KR0129777Y1 - Un-stoppage power supply of cathode ray tube - Google Patents

Abstract

The present invention relates to an uninterruptible CRT. In a series of mechanisms in which a conductive film is coated on the front glass surface of a CRT, a conductive metal tape is connected to the CRT, and then connected to a ground wire provided in the CRT internal circuit to eliminate static electricity formed in the CRT front envelope. In order to provide a safe CRT tube, static electricity is quickly dissipated by maximizing the conductivity of sucking the charged particles by improving the conductive metal tape used in the flat plate structure from the conventional flat structure.

Description

Uninterruptible CRT

1 is a schematic perspective view of a typical CRT.

FIG. 2 is an enlarged sectional view of FIG.

3 is a cross-sectional view of the antistatic conductive tape according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Panel 2: Funnel

3: NECK 4: Lead pin

5: ANODE 6: Conductive Tape

7, 7 ': conductive metal material 8,8': adhesive material

The present invention relates to a CRT tube used in a TV and the like, in particular, high voltage (CRT: Cathode Ray Tube), CPT (Color Picture Tube), CDT (CPT) The present invention relates to an uninterruptible CRT tube in which static electricity generated in an electron tube such as a CDT (Color Display Tube) is quickly absorbed and extinguished.

In general, by inducing hot electron emission by a heater inside an electron gun such as CRT and irradiating the emitted electron beam onto a film coated with a fluorescent material, It is well known that a series of procedural principles for obtaining a screen by luminescence of phosphors are well known. As can be seen from this fact, in order for the emitted electron beam to reach the fluorescent surface and impinge on the fluorescent material, it requires some strong force that gives the electron beam a straight acceleration.

Furthermore, in the structure of the panel on the front of the CRT, an aluminum film was applied to enhance the brightness of the screen. In the order of the emission path of the emitted electron beam, it arrived at the fluorescent surface coated with the fluorescent material after passing through the aluminum film. In order to penetrate the aluminum film and finally impinge the electron beam onto the fluorescent surface, a strong suction force is required as described above. It is for this principle that high voltages above 10 kv are applied at the anode electrode located on the side of the CRT, that is, on the funnel.

On the other hand, the whole country of the anode is connected to the inner graphite conductive film painted on the inner wall of the funnel, and this graphite conductive film is connected to the aluminum film, so that the aluminum film is subjected to the same high voltage as the anode electrode. As a result, the inner wall surface of the panel is positively charged. However, according to the electrical properties of the charged particles, the repulsive force of the same polarity acts on each other, so that the outer glass surface of the panel PANEL is positively charged. It is this electrostatic phenomenon that fine dust is adsorbed on the surface of the front glass tube of a TV and the like, and when people touch the skin, they often get a tingling feeling.

In order to prevent the electrostatic phenomenon, a conductive film is coated on the front glass surface of a CRT tube such as a TV. The conductive film is connected to a conductive metal thin film tape, and the conductive metal tape is connected to a ground wire installed in an explosion-proof band and an internal circuit. As a result, the charging charges are dissipated.

However, the conventional conductive metal tape used in the above-described manner is formed by attaching an electrically conductive adhesive to one side of the conductive metal material of the flat plate as shown in FIG. No matter how conductive, however, the conductive metal material is in direct contact with the conductive film, and inferior in comparison with the functional effect of attracting and following the charged particles. In the case of deterioration due to external factors, the conductivity is significantly lowered, and thus, the attracting ability of the charged particles is also drastically reduced, ultimately leading to a problem in that the electrostatic phenomenon is not smoothly solved.

Therefore, the present invention has been devised to solve this problem, and the present invention effectively absorbs and destroys static electricity generated on the CRT glass, thereby providing an electrostatic CRT without static electricity. There is this.

In order to achieve the above object, the present invention is a conductive film is coated on the front glass of the CRT, and after the conductive film and the conductive metal tape are connected, the method is connected to the ground wire provided in the metal thin film and the internal circuit. As described above, in the conductive metal tape used, the concave-convex cross-sectional structure, rather than the conventional flat plate cross-sectional structure, is characterized in that the conductive metal material is in direct contact with the conductive coating film for rapid outflow of charged particles.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

Example 1

FIG. 1 schematically shows a model of a typical cathode ray tube currently in use, and as described above, a casso installed inside the neck 3, although not shown in the anode 5 and the drawing. There is a high voltage of more than 10kv between the woods. As a result, it is noted that the internal graphite conductive film connected to the anode and the aluminum conductive film located on the inner wall of the panel connected to the graphite conductive film are subjected to the same voltage as that of the entire Anodwood. It is true. As a result, the hot electrons emitted from the cathode acquire sufficient acceleration force and collide with the fluorescent surface, and a positive electrostatic phenomenon is generated on the outside of the fluorescent surface, that is, the glass surface on the front of the panel. . The positively charged particles generated in this way exit the CRT through the conductive metal tape and the ground wire of the internal circuit as described above. As mentioned above, the conventional general conductive metal tape used here As shown in FIG. 2, the adhesive material (although it is conductive) of the conductive metal material (7) is applied to the entire portion of the conductive metal material (7), which itself has a single resistance as a result of the suction function of the charged particles In view of the surface, the effect is inferior to the case where the conductive metal material is in direct contact with the aforementioned outermost conductive coating. This is shown in Figure 3.

As shown in FIG. 3, the conductive metal body 7 'is made into an uneven shape, and the adhesive material 8' is filled only in the recessed U-shaped groove portion which is not in direct contact with the conductive outer film. By bringing the uncoated portion directly into contact with the conductive envelope, the electrical resistance caused by the adhesive material is greatly reduced, and the adhesive material is covered with the entire metallic material. The enhanced static elimination effect will be obtained. As a result, the positive (+) charged particles formed in the outer film quickly exits to the outside.

As described above, the present invention is a mechanism for eliminating static electricity generated in a CRT tube such as a TV, by introducing a conductive metal tape having a concave-convex surface to bring the conductive metal material into direct contact with the conductive outer film, thereby providing an adhesive material. The electrical resistance of the conductive metal tape of the structure covering the entire surface of the metal material can be greatly reduced, so that an electrostatic scavenging effect can be obtained which is extremely fast, thereby providing a safe CRT tube free of static electricity.

Claims (2)

A conductive film is formed on the front glass, and an explosion-proof band is wound around the edge thereof, and the conductive film is a CRT tube electrically connected to the explosion-proof band by a conductive metal tape, wherein the conductive metal tape is formed in an uneven shape. And the grooves which are not in direct contact with the conductive film or the explosion-proof band are filled with an adhesive material so as to contact the conductive film and the explosion-proof band. The uninterruptible CRT tube according to claim 1, wherein the adhesive has conductivity.