KR100224977B1 - Electron gun for color cathode ray tube - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron gun for color cathode ray tubes, and in particular, an object of the present invention is to obtain an electron gun more accurate by changing an installation position and a shape of an astigmatism correction electrode.

In order to achieve this object, the present invention is provided with a focusing electrode and an anode electrode to form a main lens unit to match the electron beam generated primarily from the triode on the screen to the opposite surface of the focusing electrode and the anode electrode as a common opening. In the in-line electron gun structure of the color cathode ray tube which is formed, and the internal electrode is formed in a predetermined portion of the focusing electrode and the anode electrode,

A plate-shaped astigmatism correction electrode is installed perpendicular to the inline inside the anode electrode.

Description

Electron gun for color cathode ray tube

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron gun for a color cathode ray tube, and more particularly, to an installation position and a shape of a correction electrode when opposing surfaces of the focusing electrode and the anode electrode constituting the main lens portion have a common opening.

As shown in FIG. 1, a general color cathode ray tube is fused to a panel 2 having R, G, and B fluorescent films 1 coated on its inner surface, and fused to a rear end of the panel 2 to vacuum the inside thereof. A funnel 3 for maintaining the state, an electron gun 6 inserted into the neck portion 4 of the funnel 3 to emit the electron beam 5, and an electron beam 5 emitted from the electron gun 6 A deflection yoke (7) for deflecting in the horizontal and vertical directions, and a shadow mask (8) having a color discriminating function of the electron beam (5) deflected by the deflection yoke (7).

As shown in FIG. 2, the electron gun 6 includes a cathode 10 that emits hot electrons by receiving heat from the heater 9 when the heater 9 is built-in, and the heater 9 generates heat. A triode consisting of a control electrode 11 for controlling hot electrons emitted from the cathode 10, an acceleration electrode 12 for accelerating hot electrons passing through the control electrode 11, and an electron beam generated from the triode; The main lens unit is composed of a focusing electrode 13 and an anode electrode 14 for focusing and finally accelerating 5).

Here, the voltages applied to the electrodes are grounded, the control electrode 11 is grounded, a high voltage of at least 20000V is applied to the accelerating electrode 12, the anode electrode 14, and the focusing electrode 13 is applied. An intermediate voltage of 20 to 34% of the voltage applied to the anode electrode 14 is applied.

In the figure, reference numeral 15 denotes a shielding cup.

When power is applied to the conventional color cathode ray tube constructed as described above, the electron beam 5 is radiated from the electron gun 6, and the electron beam 5 is formed by the magnetic field by the intensity of the current applied to the deflection yoke 7. The image is reproduced by hitting the fluorescent film 1 while being deflected into each area and passing through the shadow mask 8 in the state of color selection.

The electron gun 6 radiating the electron beam 5 is applied to the voltage difference between the focusing electrode 13 and the anode electrode 14 as the predetermined potential is applied to each of the electrodes 11, 12, 13, and 14. As a result, an electrostatic lens is formed so that the electron beam 5 generated at the triodes 9, 10, 11, and 12 is focused at the center of the screen.

Here, to focus the tricolor electron beam 5 in the center of the screen, the outer beam (electron beam embodying blue and red) through the electrode in the electrostatic lens is offset or other suitable method. The electrostatic lens is formed to direct the path towards the center beam (electron beam that realizes green).

At this time, in order to deflect the electron beam 5 focused on the center of the screen to the entire area of the screen, the action of the deflection yoke 7 is required. In general, in the case of a color cathode ray tube using an in-line electron gun Since the red, green, and blue tricolor electron beams 5 are arranged in the horizontal direction, the tricolor electron beam 5 is a separate additional circuit and an additional device by using a non-uniform magnetic field to converge the tricolor electron beam 5 in one place of the fluorescent surface. Self-convergence deflection yoke (7) is applied to achieve convergence on the screen even without using.

The magnetic field generated in the deflection yoke 7 to which the self-focusing type is applied has a pincushion in the horizontal direction and a barrel magnetic field in the vertical direction, so that the tricolor electron beams 5 have different deflection forces according to their positions. From the screen to the arrival point to the electron beams 5 at different distances are collected to the same point.

However, the blue, green, and red tricolor electron beams 5 are radiated in the horizontal direction of the electron beam 5 and focused in the vertical direction by such a magnetic field, and vertically by the geometry of the panel 2. In the direction, the halo phenomenon is over-focused.

