KR19990086206A - Electrode structure of electron gun for color CRT - Google Patents

Abstract

The present invention relates to an electrode structure of a color CRT electron gun, and more particularly, to reduce the overshoot amount by about 40% compared to the conventional method, and to greatly reduce the current deviation between the cathodes and the stabilization time of the initial screen. It is.

The present invention for this purpose is a color gun tube electron gun, the plurality of electrodes are supported by bead glass; A bead support interposed between a focus electrode (or a third electrode) 530 of the plurality of electrodes between the upper and lower electrodes 531 and 533 and the upper and lower electrodes and embedded in the bead glass 58 ( 532b is formed of the intermediate electrode 532 formed thereon.

Description

Electrode structure of electron gun for color CRT

The present invention relates to the field of color CRTs, and more particularly to the electrode structure of an electron gun for color CRTs.

In general, the color CRT forms an external shape of a bulb form by integrating a panel 1 and a funnel 2 having a neck 3 at the rear as shown in FIG. 1. In the neck portion 3, an electron gun 5 is embedded so that the electron beam 4 is radiated, and the electron beam radiated from the electron gun is disposed on the outer circumferential surface of the neck portion 3 of the funnel 2 in the horizontal and vertical directions. A deflection yoke 6 is provided to deflect, the frame 7 is supported by a plurality of leaf springs 8 inside the panel 1, and on the side of the funnel 2 of the frame 7. The screen 11 is formed so that an image is formed when the electron beam 4 radiated from the electron gun 5 collides, and the inner side of the funnel 2 and a part of the inner side of the neck portion 3 are subjected to a high pressure electron gun. A graphite film (not shown) is successively applied so as to be applied to (5).

Therefore, when power is applied to the cathode of the electron gun 5 and the electron beam 4 is generated, the generated electron beam is accelerated and focused while passing through the acceleration electrode and the focusing electrode in turn, and is then deflected by the deflection coil. About 20% of the total passes through the shadow mask 10, and the remaining about 80% of the electron beams are converted into thermal energy while impinging on the inner surface of the shadow mask 10.

The 20% electron beam 4 passing through the shadow mask 10 collides with the screen 11 applied on the inner surface of the panel 1 to emit phosphors, thereby reproducing an image.

Meanwhile, although the number of electrodes constituting the electron gun 5 varies depending on the product, a cathode for generating hot electrons, a control electrode for controlling hot electrons generated from the cathode, and a hot electron through the control electrode It is essentially equipped with an acceleration electrode for pulling out and accelerating, and a focusing electrode for collecting hot electrons.

FIG. 2 illustrates an example of the electron gun as described above. The electrode structure of the electron gun includes a cathode support 50 for supporting the cathode, a first electrode 51 for controlling the electron beam size of the cathode, and an electron beam to accelerate the electron gun. The second and fourth electrodes 52 and 54, the third, fifth and sixth electrodes 53 and 55 and 56 for focusing the electron beam, and the anode electrode 57 to which high pressure is applied. The electrodes are fused in-line by the beadgrass 58.

On the other hand, when the conventional color CRT is operated, the screen characteristics become unstable due to the change of the cathode current for the first few minutes. At this time, the greater the amount of change in the cathode current, the more white balance (red, green, The balance of the size and brightness of the blue three colors appears badly, and a clean image is not realized.

Factors that prevent such a white balance is first, the connector 59 and the bead glass 58 connecting each electrode, the thermal expansion of the negative electrode, the structure and material of the negative electrode support (2).

However, experimental results have shown that the focus electrode has a large effect on white balance among unknown causes.

3 and 4 are perspective views showing a state in which a conventional focus electrode (third electrode) which is influencing the white balance characteristic as described above and a coupling state diagram thereof, and the conventional third electrode 53 is an upper electrode 53a. ) And the lower electrode 53b, and have a structure in which these are integrated by welding.

In particular, bead supports 53a 'and 53b' are formed on the peripheral surfaces of the upper electrode 53a and the lower electrode 53b to be embedded in the bead glass 58, respectively.

In the third electrode 53 structure as described above, the portions that adversely affect the white balance characteristics are formed on the upper and lower electrodes 53a and 53b, so that the bead supports 53a 'and 53b' are formed. It was found to be inferior in the embedding ability to), and to use a material having a high coefficient of thermal expansion.

As a result of the operation, the overshoot amount of the electron gun is relatively large (about 160%), the current deviation between the cathodes is large, and the stabilization time of the initial screen is slow.

