KR0131451Y1 - Electronic gun for color cathode tube - Google Patents

Abstract

The present invention relates to an electron gun for a color cathode ray tube. In particular, the manufacturing cost is reduced by eliminating the correction electrode and the guide electrode, and the elliptic extension electrode is fused and fixed to the bead glass. In order to effectively expand the aperture, an elliptic extension electrode is formed in which three elliptic openings are formed at the upper and lower electrode connections of the first acceleration and focus electrode to form the main lens together with the second acceleration and focus electrode. The side hole of the elliptic opening is provided with a shape combining two ellipses of different radius.

Description

Electron gun for color cathode ray tube

1 is a cross-sectional view of a conventional electron gun.

2 is an internal configuration diagram of a main lens unit of a conventional electron gun.

3 is a perspective view of a conventional elliptic extension electrode.

4 is a structural diagram of a conventional guide electrode.

5 is a cross-sectional view of the electron gun to which the present invention is applied.

6 is a configuration diagram of the elliptic extension electrode of the present invention.

7 is a beam spot shape formed on a screen by astigmatism.

8 is an electron beam connection diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

100: first elliptic extension electrode 100 ': bead supporter

100 '': Side hole 103: Heater

104: cathode 105: first grid electrode (control electrode)

106: second grid electrode (acceleration electrode) 108: first acceleration and focusing electrode

109: second acceleration and focusing electrode 110: bead glass

113: second elliptic extension electrode 114: shield cup

The present invention relates to an electron gun for a color cathode ray tube, and more particularly, to an electron gun structure for improving focusing and astigmatism and effectively expanding a lens diameter without separately providing a correction electrode and a guide electrode.

In general, the electron gun used for color water pipes is arranged with a plurality of grid electrodes provided with electron beam through-holes through which three electron beams pass in-line on the same plane. A heater support 1 for supporting a heater 3 for generating heat, a cathode 4 for emitting hot electrons by the heat generation of the heater 3, and a cathode support 2 for supporting the cathode 4. ), First and second grid electrodes 5 and 6 and first and second acceleration and focus electrodes 8 and 9 sequentially arranged in front of the quaternary cathode 4, and beads for supporting the electrodes on both sides. It is composed of a glass 10, the shield cup 14 is disposed in front of the third electrode (7).

The main lens through which the electron beam passes is formed by the potential difference between the first acceleration and focusing electrode 8 and the second acceleration and focusing electrode 9 of the conventional electron gun configured as described above. Since the main lens has a stronger influence on the vertical focusing / acceleration field than the horizontal focusing / acceleration field, the shape of the three electron beams after passing through the main lens shows a horizontal phenomenon in which the horizontal length is longer than the vertical. A beam spot with a low current was obtained, which lowered the resolution of the color cathode ray tube.

To improve this, as shown in FIG. 2, a guide electrode 11 through which three electron beams pass is formed at the rear end of the first acceleration and focusing electrode 8, and the center of the electrode rims 8 'and 9' is spaced at a predetermined distance. The ball has elliptical openings, and the side holes on both sides have elliptic openings cut in half, thereby eliminating the elliptic extension electrodes 12 and 13 in which the outer circumferential walls are removed from the left and right ends, thereby compensating for the lateralization of the electron beam.

When the characteristic satisfaction is not achieved due to the oval opening, a pair of shade-shaped correction electrodes 15 are added to the lower end of the shield cup 14 in parallel with the arrangement direction of the electron beam.

The main lens structure described above can obtain the focusing force (hereinafter, referred to as positive convergence, STC) of the side beam itself to the center beam, which is an important feature for the side beam by the retreat of the elliptic extension electrodes 12 and 13.

However, the conventional electron gun for color cathode ray tubes emits a plurality of electron beams horizontally inline, and the so-called 'self-convergence' in which the strength of the 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 receiver tube. (Self-convergence) method is adopted. In the case of such non-uniform magnetic field, there is an advantage that the multiple electron beams are automatically focused in one place on the screen only by scanning the plurality of electron beams into the deflected magnetic field. Since the quadrupole magnetic lens component is present, the quadrupole magnetic lens component acts on the electron beam and transforms the cross-sectional shape of the electron beam into a horizontal shape, so that the core portion having a high electron density and the electron density of the horizontal electron beam is formed on the screen of the color cathode ray tube. Is divided into lower Halo parts.

