KR910004062Y1 - Electron gun of color cathode ray tube - Google Patents

Abstract

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Description

Electron gun for color cathode ray tube

1 is a schematic cross-sectional view of a conventional inline electron gun having a double main lens.

2 is an exploded perspective view of an electrode forming a main lens system in the electron gun shown in FIG. 1;

3 is an exploded perspective view of the electrode of the main lens system according to the present invention.

4 is a cross-sectional view of the coupling state of the main lens system electrode according to the present invention.

5 is a partial cross-sectional view of the bonding state of the electrode of another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

FG: main focus electrode FG ': auxiliary electrode of main focus electrode

AG: Final acceleration electrode AG ': Auxiliary electrode of final acceleration electrode

Fa, Fb: flange of electrode FE: protrusion

FH, FH ': Through hole

The present invention relates to an electron gun for a color cathode ray tube having a composite main lens. In particular, the structure of the main focus electrode and the final acceleration electrode constituting the composite main lens is improved to improve the assembly accuracy of the electrode and between the focus electrode and the final acceleration electrode. It relates to being able to prevent the discharge.

In general, in order to reduce spherical aberration of the electron beam in the main lens, a large diameter of the beam through hole is attempted. In addition, in recent years, spherical aberration forming a low magnification composite lens has been further reduced.

That is, as shown in FIGS. 1 and 2, a large-diameter transverse beam passing hole FA FA is applied to the main focus electrode FG constituting the main lens system or the final acceleration electrode AG facing the main lens system. The auxiliary electrode FG '(AG') is provided in the inside with the small diameter beam passing hole HR (HG) (HB).

This is to form a double electric field with large and small beam through holes so that the two low magnification main lenses are overlapped with each other and thus have a significant effect on the improvement of beam spherical aberration.

However, as the number of parts increases, the number of parts processing is increased, and a more serious problem is that the assembly precision between parts decreases. In particular, in the case of the electron gun having the composite main lens, the relative position between the main electrode (main focus electrode or the final acceleration electrode) and the auxiliary electrode must be set correctly. As shown in FIG. 1, the main lens focus electrode and the final acceleration electrode are shown in FIG. A gap of a certain interval is generated between the auxiliary electrode and the main electrode installed in the inside of the auxiliary electrode and is biased to one side of the auxiliary electrode. Therefore, the beam through hole of the auxiliary electrode to be coaxial is eccentric with respect to the beam through hole of the main electrode.

This causes a serious problem in the control of the electronic load and needs to be structurally improved. In addition, as shown, since the beam through hole of the main lens is simply biased, fine residual chips remain at the edge thereof, that is, the fracture surface. This distorts the electric field, which adversely affects the electron beam, causing complex problems such as weighting of spherical aberration, distortion of beam spot, miss landing, and variation of static convergence.

The object of the present invention is to provide an electron gun for a color cathode ray tube that can improve the above problems.

In order to achieve the above object, the present invention is to form a flange similar to the flange of the main electrode on the edge of the auxiliary electrode embedded in the main electrode (main focus electrode or the final acceleration electrode) constituting the composite main lens system, Means are provided for setting the relative positions of the main electrode and the auxiliary electrode, and additionally, a burring portion is formed at the edge of the beam passing hole of the main electrode.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. As shown in FIG. 3, a horizontal beam passing hole is formed in the beam passing plane P of the cup-shaped main electrode FG (main focus electrode FG and the final acceleration electrode) AG on which the flange FL is formed. (FH) (AH) is formed, and the bearing part BP toward the electrode inner side is formed in the edge. In addition, three beam through holes HR (HG) (HB) are formed in the auxiliary electrodes HG 'and AG' embedded therein, and unlike the conventional auxiliary electrodes, Similarly, flange FL AL is formed. In addition, male and female through holes FO and protrusions FT are formed to correspond to each other in the flanges FL 'AL of the main electrode HG AG and the auxiliary electrode FG'.

The main electrode (FG) AG and the auxiliary electrode (FG ') (AG') is in close contact as shown in Figure 4, the relative of each other by the projections (FT) and the through (FO) of the male and female The position is firmly maintained.

That is, regardless of the gap GAP between the main electrode and the auxiliary electrode, the protrusion ET and the through hole FO are precisely set.

Therefore, the alignment of the beam through hole is easy, and as a result, the assembly work is very simple. On the other hand, the electrode setting means by the projections FT and the through holes FO of the male and female can be replaced by simply facing through holes FO as shown in FIG. In the joining operation, it is possible to join the electrode with the desired precision by welding after setting the relative position by inserting the guide rod to guide it.

On the other hand, since the boundary surface constituting the electric field is smoothed by the bearing portion of the main electrode, the electric field is not distorted by the remaining chips at the edge portion as in the prior art. That is, by forming a bearing around the beam trajectory to surround the path through which the beam passes, the fracture surface where the residual chip remains is not exposed to the beam path.

According to the present invention, the assembling precision of the main electrode having the common large-diameter beam through hole and the auxiliary electrode having the independent small-diameter beam through hole is constant for all the products, and the residual chip of the electric field around the beam through hole As the distortion of the electric field and the room for self-discharge are removed, the performance of the electron gun and the stability of the reliability are expected.

Claims (3)

A flange (Fa) is formed at the edge of the body and has a cup-shaped main electrode (FG) having a large diameter horizontal common beam passing hole (HHa) on the beam passing hole plane, and embedded therein, a small diameter independent beam passing hole ( A cup type auxiliary electrode Fa 'having HR (HG) (HB) is provided, and a flange Fb facing the flange Fa of the main electrode is formed at an edge of the auxiliary electrode FG'. And a means for setting the relative positions of the main electrode and the auxiliary electrode on the flanges of the main electrode and the auxiliary electrode. The method of claim 1, wherein as a means for setting the relative position of the main electrode and the auxiliary electrode, each of the protrusions (FE) and the through hole (FH) facing each other are formed in each of the flanges (Fa) (Fb) Electron gun for color cathode ray tube to say. 2. The electrode assembly as claimed in claim 1, wherein through holes FH 'and FH' are formed to face each other at each of the flanges Fa and Fb as means for setting the relative positions of the main electrode and the auxiliary electrode. Electron gun for a color cathode ray tube, characterized in that the guide rod for assembly in the through-hole to set the relative position.