KR0137106Y1 - Cathode ray tube - Google Patents

Abstract

In a cathode support in which a heater is provided inside a tubular sleeve supported by a cathode support, and a cap is covered in an opening of the upper portion thereof, and an electron-emitting material of carbonate is laminated on the surface of the cap. Cathode structure of a cathode ray tube, characterized in that the outer diameter is inserted into the rod of the insulating material from the leg portion to the lower portion coated with the insulating material alumina.

Description

Cathode Structure of Cathode Ray Tube

1 is a longitudinal sectional view showing a cathode for a cathode ray tube according to the present invention.

2 is a longitudinal sectional view showing a conventional cathode for cathode ray tube.

* Explanation of symbols for main parts of the drawings

2: cathode support 4: sleeve

6: heater 7: ceramic rod

8: cap 10: electron-emitting material

The present invention relates to a cathode structure of a heat dissipating cathode ray tube, and more particularly, an insulation material is formed on both legs of the heater in order to eliminate thermal loss of the heater leg, thereby improving the heat insulation structure of the heater, which is a source of heat energy for improving the release of hot electrons. A cathode structure for a cathode ray tube.

In general, in a cathode ray tube, an electron gun is inserted into and fixed to a cathode ray tube neck. In an electron gun, three RGB electron beams deflect the electron beam in a predetermined direction while the external deflection magnetic field forms a magnetic field vertically or horizontally, and passes through a shadow mask hole. In this case, each electron beam collides with the RGB phosphor formed at one point and then formed on the screen inner surface to reproduce a predetermined image.

For large receiver cathode ray tubes, such as high-resolution cathode ray tubes and projection receivers, efforts have been made to improve the diameter of the electron beam and to increase the brightness of the screen as the size of the receiver increases. Characteristics also have a significant impact.

Referring to the cathode structure of a conventional cathode ray tube as described above in more detail with reference to FIG.

The sleeve 4 supported by the negative electrode support 2 receives the heater 6 therein, and a cap 8 is covered on the upper portion of the sleeve 4, and a thermoelectric emitter of carbonate is formed on the upper surface of the cap 4. 10) are stacked.

Meanwhile, the cathode support 2 is fixed by the holder 12, and the heater is also fixed to the heater cap 14, which in turn is fixed to the cathode support 16 and the heater support 18, and the lens support 20. In addition, it is embedded in the bead grass 22 on both sides.

In addition, as mentioned above, the leg 61 of the heater protrudes downward from the alumina insulating material and heats the carbonate through the cap 8 of the sleeve 4 as the heater 6 generates heat. 10) emits a predetermined hot electrons and when the hot electrons are emitted from the cathode, each electrode focuses and accelerates the hot electrons by a unique electron lens to form an electron beam having the predetermined speed.

In this conventional cathode structure, the heater 6 inserted into the sleeve 4 does not generate enough heat and is exposed outside the holder, causing a large amount of heat loss, that is, the heat of the heater is applied to the heater when power is applied to the heater. There is a problem in that the ignition characteristics of the screen are impaired due to instantaneous or partial divergence out of the holder without being concentrated by the carbonate in the cap direction.

This invention is designed to solve the disadvantages of the conventional cathode structure as described above, and to minimize the loss of heat outside the cathode holder in accordance with the heating of the heater, and to touch the surroundings when welding the heater leg portion, etc. It is an object of the present invention to provide a cathode structure for a cathode ray tube which significantly improves the screen ignition time when an electron beam radiated from a carbonate on a cap of a cathode reaches a screen by preventing a deformation of a heater.

In order to realize the above object of the present invention, a heater is installed in a tubular sleeve supported by a cathode ray tube at a lower portion thereof, and a cap is inserted into an opening of the upper portion thereof, while an electron-emitting material of carbonate is formed on the surface of the cap. In the stacked negative electrode structure, there is provided a cathode ray tube cathode structure, characterized in that the outer portion of the heater and the insulating material alumina coated and the subsequent bridge portion is inserted into the rod of the insulating material.

Hereinafter, with reference to the accompanying drawings a more preferred embodiment of the present invention is as follows.

FIG. 1 is a longitudinal sectional view showing a cathode structure of a cathode ray tube according to the present invention. In order to avoid duplication of description of the drawings, the same parts are given the same reference numerals as in the conventional drawings of FIG.

As shown in FIG. 1, the basic structure of the cathode ray tube cathode according to the present invention is substantially the same as that of the conventional one, and includes a cathode 6 supporting the sleeve 4 and a heater 6 inside the sleeve. ), The upper opening is capped with a cap (8), and the upper surface of the cap is laminated with an electron-emitting material (10) of carbonate.

Meanwhile, the cathode support 2 is fixed by the holter 12, and the heater is also fixed to the heater tab 14, which is in turn fixed to the cathode support 16 and the heater support 18, and the lens support 20. In addition, it is embedded in the bead grass 22 on both sides.

In such a cathode ray tube cathode, the heater 6 is located in a limited space on the inner surface of the sleeve 4 as shown in the figure, and a considerable length is exposed out of the holder. As a result, the heat loss during the heating of the heater 6 becomes large and the screen ignition time is delayed to about 12 seconds due to not being concentrated in the direction of the cathode cap. In addition, when the heater leg is welded to the heater tab, the touch is caused by welding. In order to prevent deformation from ash and further induce the above characteristics, a ceramic rod 7 having a length of about 2 mm in diameter and about 0.6 mm in diameter from the lower ceramic coding portion 62 of the heater to the lower portion of the heater leg 63 is used. Welded and welded to the heater support.

The position of the ceramic rod is more preferably such that its upper part is in contact with the welding portion of the cathode support 2 and the sleeve 4 and the lower part is in contact with the heater tab, which prevents the flow of the ceramic rod. In addition, it is possible to prevent the heater core wire touch during welding, which is more effective in avoiding thermal loss in its original form.

The cathode structure of the cathode ray tube according to the present invention is designed to greatly improve the screen emission characteristics from 12 to 8 seconds by concentrating the heater radiating heat in the direction of the cathode cap by preventing the external exposure of the heater leg to the maximum. Made it possible.

Claims (4)

The heater 6 is installed inside the sleeve 4 supported by the negative electrode support 2, the cap 8 is covered in the opening of the upper portion thereof, and the carbonate is electrospun on the surface of the cap 8. In the negative electrode structure in which the material 10 is laminated, the cathode ray tube is inserted into the rod 7 of the insulating material from the leg portion 61 of the heater to the lower portion 62 coated with the insulating material alumina. Cathode structure. The cathode structure of a cathode ray tube according to claim 1, wherein the insulating rod (7) is joined to a welding portion of the cathode support (2) and the sleeve (4). The cathode structure of claim 1, wherein the insulating rod (7) is coupled to and supported by a separate support means (71) inserted and fixed in the bead glass. The cathode structure according to claim 1, wherein the position of the insulation rod (7) is inserted from the welding surface of the cathode support (2) and the sleeve to the tab to which the leg is welded.