KR970006038B1 - Electrode structure of electron gun for crt - Google Patents

Abstract

An electrode of an electron gun for CRT(Cathode Ray Tube) is described that varies the distance between the correction electrodes of R, G and G in order to reduce the difference of spot size around a screen, and thereby increase the resolution of the screen. The fifth electrode of the electron gun is separated by a front electrode and rear electrode. A hole is formed at a predetermined position of the rear electrode, and a rear correction electrode is installed such that its center part can differ from its side parts. The center part of the front electrode is flat and the side parts thereof are sloped. A front correction has a hole through which a light beam pass. Thereby, it is possible to reduce the difference of spot size around the screen, and thus increase the resolution of the screen.

Description

Electrode structure of electron gun for cathode ray tube

1 is a front view of a conventional electron gun.

2 (a), (b), (c), and (d) the beam shape by the quadrupole magnetic lens component.

3A is a cross-sectional view of a state in which a conventional correction electrode is installed on a fifth electrode.

(b) is a perspective view of a conventional correction electrode.

Figure 4 (a) is a spot phenomenon in the periphery of the conventional screen.

(b) is a spot phenomenon in the periphery of the screen according to the present invention.

5 is a cross-sectional view of an electron gun provided with a correction electrode of the present invention.

6 is a perspective view of the correction electrode of the present invention.

7 is a bottom view of the correction electrode of the present invention.

* Explanation of symbols for main parts of the drawings

1 to 6: electrode 7: cathode

8: Bead glass 9: Space connector

10 electrode assembly 11 shielding cup

12 core 13: halo

14: shear correction electrode 15,15 ': through hole

16: inclined portion 17: rear end correction electrode

5a: front electrode 5b: rear electrode

The present invention relates to an electrode structure of an electron gun for a cathode ray tube, and more particularly, to reduce the difference in the spot size around the screen to a minimum by changing the correction electrode distance between red (R), green (G), and blue (B). The effect of increasing the resolution and the assembly quality of the calibration electrode is increased to achieve the effect of saving labor.

In general, the electron gun for the color cathode ray tube arranges a plurality of electrodes (1-6) for accelerating and controlling the electron beam in front of the cathode (7), and then the plurality of electrodes (1-6). The bead glass 8 is fused to the outside to form the electrode assembly 10, the shielding cup 11 is welded to the open side of the sixth electrode 6, and then the neck of the cathode ray tube of the electrode assembly 10 is formed. A bulb space connector 9 for fixing is welded to the open side of the shielding cup 11.

The electron gun of the prior art configured as described above is installed and enclosed in the neck portion of the color cathode ray tube to emit hot electrons by heating the heater, and the hot electrons once emitted are accelerated by the voltage applied to the second electrode 2 to form an electron beam. do.

The electron beam is gradually accelerated after passing through the second electrode 2 arranged in front of the first electrode 1, and then is electrostatic focusing lens between the third, fourth, fifth and sixth electrodes 3 to 6. As it passes through, it is focused narrowly toward the front screen.

In order to reproduce the image by reaching the screen with the focused electron beam, the deflection magnetic field generated by the deflection yoke installed on the outside of the cathode ray tube must be deflected to scan the entire screen by deflecting the traveling path of the focused electron beam. A plurality of electron beams emit a plurality of pigments on the color cathode ray tube screen to reproduce an accurate image with a combination of these colors. A plurality of electron beams are concentrated on one screen, and the beam spot reaching the screen forms a power source. To get it.

The electron gun for the color cathode ray tube emits a plurality of electron beams horizontally in-line, and the self-deflection magnetic field of the deflection yoke is formed in a non-uniform magnetic field differently in the tubular region and the peripheral region of the color receiving tube. The self-convergence method is adopted. In the case of such a non-uniform magnetic field, there is an advantage that the plurality of electron beams are automatically focused in one place on the screen only by scanning the plurality of electron beams into the deflected magnetic field. As shown in the figure, the quadrupole magnetic lens component is present in the non-uniform magnetic field, and the quadrupole magnetic lens component acts on the electron beam to deform the cross-sectional shape of the electron beam into a horizontal shape.

Therefore, on the screen of the color cathode ray tube, it is divided into a core (12) portion having a high electron density and a halo (13) portion having a low electron density. This phenomenon is affected by a non-uniform magnetic field. The distance between the focal point of the color cathode ray tube, that is, the focal point of the electrostatic focusing lens of the electron gun and the color cathode ray tube screen is increased at the periphery of the screen, so that the halo of the beam spot reaching the periphery of the screen is increased. 13) is more severe.

