KR100339348B1 - electron gun for colon CRT - Google Patents

Abstract

The present invention relates to an electron gun for a color cathode ray tube, to maintain the focusing force of the main lens so as not to be largely affected by the direction to optimize the shape of the electron beam formed on the screen and to improve the resolution of the color receiving tube.

The present invention provides a cathode comprising a cathode for emitting an electron beam, a triode consisting of a first electrode and a second electrode for adjusting the radiation amount of the electron beam, a main lens including a focus electrode and an anode electrode for focusing the electron beam on a screen; A focus opening electrode portion and an anode opening electrode portion formed on opposing surfaces of the electrodes constituting the main lens to become a common opening of three electron beams, and a focus inner electrode portion disposed to be retracted into the electrode from the opening electrode portion of the main lens; And an electron gun composed of an anode inner electrode portion, wherein an depression or a protrusion is formed in an outer corner of the side electron beam through hole of the focus opening electrode portion or the anode opening electrode portion, or both of the side electron beam through holes of the focus electrode opening or the anode electrode opening portion are formed. For color cathode ray tubes formed by forming recesses or protrusions in each outer corner A gun.

Description

Electron gun for colon CRT

The present invention relates to an electron gun for a color cathode ray tube, and in particular, to maintain the focusing force of the main lens so as not to be greatly influenced in the direction to optimize the shape of the electron beam to improve the resolution of the color receiving tube.

In general, color cathode ray tube is formed in the neck portion of a glass panel (Panel) and the funnel (Funnel) (2) made and 10 ^-7 Torr by the bulb (3) formed so as to maintain the degree of vacuum in the bulb as shown in Figure 1 (4) an electron gun (6) mounted therein to emit an electron beam, and a shadow mask (8) for selectively impinging the three electron beams (5) emitted from the electron gun onto the fluorescent film (7) applied to the panel; And a deflection yoke positioned outside the funnel to deflect the electron beam emitted from the electron gun.

FIG. 2 is a half sectional view showing a configuration of a uni-bi type electron gun, which is one type of the electron gun of FIG. 1, in which the electron gun controls a cathode 10 radiating hot electrons and a hot electron radiated from the cathode. The first electrode 11 and the second electrode 12 which are triodes, and the third electrode 13 and the fourth electrode arranged in the tube axis direction to form a capacitive focusing lens for focusing the electron beam on the fluorescent film. 14), the focus electrode 15, the anode electrode 16, and the shield cup 17 attached to the anode electrode and the like, which are fixed in a fixed shape by the non-insulating bead glass 18.

Therefore, when hot electrons are emitted by the heating of a heater (not shown) inserted into the cathode 10, the amount of the electron beam is controlled by the first electrode 11 and accelerated by the second electrode 12.

In addition, the electrostatic lens formed between the second electrode 12 and the third electrode 13, and the electrostatic lens formed by the third electrode 13, the fourth electrode 14 and the focus electrode 15 (these electrostatic lenses The incident angle at which the electron beam 5 is incident on the main lens is determined by the action of the shear focusing lens, and the main electrostatic focusing lens (referred to as the main lens) composed of the focus electrode 15 and the anode electrode 16 is determined. After focusing, the screen collides with the fluorescent film 7 through the shadow mask 8.

In this case, the voltage applied to the anode electrode 16 is a high voltage of about 20,000 to 35,000 volts, and is applied to the anode electrode 16 to the focus electrode 15 disposed at a distance of 0.8 to 1.3 mm from the anode electrode 16. About 20% to 40% of the voltage applied is applied.

Sharpness of the electron beam spot formed on the screen through the above process is determined by the formula Ds = {(Dx + Dsa) ² + Dsc} ^1/2 .

In the above equation, Dx is an enlargement component of the crossover point by the magnification of the electrostatic focusing lens, Dsa is an electron beam dispersion component due to the spherical aberration of the main lens, and Dsc is an electron beam dispersion component due to the space charge effect.

In particular, the electron beam dispersion component due to the main lens spherical aberration has a great influence on the performance of the monitor electron gun, and an effective large-diameter electron gun is mainly used to reduce spherical aberration and improve resolution.

