. 40 g of zeolite was added to 40 g of frit to prepare a mixed powder. A mixed powder was prepared by adding 20 g frit to 60 g lead powder. Each of the mixed powders was added to the vehicle to prepare an anti-doming composition of the present invention. In the anti-doming composition, a coating film having a thickness of 10 μm was formed on the shadow mask in which the zeolite-containing composition was annealed by a silk screen method, and then the lead-containing composition was formed in the same manner. Thus, the shadow mask for the color cathode ray tube of the present invention was manufactured by further heating the anti-domming property by heating the shadow mask having the coating layer formed therein to prevent minging at 570 ° C. through a blackening process.

Example 6

A vehicle was prepared by adding 4 g of epoxy resin to 16 g of butyl carbitol. 40 g of zeolite was added to 40 g of frit to prepare a mixed powder. A mixed powder was prepared by adding 30 g frit to 50 g tungsten oxide powder. Each of the mixed powders was added to the vehicle to prepare an anti-doming composition of the present invention. The coating film having a thickness of 10 μm was formed on the shadow mask in which the zeolite-containing composition of the prepared anti-doming composition was annealed by a silk screen method, and then the composition containing tungsten oxide was formed by the same method. Thus, the shadow mask for the color cathode ray tube of the present invention was manufactured by further heating the anti-domming property by heating the shadow mask having the coating layer formed therein to prevent minging at 570 ° C. through a blackening process.

Example 7

A vehicle was prepared by adding 4 g of epoxy resin to 16 g of butyl carbitol. 40 g of zeolite was added to 40 g of frit to prepare a mixed powder. The mixed powder was added to the vehicle to prepare an antidoming composition of the present invention. The coating film having a thickness of 10 μm was formed on the shadow mask in which the zeolite-containing composition of the prepared anti-doming composition was annealed by a silk screen method, and then the composition containing tungsten oxide was formed by the same method. Thus, the shadow mask for the color cathode ray tube of the present invention was manufactured by further heating the anti-domming property by heating the shadow mask having the coating layer formed therein to prevent minging at 570 ° C. through a blackening process.

Comparative Example 1

A shadow mask for a color cathode ray tube was manufactured in the same manner as in Example 1, except that the coating film was formed using the anti-doming composition of Example 1.

The method of measuring the dominant incidence rate is generally determined by measuring the maximum position of the beam when it is not subjected to heat and the maximum position of the beam when it is immersed in heat. The domming rate measured by coating the surface of the shadow mask is shown in Table 1.

Maximum Domming Amount (㎛) Doming reduction (%) Example 1 40 33.3 Example 2 42 30.0 Example 3 35 41.7 Example 4 35 41.7 Example 5 38 36.7 Example 6 30 50.0 Example 7 40 33.3 Comparative Example 1 60 -

As a result of preparing the anti-doming composition of the shadow mask and the shadow mask coated with the same by the method of the examples and comparative examples of the present invention, the shadow mask of the example is a shadow of the comparative example by the electron reflection effect of the electron reflective material and the thermal insulation effect of the zeolite. It was confirmed that the temperature can be reduced by 30 to 50% by suppressing the temperature increase compared to the mask, and the price was low and the processability was easy. In the above examples, all 4A type zeolites were used, but the same results were obtained using 3A, 5A, and X type zeolites having the same molecular structure but different pore sizes.

Claims (14)

Vehicle; And Zeolites; Anti-doming composition of the shadow mask comprising a. Vehicle; An electron reflecting material selected from the group consisting of bismuth oxide, lead and tungsten oxide; And Zeolites; Anti-doming composition of the shadow mask comprising a. The anti-doming composition according to claim 1 or 2, wherein the zeolite is included in an amount of 10 to 90 parts by weight based on the total weight of the composition. A steel sheet for shadow mask including a plurality of holes through which an electron beam passes; And A coating film formed of the anti-doming composition of claim 1; Shadow mask comprising. The shadow mask of claim 4, wherein the coating layer is formed to have a thickness of 3 to 30 μm using silk screen printing. A steel sheet for shadow mask including a plurality of holes through which an electron beam passes; A coating film formed of an anti-doming composition comprising a zeolite; And A coating film formed of an anti-doming composition comprising a powder of an electron reflecting material selected from the group consisting of bismuth oxide, lead and tungsten oxide on the coating film formed of the anti-doming composition comprising the zeolite powder; Shadow mask comprising. The shadow mask of claim 6, wherein each of the coating layers has a thickness of 3 to 30 μm using a silk screen. Vehicle; And Zeolites; Method of producing an anti-doming composition of the shadow mask comprising the step of mixing. Vehicle; An electron reflecting material selected from the group consisting of bismuth oxide, lead and tungsten oxide; And Zeolites; Method of producing an anti-doming composition of the shadow mask comprising the step of mixing. The method of claim 8 or 9, wherein the zeolite is 10 to 90 parts by weight based on the total weight of the coating composition. In the manufacturing method of the shadow mask to form a coating film using an anti-doming composition prepared to prevent doming in the steel sheet for shadow mask including a plurality of holes for passing the electron beam, The anti-doming composition is a method of producing a shadow mask, characterized in that it comprises a zeolite. In the manufacturing method of the shadow mask to form a coating film using an anti-doming composition prepared to prevent doming in the steel sheet for shadow mask including a plurality of holes for passing the electron beam, The anti-doming composition is a method of manufacturing a shadow mask, characterized in that it comprises a zeolite and an electron reflecting material selected from the group consisting of bismuth oxide, lead and tungsten oxide. In the manufacturing method of the shadow mask to form a coating film using an anti-doming composition prepared to prevent doming in the steel sheet for shadow mask including a plurality of holes for passing the electron beam, The anti-doming composition is prepared by including an electron reflecting material selected from the group consisting of bismuth oxide, lead, and tungsten oxide and zeolite, respectively, to form a coating film containing zeolite and then to form a coating film containing an electron reflecting material. The manufacturing method of the shadow mask characterized by the above-mentioned. The method of manufacturing a shadow mask according to any one of claims 11 to 13, wherein each of the coating films is formed to a thickness of 3 to 30 µm using a silk screen printing method.