KR100266622B1 - Method of manufacturing a contact stud coating - Google Patents

Abstract

PURPOSE: A method for making a stud-coating is provided to enhance a performance reliability of a color cathode ray tube by using a stud-coating made of a frit being a semi-glass material. CONSTITUTION: In a method for making a stud-coating, a colloidal graphite mixture is prepared, and an acrylic resin solution inserted in a lacquer film of a face plate is prepared. A binder solution is prepared. The solution and the colloidal graphite mixture are changed to a powder state. The acrylic resin solution is made by being melted in a butyl cellosolve. The binder solution is a homogeneous mixture of a butyl cellosolve, N-butyl acetate, and a resin binder. The stud-coating is baked by a tube backing cycle, The stud coating includes a colloidal graphite suspension in a base being a solvent for the lacquer film.

Description

Stud coating manufacturing method

FIELD OF THE INVENTION The present invention relates to cathode ray picture tubes, and in particular, an electrical path between a color cathode ray tube electron beam shadow mask and a screened faceplate. The present invention relates to a stud coating composition and a method for producing the same.

A color television cathode ray picture tube consists of a glass bulb with a funnel and a faceplate sealed at the flared end of the funnel. The electron gun provides one or more electron beams and is installed in the neck of the funnel. The faceplate has an almost flat surface on which a group of fluorescent materials excited by the electron beam is deposited. The electron beam shield allows a single electron beam to mask the fluorescent materials to excite the fluorescent material and select a color. The electron beam shield is accurately attached to the faceplate by a plurality of support springs detachably coupled to metal studs extending from the faceplate. A coating of colloidal graphite with electrical conductivity is applied to the inner wall of the funnel and subjected to a high voltage applied through an anode button on the funnel wall.

It is a known technique to make an electrotransmission film of aluminum and to treat the fluorescent screen with aluminum. The electron transmitting film increases the display brightness by acting as a mirror and reflecting light generated by the fluorescent material toward the rear. An organic film, such as lacquer, is applied onto phosphor deposits before adding aluminum. The organic film fills the non-flat surface in the fluorescence deposition, and makes a smooth surface so that aluminum can be deposited, thereby utilizing the soft characteristics of the lacquer.

The electron beam shield and aluminum film must be subjected to an anode voltage across the funnel coating. The electrical path to which the anode voltage is applied includes one or more springs extending from the electron beam shield connected to the funnel coating. The anode potential on the electron beam shield is connected to aluminum film and metal support studs through shadow mask suspension springs. The metal support studs are painted with a conductive " moustache " which extends to the aluminum film in order to make an electrically conductive path to the aluminum film. In general, the conductive rustless material is referred to as stud coating.

A conventional conductive material widely used for stud coating is water-soluble silicate, which can be painted with a brush. Continuing the tube baking process, the water escapes and leaves a hard and conductive film between the stud and the aluminum film. Water based solutions usually contain potassium silicate or sodium silicate as binders, and are not only in the wet state but also in adhering the components. . As a result, pieces of the coating peel off studs and glass areas into thin pieces, blocking one or more holes in the electron beam shield, making the electron tube bad. The particles in the gun area cause arc and / or cathode poisoning between the electrodes. Water-soluble coatings should be further baked after aluminum and before stud dag.

In US Pat. Nos. 4,289,800 and 4,301,041, which the inventors assigned to Zenith Electronics Corporation, solve the problems of the prior art described above, and eliminate the steps of baking aluminum and then baking, thereby reducing the cost Contains information about shortening. In addition, the patents cited by reference in the present invention are semi-finished in volatile solvents for lacquer film (under the aluminum film) and thickening agents with a viscosity enough to be painted. Disclosed are a stud coating composition comprising a mixture of frit grains, which are glass raw materials, and colloidal graphite, and a method of composition thereof. Through an aluminum film with many small pores, the solvent penetrates into the lacquer layer and is discharged in a tube baking cycle by a Lehr oven. The stud coating solution and the method for producing the solution described in the invention of the above cited reference have been widely used in the industrial field, and have obtained good reactions for many years.

The frit-shaped stud coating, a semi-glass material described in the above-referenced reference invention, causes defects during breakdown or interruption during the production process. In particular, during the extended time resulting from the stop of the production line, this problem occurs in the tubes affected in the high temperature Lehr oven. Lead oxide in the frit, a semi-glass raw material, reacts with carbon in graphite to produce carbon dioxide and lead, and eliminates the conductivity of stud coatings. In many cases, even if the production line is extended and during its downtime, care must be taken to control the rare ovens to eliminate the problem, but still solving the problem remains a difficult task. Although inherent malfunctions with arcs in the industrial field, the use of stud coatings in sufficient amounts to pass the final inspection and testing of the tubes further complicates the problem. Since the above problem does not occur many times because it does not occur during the defined test of the cathode ray tube, once it occurs, it greatly affects the cathode ray and is costly to the consumer.

An object of the present invention is to improve the performance reliability of a color cathode ray tube.

Another object of the present invention is to reduce the manufacturing cost of the color cathode ray tube.

It is still another object of the present invention to provide a cathode ray tube with a stud coating that minimizes arcing.