3 and 4 are perspective views showing an example of the main lens unit of the general effective large-diameter electron gun, FIG. 3 shows a focus electrode, FIG. 4 shows an anode electrode, and the anode electrode is shown in the same direction as the focus electrode for convenience. In practice, the directions are opposite and are arranged to face the focus electrodes.

As shown in FIG. 3, the focus electrode 15 is a cap-type focus opening electrode part 15a having a common opening similar to that of a race track, and a focus installed in the focus opening electrode part and electrically connected thereto. The anode electrode 16 is composed of an inner electrode portion 15b, and the anode electrode 16 is provided inside the cap-shaped anode opening electrode portion 16a and the anode opening electrode portion having a common opening similar to a dog bone. And an anode inner electrode portion 16b connected to each other.

Therefore, when a high voltage of about 20,000 volts to 35,000 volts is applied to the anode electrode 16 and a voltage of about 5,000 to 10,000 volts is applied to the focus electrode 15, an electrostatic lens is formed between the two electrodes, and a focus opening electrode part ( 15a) and the anode opening electrode portion 15b have a smaller vertical diameter than the diameter of the three electron beams in the vertical direction, thereby causing a strong vertical focusing action, and penetrating through both opening electrode portions 15a and 16a. The weakened electric field is subjected to the horizontal focusing action by the focus inner electrode portion 15b and the anode inner electrode portion 16b.

In addition, both side electron beams 5a and 5c are subjected to a force directed to the center electron beam 5a by an electric field formed in a common opening of the focus opening electrode portion 15a and the anode opening electrode portion 16a. ), Which is called static convergence.

In this electron gun, the moving speed of the electron beam is equal to the equation v = (2ev / m) ^1/2 .

Where v is the speed of electrons (meter / sec), e is the charge of electrons (1.6 × 10 ^-19 Coulomb), m is the mass of electrons (9.1 × 10 ^-31 Kg), and V is the potential (Volt).

Therefore, since the moving speed of the electron beam is proportional to the square root of the voltage, the electron beam moves faster in the anode electrode 16 having a higher potential, so that the time of divergence in the anode electrode 16 is longer than the time focused in the focus electrode 15. It is short, and thus, the focusing action is strongly influenced by the focus electrode 15 rather than the diverging action by the anode electrode 16.

Meanwhile, the horizontal focusing of the electron beam is mainly controlled by the focus inner electrode part 15b and the anode inner electrode part 16b, and the focusing in the vertical direction is performed by the focus opening electrode part 15a and the anode opening electrode part 16a. Mainly controlled.

Therefore, in order to properly focus the electron beam in the vertical direction, the opening vertical diameter of the anode opening electrode portion 16a should be designed to be smaller than the opening vertical diameter of the focus opening electrode portion 15a, and the center electron beam of the anode opening electrode portion 16a should be designed. The opening vertical diameter of the position must be designed smaller than the opening vertical diameter of the side electron beam position to obtain an appropriate focusing force between the center electron beam and the side electron beam.

In addition, the side electron beams show a difference in the focusing force in the center direction and the opposite direction from the center of the side electron beam due to the asymmetry of the pass path. This is called a coma aberration and solves the coma aberration of the side electron beam. In order to do this, the side electron beam through holes of the inner electrode portions 15b and 16b are eccentrically outward with respect to the traveling center of the electron beam.

FIG. 5 is a front view showing the focus electrode and the anode electrode overlapped for explanation of the main lens, and the focus opening electrode part 15a is shown by a solid line and the anode opening electrode part 16a is shown by a dotted line to distinguish each electrode. It was.

In FIG. 5, the horizontal end portion of the anode opening electrode portion 16a with the focus opening electrode portion 15a is generally coincident to obtain the maximum aperture, but the vertical diameter of the opening is that the anode opening electrode portion 16a is the focus opening electrode portion 15a. Is less than

This is because when the vertical diameter of the anode opening electrode portion 16a is made smaller than the vertical diameter of the focus opening electrode portion 15a, the divergence force in the vertical direction is increased while the inflow of the electric field from the opposing focus opening electrode portion 15a is increased. This is because it is weakened and the diverging force in the horizontal direction is weakened by the anode inner electrode portion 16b.

