KR900001050B1 - Electron gun of crt - Google Patents

Abstract

The electron gun for converging the 3 way electron beams uniformly on the screen includes 4 electrodes (12-15) placed at the front of a cathode (11), and an auxiliary electrode placed between the third (14) and forth (15) electrodes. The auxiliary electrode has three electron beam holes (21A-C) of which central hole (21B) is longer than the other holes (21A,21C) so that deflection field generated around the holes become uniform and the electron beams passed through the holes are converged at a certain spot of the screen.

Description

Electron gun for cathode ray tube

1 is a schematic view showing a typical cathode ray tube.

2 is a cross-sectional view showing a conventional electron gun.

3 is an explanatory diagram showing a spot of an electron beam by a conventional electron gun.

4 is a cross-sectional view showing an electron gun of the present invention.

5 is a perspective view of an auxiliary electrode used in the electron gun of the present invention.

6A and 6B are waveform diagrams showing the relationship between the deflection current and the voltage applied to the auxiliary electrode of the electron gun of the present invention.

7 is an explanatory diagram for explaining the focusing action by the electron gun of the present invention.

* Explanation of symbols for main parts of the drawings

11: cathode 12-15: first-fourth electrode

21: auxiliary electrode 21A-21C: electron beam through hole

The present invention relates to an electron gun for a negative ray tube installed in the neck portion of the cathode ray tube to emit an electron beam to the front screen, and more particularly to a cathode ray tube electron gun to focus the electron beam in the center and the electron beam on both sides uniformly.

In general, the resolution of an image of a cathode ray tube depends on the beam spot formed on the screen, that is, the size and shape of the bright spot. In order to obtain a high resolution, the beam spot should be as small as possible and free from distortion. The beam spot should be as circular as possible at any position on the screen.

When such a cathode ray tube is explained with reference to FIG. 1, the electron gun 4 which projects three electron beams 2 to the screen 3 is fixed to the neck part 1A of the glass tube 1, and the neck part ( A deflection yoke 5 for deflecting the electron beam 2 is fixed outside the 1A.

In constructing the electron gun used for such a cathode ray tube, the first to fourth electrodes 12-15 are arranged in a row in front of the cathode 11 and fixed as shown in FIG. have.

In such a cathode ray tube, the deflection yoke 5 generates vertical and horizontal deflection magnetic fields to selfconverge the electron beam 2 on the screen 3, and the vertical deflection magnetic field is distributed in a pin-ku shape. However, the horizontal deflection field is a barrel-shaped magnetic field distribution.

The spot of the electron beam 2 of the conventional electron gun deflected by such a deflection yoke 5 is formed as a power source in the center of the screen 3, as shown in FIG. The core 2A and halo are generated to reduce the resolution of the peripheral portion, and the divergence angle θ of the electron beam 2 incident on the main lens 17 is reduced to reduce such deflection distortion. It should be made as small as possible in the range which does not enlarge the electron beam 2 on (3).

For this reason, the pre-locus lens 16 formed on the opposite side of the second electrode 13 and the third electrode 14 is set to an optimum condition, that is, for example, the second electrode 13 and the third electrode ( It is necessary to appropriately set the interval between the portions 14 and the thickness of the electron beam through hole 13 'of the second electrode 13.

However, in order to improve the spot characteristic of the periphery of the screen 3, even if the through hole 13 'of the second electrode 13 is thickened or the gap between the second electrode 13 and the third electrode 14 is optimized. Due to the limitation, when the electron beam 2 is focused on the screen 3, the spot of the electron beam 2 around the screen 3 is improved in the vertical direction, but a phenomenon occurs that increases in the horizontal direction.

For example, when the focus lens 16 is made strong, the divergence angle θ becomes small, and it is possible to remove the halo 2B occurring around the spot at the periphery of the screen 3, but on the contrary, the focus lens Since 16 is strong and the virtual indeterminate becomes large when viewed from the main lens 17, the spot on the screen 3 is enlarged. In addition, since the two electron beams 2 on the both sides arranged inline and the electron beam 2 on the center have different degrees of deflection distortion, the spots of the two electron beams 2 on both sides have very high distortion at the corners of the screen 3. Larger, more focused astigmatism occurs around the spot, so the degree of focusing becomes worse, and the electron beam 2 in the center passes through the center of the deflection field distribution so that the deflection distortion is less likely to be applied to the electron beam 2 on both sides. In comparison, the spot shape at the corners of the screen 3 is close to the power source, and the back light 2B is also reduced.

That is, the conventional electron gun cannot form a spot close to the power source at the periphery of the screen 3, and cannot affect the deflection field effects of the two electron beams 2 on the two sides and the electron beam 2 on the center equally. There was a defect that the resolution was lowered.

SUMMARY OF THE INVENTION In view of the above conventional deficiencies, the present invention was devised to improve the resolution of an image by equalizing the deflection field of the electron beam in the center and the two electron beams on both sides, which will be described in detail with reference to the accompanying drawings. . As shown in FIG. 4, in the electron beam gun for the cathode ray tube having the first to fourth electrodes 12-15 arranged in a row in front of the cathode 11, the third electrode 14 and the fourth electrode 15 are disposed. A secondary electrode 21 in which the longitudinal electron beam through-holes 21A, 21B and 21C are punctured is installed between the two sides. However, as shown in FIG. It is formed longer than the through-holes 21A and 21C. In the above, the auxiliary electrode 21 is applied with a voltage that varies according to the deflection current based on the voltage divided by ½ by adding the voltages applied to the third and fourth electrodes 14 and 15, that is, (a) of FIG. According to the deflection current shown in Fig. 6B, the variable voltage shown by the solid line or the silver line is applied.

According to the present invention as described above, the main lens 17 formed by the third electrode 14, the auxiliary electrode 21, and the fourth electrode 15 has a rectangular electron beam through hole 21A- formed in the auxiliary electrode 21. 21C) to form an axial asymmetric lens so that the electron beams 2 are asymmetrically focused.

At this time, when the electron beam through holes 21A to 21C of the auxiliary electrode 21 are all rectangular in the same length, the three electron beams 2 are strong in the horizontal direction and weakly focused in the vertical direction.

Referring to FIG. 7, since the electron beam 2 passing through the main lens 17 ′ is strong in the horizontal direction and weakly focused in the vertical direction, the focal point P _{1 in the} vertical direction is horizontal. It is formed farther than the focal point P _{2 in the} direction, and this phenomenon cancels the weak focus in the horizontal direction and the strong focus in the vertical direction in the deflection magnetic field.

Further, the electron beam through hole 21B in the center of the auxiliary electrode 21 is longer in the vertical direction than the electron beam through holes 21A and 21C on both sides, so that the electron beam 2 is concentrated more strongly than both sides. The electron beam 2 of the electron beam 2 and the electron beam 2 on both sides become substantially the same, and therefore the spot of the electron beam 2 deflected very strongly in the horizontal direction is also formed almost close to the circle.

As described in detail above, the present invention allows the spot of the electron beam to be formed as a power source over the entire screen, thereby improving the resolution of the image.

Claims (1)

The first to fourth electrodes 12-15 are arranged in a row in front of the cathode 11, and the third and fourth electrodes 14 and 15 are vertically long rectangular electron beam through holes 21A to 21C. In the cathode ray tube electron gun provided with the auxiliary electrode 21 formed thereon, wherein the electron beam through hole 21B in the center of the auxiliary electrode 21 is formed longer than the electron beam through holes 21A and 21C on both sides. Electron gun for cathode ray tube.

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