Therefore, to eliminate this problem, that is, the astigmatism of the electron gun 6 is asymmetric in order to eliminate the phenomenon that the astigmatism increases in the negative direction, so that the astigmatism at the center of the screen is taken to be a positive value. Although the value of the score difference is negative, reducing the absolute value improves the resolution of the front of the screen.

On the other hand, the size of the main lens used to make the blue, green, and red electron beams 5 form a small beam spot on the screen depends largely on the inner diameter of the neck portion 4, which focuses the main lens. It is a known fact that the larger the beam passing hole between the electrode 13 and the anode electrode 14, the smaller the beam spot on the screen appears due to the reduction of spherical aberration and magnification.

In general, the electron beam 5 is radiated from the electron gun 6 inserted into the neck portion 4 of a constant size and passes through the beam passing holes of the focusing electrode 13 and the anode electrode 14, thereby increasing the size of the main lens. For this purpose, the converging electrode 13 and the anode electrode 14 have a common opening on the opposite surface.

Accordingly, as shown in FIG. 3, the opposing surfaces of the control electrode 13 and the anode electrode 14 have a common opening, and the internal electrode 16 is provided inside the focusing electrode 13 and the anode electrode 14. The actual main lens can be made larger.

Such a structure can reduce spherical aberration and reduce magnification of the lens, thereby realizing smaller beam spots on the screen.

In addition, when the internal electrode 16 is installed at a position where the focusing electrode 13 and the anode electrode 14 are retracted by a certain distance, the astigmatism that the electron beam is increased in the negative direction becomes severe, so that correction is performed to correct this. Installation of the electrode 17 has become necessary.

In order to solve this problem, the US patent USP4086513 has a horizontal partition wall correction electrode 17 for correcting astigmatism in the anode electrode 14. The correction electrode 17 of the focusing electrode 13 and the anode electrode 14 forming the main lens is provided. In the structure having three openings with independent opposing surfaces, when the shape or large diameter main lens, that is, the internal electrode 16 is present in the anode electrode 14, problems arise in assembly and characteristics.

This can correct astigmatism when a horizontal bulkhead is installed on the screen side of the internal electrode 16 located inside the anode electrode 14, while affecting the convergence of the outer and center beams. If the beam passing hole vertical diameter of the is greater than the distance between the parallel plates of the correction electrode 17, a difference in just focus voltage between the center beam and the outer beam occurs.

Japanese Patent 平 4-52586 has also been developed to correct astigmatism and to compensate for the problems of US Patent USP4086513, and installed a horizontal partition wall correction electrode 17 on the cathode side of the shielding cup 15.

This caused a problem that the degree of the electron gun 6 is lowered, which will be described in more detail as follows.

In general, assembling of the electron gun 6 is performed by mounting the gap holding plates between the electrodes and the electrodes in a row on the beam support hole electrode support 19 of the bidding jig 18 as shown in FIG. 4. Bead glass is crimped | bonded from the outer side of an electrode, and it is comprised.

This configuration is called a bead mount, and after connecting the bead mount to the stem, the shielding cup 15 to which the correction electrode 17 is welded is corrected on the opposite side of the focusing electrode 13 of the anode electrode 14. The electrode 17 is inserted into the positive electrode 14 to weld the positive electrode 14 and the shielding cup 15.

However, due to the characteristics of the electron gun, the degree of correction electrode is related not only to the degree of the single component itself but also to the depth from the common opening of the anode electrode to the correction electrode.

In general, the depth from the common opening of the anode electrode to the correction electrode depends on the flatness of the shield cup surface to which the correction electrode is welded and the pressing force applied to the anode electrode when welding the shield cup and the anode electrode. In practice, it is difficult to maintain an assembly tolerance of 50 µm or less in the design dimension, which lowers the assembly processability and productivity.

In view of the above, the present invention provides a correction electrode having a higher degree of assembly by installing a correction electrode for correcting astigmatism in the shape of a plate inside a cup-shaped anode electrode to obtain a highly accurate electron gun corresponding to high resolution and large size. There is a purpose.

1 is a block diagram of a general color cathode ray tube.

2 is a first embodiment of a conventional inline electron gun,

(A) Front section view.

(B) is plan section.

3 is a second embodiment of a conventional inline electron gun,

(A) Front section view.

(B) is plan section.

(C) is a cross-sectional view of the correction electrode.