The present invention has been made to solve the above-mentioned conventional problems, the object is to improve the white balance characteristics of the cathode ray tube.

The present invention for this purpose is a color gun tube electron gun, the plurality of electrodes are supported by bead glass; Among the plurality of electrodes, a focus electrode (or a third electrode) is formed of an intermediate electrode formed between an upper / lower electrode and the upper / lower electrode and a bead support embedded in the bead glass. It is to provide an electrode structure of the electron gun.

1 is a side cross-sectional view showing an example of a general color CRT

2 is a front view showing an example of an electron gun;

3 is an exploded perspective view of a conventional focus electrode (third electrode)

4 is a coupled state of FIG.

5 is an exploded perspective view of the focus electrode (third electrode) of the present invention;

6 is a combined state of FIG.

7 is a graph comparing the amount of overshoot between the conventional third electrode and the third electrode of the present invention.

Explanation of symbols for main parts of the drawings

530: third electrode 531: upper electrode

532: intermediate electrode 533: lower electrode

532b: Bead Support

Hereinafter, the focus electrode structure of the present invention will be described in detail with reference to FIGS. 5 to 6 as follows.

FIG. 5 is an exploded perspective view of the focus electrode (third electrode) of the present invention, and FIG. 6 is a coupled state diagram of FIG. 5.

The focus electrode (hereinafter referred to as a “third electrode”) 530 of the present invention is an intermediate electrode positioned between the upper electrode 531, the lower electrode 533, and the upper / lower electrodes as shown in FIG. 5. It is divided into three parts of 532), and when installed, it is integrated by welding as shown in FIG.

In the above, the upper electrode 531 has a simple flat plate shape in which a beam passage hole 531a is formed in the center portion, the thickness t is 0.7 mm, and the material is made of stainless steel (S12S1).

The lower electrode 533 has the same structure as that of the related art (with the same thickness), and has a form of removing the bead support, and also has a beam through hole 533a formed at the center thereof, and the material is the same as that of the upper electrode 531. It is made of stainless steel (S12S1).

The intermediate electrode 532 positioned between the upper electrode 531 and the lower electrode 533 is a newly added part of the present invention. A beam passage hole 532a is formed at the center of the upper electrode 531 and the lower electrode 533. A thin bead support 532b is formed in 58 so as to be well embedded.

The thickness of the intermediate electrode 532 is 0.5mm, and the material is made of stainless steel (I106S), which is a low thermal expansion material, to minimize the amount of thermal change.

Therefore, the third electrode 530 of the present invention is characterized in that the overall thickness of the third electrode to the same thickness as the existing third electrode 53, wherein the lower electrode 533 is the same as the existing lower electrode 53b The thickness of the upper electrode 531 and the intermediate electrode 532 is the same as that of the existing upper electrode 53a.

In addition, the intermediate electrode 532 is made of a material having a low thermal expansion rate, and is formed to a minimum thickness that can be supported by the bead glass 58, thereby improving the embedding of the bead glass 58 by making the thickness thin.

Accordingly, the coupling force between the third electrode 530 and the bead glass 58 is increased to cope with the deformation even in the portion of the bead glass 58 supporting the third electrode 530 due to the current transient. .

FIG. 7 is a graph comparing the amount of overshoot between the conventional third electrode and the third electrode of the present invention, and compared to the structure of the conventional third electrode 53 by applying the third electrode 530 of the present invention. It can be seen that the chute amount has a damping effect of about 40%.

By applying the third electrode (focus electrode) of the present invention as described above, the amount of overshoot can be reduced by about 40% as well as the amount of current deviation between the cathodes.

In addition, it is possible to obtain the effect of greatly shortening the settling time of the initial screen.

Claims (4)

An electron gun for a color CRT tube, in which a plurality of electrodes are supported by bead glass; Among the plurality of electrodes, a focus electrode (or a third electrode) is formed of an intermediate electrode formed between an upper / lower electrode and the upper / lower electrode and a bead support embedded in the bead glass. Electrode structure of electron gun. The method of claim 1, Electrode structure of electron gun for color CRT tube, characterized in that the thickness of the intermediate electrode is thinner than the upper electrode. The method of claim 2, The thickness of the upper electrode is 0.7mm, the thickness of the intermediate electrode is 0.5mm electrode structure of the electron gun for color tube. The method of claim 1, The electrode structure of the electron gun for a color CRT tube, characterized in that the intermediate electrode is made of a material having a lower coefficient of thermal expansion than the upper and lower electrodes.