KR0131933Y1 - Slurry recovery cover - Google Patents

Abstract

The present invention discloses an improved slurry recovery cover of a color cathode ray tube.

Conventionally, since the inner surface of the recovery cover is formed in a flat plane, the scattered slurry is thrown out and re-entered into the panel, causing a coating failure.

The present invention solves the conventional problem by forming irregularities on the inner surface of the recovery cover so that the scattered slurry is birefringent.

Description

Slurry Recovery Cover

1 is a cross-sectional view showing a conventional recovery cover.

2 is a cross-sectional view showing a recovery cover according to the present invention.

Figure 3 is a principle diagram showing the action of the present invention recovery cover.

4 is a cross-sectional view showing another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

11,21: salvage cover C: carrier

13,23: Skirt (of recovery cover) P: Panel

12a, 13a: unevenness (of the recovery cover) 23: bellows

The present invention relates to the production of color cathode ray tubes, and more particularly to a slurry cover used to recover excess slurry in a fluorescent surface forming process.

The fluorescent surface of the color cathode ray tube is formed by forming fine R, G and B phosphor stripes or dots between the black matrices. The most suitable method for forming such a microstructure is a photolithography method. lithographic method). In this method, a required stripe is sequentially formed by coating and drying a slurry such as a phosphor on an inner surface of a panel and then exposing and developing the slurry. However, in order to obtain a good fluorescent surface, since the coating thickness of the slurry has to be uniform, a slurry is usually injected into the inner surface of the panel, and then the coating layer is rotated at a high speed to obtain a uniform coating thickness. In this case, it is common to form an extra film thickness, and the remaining slurry is scattered to the outside of the panel by centrifugal force, which contaminates another adjacent panel.

FIG. 1 shows a conventional recovery cover for recovering the slurry as described above. The panel P supported by the carrier C is rotated together with the carrier C by the rotation of the driving means after the slurry is injected to scatter the excess slurry by centrifugal force. The scattered slurry is guided by a cylindrical recovery cover 1 positioned to surround the panel P and dropped to the lower portion thereof, and is then recovered along the recovery pipe 4 to a recovery means not shown.

However, since the conventional recovery cover 1 has a flat inner surface, the slurry scattered from the panel hits the recovery cover 1 and reenters the inner surface of the panel P. In more detail, the panel P supported by the carrier C is rotated at a considerably high speed, in which the slurry is scattered approximately radially by its centrifugal force. As a result, almost no slurry is scattered on the inner surface of the base 2 of the recovery cover 1, that is, the bottom surface, and most of the slurry is directed to the skirt 3. Therefore, since the amount of the slurry directed to the base 2 of the recovery cover 1 is not very small and does not collide with a very large force, there is no fear of re-entry into the panel P as shown by the dotted arrow, which is not a problem. However, since the slurry directed to the skirt 3 collides with the skirt 3 by a large centrifugal force, it is bounced out of it as shown by the solid arrow and enters the inner surface of the panel P again. This results in uneven coating thickness of the slurry on the inner surface of the panel P, resulting in poor coating of the fluorescent film, as well as minute black spots on the inner surface of the panel P. Could not be guaranteed.

It is an object of the present invention to provide a slurry recovery cover which can prevent excess slurry scattered from entering the panel in view of such a conventional problem.

In order to achieve the above object, the slurry recovery cover of the present invention is characterized by having a reentry means for preventing extra slurry scattered during rotation of the panel from reentering the panel.

According to one preferred feature of the present invention, the re-entry prevention means is characterized in that the concave-convex is formed on the inner surface of the recovery cover.

According to another preferred feature of the present invention, the re-entry prevention means consists of bellows.

As a result, the present invention does not re-enter the extra slurry scattered during the rotation of the panel, thereby preventing the conventional fluorescent film coating defects and the like, thereby exerting a great effect on improving the production efficiency and reliability of the cathode ray tube.