Therefore, the conventional electron gun can be designed to properly focus the electron beam on the screen in the horizontal and vertical directions, but the arc center of the focus opening electrode portion 15a having two different curvature radii and the anode opening electrode portion 16a Since the arc center is eccentric by a predetermined distance D, which is a predetermined value, the focusing force cannot be adjusted by adjusting the distance from the opening electrode portions 15a and 15b to the electron beam at any angle.

FIG. 6 is a computer simulation of the electron gun according to the embodiment of FIG. 5. Due to the rotational asymmetry focusing force, the central electron beam 5b is rotated symmetrically as shown in FIG. 6. Side electron beams 5a and 5c are distorted.

In addition, when the electron beam is not optimally formed at the center of the screen and is deflected by the deflection yoke 9 to the periphery of the screen, the error component is enlarged and displayed, which in turn acts as a factor to further reduce the resolution on the screen.

SUMMARY OF THE INVENTION An object of the present invention is to improve the shape of a focus opening electrode part or an anode opening electrode part to provide an electron gun of a color cathode ray tube capable of bringing the focusing force of a rotationally asymmetrical electron beam closer to rotational symmetry and thus improving the resolution of a side electron beam. It is to.

According to an embodiment of the present invention for achieving the above object, a triode consisting of a cathode for emitting an electron beam, a first electrode and a second electrode for adjusting the radiation amount of the electron beam, and for focusing the electron beam on the screen A main lens composed of a focus electrode and an anode electrode, a focus opening electrode portion and an anode opening electrode portion formed on opposing surfaces of the electrodes constituting the main lens to become a common opening of three electron beams, and an opening electrode portion of the main lens In the electron gun consisting of a focus inner electrode portion and an anode inner electrode portion disposed to be retracted into the electrode in the electrode, the depression or protrusion is selectively formed or embedded in the outer corner of the side electron beam through hole of the focus opening electrode portion and the anode opening electrode portion There is provided an electron gun for a color cathode ray tube formed by forming both a portion and a protrusion.

1 is a schematic cross-sectional view of a common color cathode ray tube

2 is a half sectional view showing the configuration of a general electron gun;

3 is a perspective view showing an example of a focus electrode of a conventional electron gun

4 is a perspective view showing an example of an anode electrode of a conventional electron gun

5 is a front view illustrating a conventional focus electrode and an anode electrode overlapped with each other;

6 is an electron beam screen formed by a conventional electron gun

7 is a front view showing the focus electrode and the anode electrode of the electron gun in accordance with one embodiment of the present invention;

8 is a front view illustrating the focus electrode and the anode electrode overlapped according to another embodiment of the present invention;

9 is a front view illustrating a focus electrode and an anode electrode overlapped according to another embodiment of the present invention;

10 is a front view illustrating the focus electrode and the anode electrode overlapped according to another embodiment of the present invention;

FIG. 11 is a front view illustrating the focus electrode and the anode electrode overlapping each other according to another exemplary embodiment of the present invention.

12 is a front view of a focus electrode and an anode electrode overlapped according to another embodiment of the present invention;

13 is an electron beam screen formed by the electron gun of the present invention

Explanation of symbols for main parts of the drawings

5a, 5b, 5c: electron beam 15: focus electrode

15a: focus opening electrode portion 15b: focus inner electrode portion

16: anode electrode 16a: anode opening electrode portion

16b: anode inner electrode portion 21, 24: ear recess

22,23,27,28: protrusion 25,26: depression

7 to 12 are front views showing overlapping focus electrodes and anode electrodes according to various embodiments of the present invention, and FIG. 13 is an electron beam screen forming view according to the present invention.

FIG. 7 shows a small indentation 21 having an ear shape in the outer corners of the side electron beam through-holes in forming the anode opening electrode portion 16a of the anode electrode 16, so as to be diagonal (A). It is designed to weaken the divergence of the furnace.

Therefore, the side electron beam 5a has a balance between the distance from the focus opening electrode portion 15a and the distance from the anode opening electrode portion 16a in the oblique direction A, so that the horizontal and vertical focusing forces together with the oblique direction The focusing force at any angle represented by (A) can also be adjusted to have a rotationally symmetrical focusing force with respect to the side electron beam.