In addition, as shown in FIG. 2 (d), the beam spot of the center portion of the screen which is not affected by the deflection magnetic field is formed only of the core 12 having a power shape, but the beam spot of the periphery of the screen that is deflected in the horizontal and vertical directions is horizontal. The long core 12 and the halo 13 having a low electron density appear to be separated.

Therefore, in the conventional electron gun for color cathode ray tubes, as described above, beam spots affected by astigmatism and focal length difference due to non-uniform magnetic field are generated, and thus, good image quality characteristics cannot be obtained. In order to solve this problem, a method of distorting the electron beam in the longitudinal form has been proposed by forming an asymmetric lens system between the first electrode and the second electrode before the electron beam emitted from the cathode reaches the electrostatic focusing lens. By correcting astigmatism due to non-uniform magnetic field, the beam spot at the periphery of the screen is improved. On the contrary, the beam spot is greatly increased at the center of the screen, thereby deteriorating image quality characteristics.

The present invention is made to solve the problems of the prior art as described above by reducing the difference in the spot size around the screen by changing the correction electrode distance between red (R), green (G), blue (B) to the minimum It is an object of the present invention to provide an electrode structure of a cathode ray tube electron gun capable of increasing the resolution of a peripheral portion.

When the present invention for achieving this purpose will be described in detail according to the accompanying drawings of the embodiments as follows.

As shown in FIGS. 5, 6, and 7, a plurality of electrodes 1 to 6 are formed to accelerate and control the electron beam emitted from the cathode 7, and the electron beam is accelerated to each of the electrodes 1 to 6. In a cathode ray tube electron gun which focuses to form a beam spot on a screen of a cathode ray tube, the fifth electrode 5 is separated and divided into a front electrode 5a and a rear electrode 5b and an electron beam on the front electrode 5a. A plurality of quadrangular through holes 15 and a plate-shaped front end correction electrode 14 having slopes 16 formed therein are provided, and through holes 15 of the front end correction electrode 14 are also provided at the rear end electrode 5b. ), The through hole 15 'is formed to face the center hole G, and the height of the central hole G is high (H ₂ ) and the rear end correction electrode 17 formed to be inclined at the ends (height: H ₁ ) of both side holes (RB) is formed. It is installed and configured.

The central hole 15 (G) is formed in the flat plate and the side holes 15 (R) and (B) are formed in the inclined plate in the front end correction electrode 14. Since the distance between the correction electrodes 14 and 17 is opposite to the distance between the side holes, the distance between the correction electrodes 14 and 17 is greater than that of the side holes. Distance from the beam passing hole 15 'is increased.

The shape of the front and rear correction electrodes 14 and 17 may be any shape, such as a semicircle or a bend, as long as it can be provided in the fifth electrode 5.

Referring to the effects of the present invention configured as described above are as follows.

As shown in FIG. 5, the variable voltage vfd is applied to the rear electrode 5b and the third electrode 3 from which the fifth electrode 5 is separated, and the focusing voltage vfs is applied to the front electrode 5a. By being applied, the equipotential distribution around the through holes 15 and 15 'through which the electron beam passes is formed in the direction of the arrow as shown in FIG. 7, wherein when the voltage V _fs ? V _fd is applied, the electron beam is vertical The electron beam subjected to the electrostatic quadrupole lens action is formed in an elongated shape immediately before the incidence of the electrostatic focusing lens, because it is divergent in the direction and focusing in the horizontal direction. Due to the influence of the distance (ℓ, ℓ ') and the height difference (H ₂ , H ₁ ), the electric field shape in FIG. 7 is the center hole (green (G) and guide hole (red (R), blue (B)). ), And the electron beams incident through the front and rear correction electrodes 14 and 17 have uniform beam spots of red (R), green (G), and blue (B). It is possible to increase the resolution of the periphery of the screen by allowing it to be displayed.

In addition, as shown in FIG. 5, the shear correction electrode 14 is welded to the shear electrode 5a to be different from the conventional welding method shown in FIG. Quality could also be improved.

As described above, the present invention is a very useful inventor to increase the resolution of the screen periphery by minimizing the difference in spot size around the screen by varying the distance of correction electrodes between red (R), green (G), and blue (B). will be.

Claims (2)

The fifth electrode of the electron gun is separated into a front end electrode and a rear end electrode, a through hole is formed at a predetermined position of the rear electrode, and a rear end correction electrode having a height different from a height of a center part and a side part is provided, and a center of the front electrode The electrode structure of the cathode ray tube electron gun, characterized in that the front surface is formed in the plane, both side portions are formed in the inclined plane, the shear correction electrode is formed to form a beam through hole, respectively. The electrode structure of an electron gun for a cathode ray tube according to claim 1, wherein the beam passage hole formed in said shear correction electrode is quadrangular.