Specific features and other advantages of the present invention will become more apparent from the following description of the preferred embodiments with reference to the attached drawings.

In FIG. 2, the slurry recovery cover 11 according to the present invention has a base 12 positioned to face the panel P supported by the carrier C, and extends from an edge of the base 12 so that the panel ( It consists of the skirt 13 which surrounds P). The inner surface of the recovery cover 11 is formed with irregularities (12a, 13a) as a means for preventing the re-entry of the slurry scattered in accordance with the features of the present invention. The unevenness 12a, 13a may be formed only in the skirt 13 because the slurry scatters substantially radially when the panel P is rotated, but is preferably also formed at the base 12 together. Unevenness (12a, 13a) in the figure is shown as having a triangular cross section, which can be modified in various forms, any shape as long as it can prevent the scattered slurry to re-enter the panel (P). Reference numeral 14 is a recovery pipe into which the recovered slurry is introduced.

Referring to the operation of the slurry recovery cover according to the present invention configured as described above are as follows.

In FIG. 2, as the carrier C is rotated by the driving means (not shown), the panel P in which the slurry is injected is rotated together. Then, the excess slurry which formed the coating film of the predetermined thickness in the inner surface of panel P is scattered from the panel P by centrifugal force. The slurry scattered in this way is hardly scattered to the base 12 of the recovery cover 11 as shown by the dotted arrow, and is mostly directed to the skirt 13 as shown by the solid arrow. By birefringence to the concave-convex (12a, 13a) that is the re-entry prevention means of the present invention is prevented re-entry to the inner surface of the panel (P) as in the prior art.

That is, the principle of the present invention is well illustrated in FIG. 3, for convenience, the unevenness 13a of the skirt 13 will be described as an example. The slurry scattered from the panel P hits one of the unevenness 13a and is bended in a predetermined angle to bounce. The slurry thus thrown out again strikes the adjacent unevenness 13a with a relatively small force. This slurry is again bent in a certain angle direction by the unevenness 13a to be scattered in a predetermined direction, but the force at this time is in a very small state. Accordingly, even if the scattering direction is the panel P side, it will not be able to enter the panel P again. This principle of action is also applied to the unevenness (12a) of the base 12 as it is, at this time the slurry has a very small amount and force, so that reentry into the panel (P) is essentially prevented. Thus, the slurry guided to the recovery cover 11 is recovered along the recovery pipe 14 to the recovery means (not shown).

On the other hand, the configuration shown in FIG. 4 adopts the bellows 23 instead of the unevenness 13a of FIG. The bellows 23 may be installed in a normal recovery cover, but preferably, the bellows 23 is attached to one end of the cylindrical support 22 having a predetermined width to form the recovery cover 21 as shown. The lower part of the bellows 23 is attached with a recovery pipe 24 through which the recovered slurry is guided. The bellows 23 is preferably composed of a soft synthetic resin material or rubber material. Embodiments of this configuration can also prevent the slurry from being scattered back into the panel P by the same principle as the above-described embodiment. In addition, since such a configuration is to extend the length of the bellows 23 as shown by the virtual line, the effect is further increased.

According to the present invention as described above, since the excess slurry scattered during the rotation of the panel does not re-enter the panel as in the prior art, not only the uniform coating of the fluorescent film is possible but also the occurrence of black spot phenomenon is fundamentally prevented. Therefore, the present invention has a great effect in improving the manufacturing efficiency and reliability of the cathode ray tube.

Claims (3)

A slurry recovery cover for recovering the slurry scattered during rotation of a slurry-injected panel, the recovery cover 11 is provided with a re-entry prevention means for preventing the scattered slurry from re-entering the panel (P) Slurry recovery cover, characterized in that configured. The slurry recovery cover according to claim 1, wherein the re-entry prevention means is irregularities (12a, 13a) formed on an inner surface of the recovery cover (11). The slurry recovery cover according to claim 1, wherein said re-entry prevention means is a bellows (23) provided in said recovery cover (11).