(D) is a sectional view of an internal electrode.

4 is a conventional bidding jig,

(A) is an electrode fastening cross section.

(B) is A-A 'section of (a).

5 is an inline electron gun according to the present invention;

(A) Front section view.

(B) is plan section.

(C) is a cross-sectional view of the correction electrode.

Figure 6 is a cross-sectional view of the electrode support of the bidding jig according to the present invention.

*** Explanation of symbols for the main parts of the drawing ***

101: heater 102: cathode

103: control electrode 104: acceleration electrode

105: focusing electrode 106: anode electrode

107: internal electrode 108: correction electrode

109: electrode support 109a: groove

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

5 is a configuration diagram of an electron gun according to the present invention, a cathode 102 having a heater 101 for cathode heating, a control electrode 103 for controlling and accelerating hot electrons emitted from the cathode 102 and The triode having the accelerating electrode 104 and the main lens unit having the focusing electrode 105 and the anode electrode 106 for focusing and finally accelerating the electron beam generated from the triode are sequentially arranged in the tube axis direction.

Opposing surfaces of the focusing electrode 105 and the anode electrode 106 serve as a common opening with the beam barrel, and the internal electrode 107 is provided at a predetermined position of the focusing electrode 105.

The internal electrode 107 is also retracted from the internal electrode 107 by a predetermined distance from the common opening of the opposite surface of the focusing electrode 105 side of the anode electrode 106. The plate-shaped correction electrode 108 is provided there.

In addition, the center beam through hole of the correction electrode 108 is formed to have a length in the in-line direction longer than the length in the in-line vertical direction, the outer beam through hole is formed to open toward the neck.

In addition, the length d ₁ of the inline vertical direction including the electrode of the outer beam through hole of the correction electrode 108 may be assembled with the electrode support 109 to form the bead mount. It is smaller than the vertical inner diameter d ₂ of the beam through and the common opening of the anode electrode 106.

When described in detail based on the accompanying drawings as follows.

First, before constructing the bead mount, the anode electrode 106 is welded to the anode electrode 106 and then the anode electrode 106 to which the internal electrode 107 and the correction electrode 108 are welded to remove foreign substances generated during welding. ) Will be heat treated.

Subsequently, each electrode is fixed to the electrode support 109 of the bead jig to form a bead mount, and the outer beam through hole support side of the electrode support 109 is opposed to the focusing electrode 105 and the anode electrode 106. The inner surface of the common opening is supported.

In this case, the length d ₁ in the vertical direction including the electrode of the outer beam through hole of the correction electrode 106 is smaller than the vertical opening diameter d ₂ of the common opening of the focusing electrode 105 and the anode electrode 106. As shown in FIG. 6, grooves 109a are formed to a certain degree up and down on the support side of the outer beam passing hole of the electrode support 109 so that the outer beam passage of the correction electrode 108 is inserted into the groove 109a. To construct a higher electron gun.

The main lens of the electron gun formed as described above includes the internal electrode 107 of the focusing electrode 105, the internal electrode 107 of the anode electrode 106, and the correction electrode 108, the focusing electrode 105, and the anode electrode 106. The intensity and aberration are determined by the opposing-surface beam through the common opening, and the dimensions of the correction electrode 108 are internal electrodes 107 and focus electrodes 105 formed in the focusing electrode 105 and the anode electrode 106. And the non-score value generated by the structure and deflection of the anode electrode 106 are determined.

In addition, even if the structure of the electron gun is complicated, it is possible to assemble the electron gun to a degree that is sufficient when employing the correction electrode 108 of the type mentioned above.

As described above, the present invention has the effect of realizing a more accurate electron gun by forming the astigmatism correction correction electrode perpendicular to the inline inside the anode electrode.

Claims (2)

A focusing electrode and an anode electrode are formed to form the main lens unit so that the electron beam generated primarily from the triode is matched on the screen, and the opposing surfaces of the focusing electrode and the anode electrode are formed as a common opening part. In the in-line electron gun structure of a color cathode ray tube in which internal electrodes are formed at a predetermined portion, A plate-shaped astigmatism correction electrode is installed perpendicular to the inline inside the anode electrode, Electron gun for a color cathode ray tube, characterized in that the correction electrode is formed in the outer beam through-hole opening in the neck direction. The method of claim 1, And a center beam through-hole formed in the correction electrode, the length of the inline direction being longer than the length of the vertical direction of the inline direction.

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