As described above, the color cathode ray tube is an image faceplate containing a fluorescent material in which a lacquer film and an aluminum film are successively overlapped. An electron beam shadow mask is secured to the faceplate by a plurality of metal studs lining from the faceplate. An electrical bridge is between the electron beam shield and the aluminum film through the stud, and the stud coating causes the aluminum film to hang at the anode potential. (As well known, the electron beam shield is connected to the nose positive voltage, which is connected to the inside of the funnel by a spring connecting a frit seal, a non-conductive semi-glass material, between the cathode ray tube faceplate and the funnel. Is the voltage across the coating connected to it.)

According to the present invention, an improved bake-harden solution providing stud-coated electrical bridges or mouseaches comprises a mixture of micron-size graphite grains. The granules are suspensions floating in an evaporative solvent for lacquer film. The suspension contains a thickening agent thickened in sufficient amount to have a viscosity sufficient to be painted with a brush. When the solution is applied between the suspension studs and the aluminum film, the solution permeates into the lacquer film. When the tube is baked, the solution hardens to form a conductive bridge by electrically connecting the electron beam shield and the aluminum film.

The solution may have a viscosity in the range of 200 to 800 centripoises, with about 550 centripoises being appropriate. After baking, the solution has an electrical resistance on the order of 100 to 500 ohms per unit area. The electrically conductive stud coating according to the present invention makes one gallon in the following manner. Equivalent materials supplied by other sources may be used.

The acrylic resin sock solution is a solution of 225 grams of Elvacite 2044-Source ICI Acrylics from 2025 grams of purified butyl cellosolve (Fisher Scientific Co.). E179).

225 grams of butyl cellosolve in a suitable container (2000 ml beaker), 675 grams of N-butyl acetate (B-396 from Fisher Scientific Co.) and 630 grams of resin Place in a binder and stir until the solution is a uniform resin binding solution.

The material in the table below is placed in a ball mill containing about 8000 grams of grinding media.

Ingredient Amount (grams) weight(%) range Graphite HPN-2 630 14 12-16 Graphite LN 1052 (Source Grapfo Colloids) 90 2 1-3 Acrylic Resin Stock Ssolution 2250 50 45-55 Resin Binder Solution 1530 34 30-38

The ball jar is rotated for 22 to 24 hours and the powdered coating suspension is placed in a 1 gallon container.

Such coating preparation should be carried out in a well-ventilated place after the person concerned handles such things as rubber gloves, a gas mask, a lab coat, a headband and a shoe cover. This is because N-butyl acetate and the resin binder solution are flammable.

The stud coating prepared and used according to the present invention eliminates the problems described above by using a stud coating of frit that is a half glass material. A key feature of the new stud coating was its resistance to flaking and improved resistance. In addition, the stud coating according to the invention is less expensive and does not need to be baked further for the cathode ray tube.

In testing, a prior art frit based stud coating is applied to the stud film and the aluminum film and subjected to a temperature of 450 degrees Celsius for 2 hours. That is, the resistivity of the coating increases from 300 to 73,000 ohms, and under the same conditions, the resistivity of the new stud coating becomes 300 ohms.

When the line producing the cathode ray tube is operated, rejects due to the stud arc were about 0.3% in the stud coating based on the frit of the prior art, but the stud coating according to the present invention does not produce defective products due to the stud arc. Do not.

So far, the new stud coating composition which solves the problem of the stud with respect to aluminum film conductivity in a cathode ray tube and the method of its composition was demonstrated.

The stud coating prepared according to the present invention, by using a stud coating made of frit, which is a semi-glass material, can not only improve the resistance after processing the flaking but also reduce the cost and reduce the cathode There is no need to bake additional tubes. It also eliminated rejects due to stud arcs in cathode and production lines.

It will be appreciated by those skilled in the art from the embodiments of the present invention that many changes may be made without departing from the spirit and scope of the invention. The invention is limited by the terms defined in the claims.

Claims (9)

In the method of manufacturing a stud coating, Providing a colloidal graphite mixture, Preparing an acrylic resin solution that can penetrate the lacquer film of an aluminum-treated cathode ray tube face plate; Preparing a binder solution; Stud coating manufacturing method comprising the step of powdering the solution and the graphite mixture. The method of claim 1, The acrylic resin solution is a stud coating manufacturing method characterized in that made by dissolving the acrylic resin in butyl cellosolve (butyl cellosolve). The method of claim 2, The resin binding solution, A method for preparing a stud coating comprising preparing a butyl cellosolve, an N-butyl acetate, and a resin binder into a homogeneous mixture. The method of claim 3, The weight percentage of the stud coating solution, 16% colloidal graphite, 14% resin (binder), 5% acrylic resin, 15% N-butyl acetate, A method for preparing a stud coating comprising 50% butyl cellosolve. In the stud coating for electrically connecting the studs on the front face plate of the color cathode ray tube and the aluminum film, Colloidal graphite dispersed in an acrylic resin solution that can penetrate the lacquer layer beneath the aluminum film; And an organic solvent in the coating made by baking the flexible conductive connection such that flaking does not occur with the lacquer layer during baking of the tube. The method of claim 5, The coating is With acrylic resin solution, Stud coating manufacturing method comprising a resin bonding solution. The method of claim 6, The acrylic resin solution, A method for producing a stud coating, comprising an acrylic resin dissolved in a butyl cellosolve solution. The method of claim 7, wherein The resin binding solution, A method of producing a stud coating comprising a resin binder, N-butyl acetate, and butyl cellosolve. The method of claim 8, The weight percentage of always coating 16% colloidal graphite, 14% resin (binder), 5% acrylic resin, 15% N-butyl acetate, A method for preparing a stud coating comprising 50% butyl cellosolve.