This phenomenon is more prominent in the periphery of the screen, which is heavily influenced by non-uniform magnetic fields. Furthermore, the focal length difference of the color cathode ray tube, that is, the distance between the focal point of the electrostatic lens of the electron gun and the color cathode ray tube screen is increased at the periphery of the screen. The halo of the beam spot reaching the periphery of the screen is even worse.

That is, as shown in FIG. 7, the beam spot of the center portion of the screen which is not affected by the deflection magnetic field is formed of only a core of a circular shape, but the beam shaft of the periphery of the screen that is horizontally and vertically flattened is horizontal. The core and the electron density are separated into halo of low density.

Therefore, the conventional electron gun has a problem that it is difficult to obtain good image quality characteristics because the beam spot is affected by the astigmatism and the focal length difference caused by the non-uniform magnetic field.

The present invention eliminates the guide electrode installed in the first acceleration and focusing electrode and the correction electrode installed in the shield cup, and forms three circular holes between the upper and lower electrodes of the first acceleration and focusing electrode. By providing the formed elliptic extension electrode, the side beam and the center beam pass through the main lens to eliminate the focusing force difference in the horizontal direction and the vertical direction of the main lens in a state that satisfies the STC at the center of the screen.

The invention is described in detail below with reference to FIGS. 5 and 6.

First of all, the structure supports a heater support 101 for supporting a heater 102 that generates heat by receiving power, a cathode 104 that emits hot electrons by heat generation of the heater 102, and supports the cathode 104. The cathode support 102, the first and second grid electrodes 105 and 106 and the first and second acceleration and focus electrodes 108 and 109 sequentially arranged in front of the cathode 104, and supporting the electrodes from both sides. In the electron gun structure in which the bead glass 110 and the shield cup 114 is disposed in front of the third electrode 107, the upper electrode (a) and the lower electrode of the first acceleration and focusing electrode 108 A first elliptic extension electrode 100 having three elliptical holes formed between the electrodes b was provided.

In addition, the bead support 100 ′ having a round protrusion shape embedded in the bead glass 110 was formed at both sides so that the first elliptic extension electrode 100 was fused and fixed to the bead glass 110. 100 '') is formed in the shape of a combination of two ellipses with the central elliptical radius (d) smaller than the outer ellipse radius (d ') around the vertical axis.

Reference numeral 113 in the drawing denotes a second elliptic extension electrode.

In this configuration, when the electron gun is operated, the main lens is formed by the first acceleration and focusing electrode 108 and the second acceleration and focusing electrode 109. As shown in FIG. ) And the central beam B pass through the main lens to satisfy the STC at the center of the screen, thereby eliminating the difference in focusing power in the horizontal and vertical directions of the main lens.

The STC and astigmatism vary greatly due to the horizontal dimension of the elliptic extension electrode 100. In order to satisfy the STC ± 2mm and the astigmatism ± 200V on the screen, H ₁ = H ₂ = 0.4 to 0.6 When a, H = 0.2 ~ 0.4a, and a = 8mm, it was satisfied.

FIG. 8 is a diagram showing the process of electron beam escaping from the electron gun adopting the main lens according to the present invention, focusing on one point of the screen, where STC is + 0.1mm and astigmatism is + 100V. Could get.

As described above, the present invention reduces manufacturing costs by eliminating correction electrodes and guide electrodes, and improves STC and astigmatism of the electron beam and improves lens diameter effectively in the state of assembling by improving fusion of ellipse extension electrodes to bead glass. It is designed to be extensible.

Claims (4)

The first and second acceleration and focusing electrodes common to the three electron beams generated from the cathode and forming the main lens, and the central hole has an elliptical opening at a predetermined distance from the rim of the second acceleration and focusing electrode, and both side holes are elliptical. In the electron gun structure provided with the second ellipsoidal extension electrode in which the opening is cut in half and the portions in contact with the outer circumferential wall of the left and right ends are removed, three elliptic openings are formed in the upper electrode and the lower electrode connection of the first acceleration and focusing electrode. An electron gun for a color cathode ray tube, characterized by comprising a first elliptic extension electrode. The electron gun for a color cathode ray tube according to claim 1, wherein the elliptic opening formed in said first elliptic extension electrode is formed such that a width in a vertical direction is larger than a width in a horizontal direction. The electron gun for a color cathode ray tube according to claim 1, wherein the side hole of the first elliptic extension electrode is formed by combining two ellipses having different radii about a vertical axis. [4] The electron gun for color cathode ray tube of claim 1 or 3, wherein the side hole of the first elliptic extension electrode is formed such that the central hole ellipse radius is smaller than the outer ellipse radius about the vertical axis.