KR940008087Y1 - Panel of crt - Google Patents

Abstract

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Description

Cathode ray panel

1 is a cross-sectional view showing an embodiment of this invention.

2 is a detailed cross-sectional view of a panel designed according to this design.

3 is a conventional panel.

* Explanation of symbols for main parts of the drawings

1: shadow mask 2: neck

3: electron gun 5: panel

6: vacuum area 51: outer glass

52: inner glass

The present invention relates to a structure of a cathode ray tube panel, and more particularly, to a panel which can be made more flat by overcoming the difficulty of explosion-proof design due to the enlargement of the panel by doubling the glass of the panel face.

In general, the manufacturing process of the cathode ray tube generally includes a screen manufacturing process of applying a fluorescent film in a panel, fixing a frame equipped with a shadow mask, an electron gun manufacturing process of arranging a plurality of electrode components in a row, and fixing the stem to the stem; A process of encapsulating an electron gun in a bulb of a water tube, an exhaust process of discharging air from the enclosed bulb, an aging process of the water tube, and a test process of inspecting electrical characteristics of the aged water tube.

The water tube is a device that emits light by colliding the phosphor of the screen with a certain amount as the electron beam accelerated by a high voltage, as is well known already, the problem of producing the water tube increases the tensile stress, the exhaust process described above However, the probability of explosion due to impact during daily use is very high.

In more detail, in the vacuum container, the complete sphere is generally the strongest with respect to the shrinkage in the vacuum vessel, and weakens when it becomes the same type as the cathode ray tube.

On the surface of the cathode ray tube, a particularly strong stress acts on the bulb measurement part by atmospheric pressure. The greatest stress on the outer surface of the bulb is concentrated from the edge of the surface to the skirt. That is, the outer surface between the surface and the skirt portion is subjected to compressive stress on the outer side of the tensile stress. If any impact is applied to the stressed bulb again or if a crack occurs on the surface, it scatters and deflates.

By the way, in order to visually emphasize the flatness of the panel of the cathode ray tube, which has become very large, it has been required to planarize the surface of the panel. However, when the panel is enlarged in size, the concentration of stress increases.

Thus, in order to prevent the explosion of the bulb due to the concentration of stress, the thickness of the panel may be thickened as a whole, but as a whole, the weight is heavy and there is a problem in that it takes a long time to fire the glass.

The present invention was devised to solve the conventional problems as described above, and in order to provide a panel designed to planarize the surface of the panel in the production of large cathode ray tubes and to prevent the shrinkage due to the planarization. have.

To realize this, a cathode ray is composed of an electron gun stored in the neck formed on the small diameter side of the bulb, a shadow mask forming a gap through which the electron beam projected from the electron gun passes, a panel facing the shadow mask, and the like. In the tube, the glass of the panel face consists of a double glass of inner glass and outer glass, and a low vacuum zone for dispersing the vacuum pressure in the bulb is formed between the outer glass and the glass. It relates to a cathode ray tube panel to maintain a vacuum pressure.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a cross-sectional view of a cathode ray tube designed according to the present invention. The electron gun (3), funnel (4), and panel (5), which will form the screen of the cathode ray tube in succession with the funnel (4), form a vacuum zone (6) with its face made of two layers of glass. The two glasses are kept in a high vacuum of about 10 ^-4 Torr.

FIG. 2 shows the panel in more detail in cross section, wherein the outer glass 51 and the inner glass 52 of the panel are arranged at intervals of μ, and the sealant 53, such as frit, is disposed above. The vacuum in the vacuum zone 6 formed by sealing the two glasses is maintained at about 10 ⁻⁴ Torr, and the curvature 52 of the inner glass is made larger than the curvature of the outer glass 51.

And the configuration of the pressure of vacuum degree of 10 ^-7 Torr is formed in the cathode-ray tube, such as by the inner face makin applied to the glass at this time a pressure of about 10 ^-4 Torr which is formed on the inner surface of the glass relative to the action as a result the cathode ray The pressure on the face of the panel is reduced by 10 ^-4 Torr. In other words, the pressure in the vacuum zone disperses the high vacuum in the cathode ray tube. Therefore, the atmospheric pressure of about 10 ^-4 Torr outside the cathode ray tube is relatively higher than the vacuum pressure inside the cathode ray tube, thereby preventing deflation.

According to the above embodiment, it is possible to overcome the difficulty in explosion-proof design of a large panel due to the enlargement of the cathode ray tube, to make it more flat than the conventional panel (FIG. 3), and to take an excessive amount of light by double glass, resulting in improved contrast. It also has the advantage of being.

Claims (2)

An electron gun 3 stored in the neck 2 formed on the small diameter side of the bulb, a shadow mask 1 forming a through hole through which the electron beam projected from the electron gun passes, and a panel facing the shadow mask ( 5) In a cathode ray tube composed of a glass tube, the glass of the panel face is composed of two layers of glass of the inner glass 52 and the outer glass 51, and there is a bulb between the inner glass and the outer glass 51, 52. A panel of cathode ray tubes, characterized in that a vacuum zone (6) is formed for dispersing the vacuum pressure therein. The panel of a cathode ray tube according to claim 1, wherein the vacuum degree of the vacuum zone (6) is smaller than the vacuum degree in the bulb.