13 is an electron beam screen forming view according to the present invention, as well as the center electron beam (5b) as well as the side electron beams (5a) (5c) to form a circle or oval by the rotationally symmetrical focusing force at the center of the screen, as described above As the degree of focusing on the electron beam is rotationally symmetrical, when the side electron beams are deflected by the deflection yoke 9 to the periphery of the screen, the shape change due to the difference in focusing force does not cause a small and distinct beam spot throughout the screen. To form.

In addition, if the small ear-shaped indentation 21 is formed in a part of the electrode, the electric field changes smoothly, and at the position where the side electron beam passes, the effect is as if the outer shape of the opposing opening electrode part is matched as a whole. It is not necessary to match the shape of the electrode portions opposing in all directions.

Therefore, the center of the ear-shaped recess 21 according to the present invention should be located at the corners outside the side electron beam through holes as shown in FIG.

In addition, since the shape of the electrode has a great influence on the focusing and divergence of the electron beam, the depth of intrusion is 1 mm or less when forming the indentation only on one of the opposing electrodes, but when it is formed on both opposing electrodes, it is 1 mm or more. It is also possible.

FIG. 8 is an embodiment in which the protrusions 22 are formed in the focus opening electrode portion 15a of the focus electrode 15. In this embodiment, the same effects as in FIG. 7 can be obtained.

On the other hand, when the beam distance of the electron gun is changed, a weak focusing force in the diagonal direction A may be required according to one strong horizontal focusing or weak horizontal diverging by the focus inner electrode part or the anode inner electrode part 16b. For this purpose, it is necessary to form an ear-shaped protrusion at the outer corner of the side electron beam through hole of the anode opening electrode portion 16a as opposed to the embodiment of FIG.

FIG. 9 shows a rotational symmetrical focusing force by forming a protrusion 23 in the anode opening electrode portion 16a to perform a weakening focusing action in the diagonal direction A as an embodiment in the case described above. FIG. 10 is an example in which the depressions 24 are formed in the anode opening electrode portion 16a, and the same effects as in FIG. 9 can be obtained.

FIG. 11 illustrates an embodiment in which the ear openings 25 and 26 are formed in both the focus opening electrode part 15 and the anode opening electrode part 16. FIG. 12 shows the focus opening electrode part 15a as opposed to the above. In the embodiment, protrusions 27 and 28 are formed on both of the anode opening electrode portions 16a.

11 and 12, the side electron beams have a rotationally symmetrical focusing force.

In the above embodiment, a description has been given mainly on an electron gun having a race track and a dogbone. However, even when the opposite surfaces are the same, the side electron beam subjected to asymmetrical focusing force by the static convergence of the side electron beam is rotated by the above-described method. It can focus symmetrically.

According to the present invention, the focusing force in the diagonal direction of the side electron beam can be adjusted by forming recesses or protrusions in each of the opening electrode portions of the focus electrode and the anode electrode constituting the main lens, so that the side electron beams are uniform in a circular or elliptical shape on the screen. Because of the focusing, the shape of the electron beam can be sharpened to improve the resolution of the entire screen.

Claims (6)

A main lens comprising a plurality of cathodes emitting an electron beam, a triode consisting of a first electrode and a second electrode for adjusting the radiation amount of the electron beam, a focus electrode and an anode electrode for focusing the electron beam on a screen, and the main lens; A focus opening electrode portion and an anode opening electrode portion formed on opposing surfaces of the electrodes constituting the lens to become a common opening of three electron beams, a focus inner electrode portion disposed to be retracted into the electrode from the opening electrode portion of the main lens; An anode inner electrode portion, wherein an indentation portion is formed in an outer corner portion of a side electron beam through hole of the focus opening electrode portion or the anode opening electrode portion, and an electron gun for a color cathode ray tube. The method of claim 1, The electron gun for the color cathode ray tube formed in the upper and lower left and right symmetrical shape, the indentation portion more than the four corners of the opening surface. A main lens comprising a plurality of cathodes emitting an electron beam, a triode consisting of a first electrode and a second electrode for adjusting the radiation amount of the electron beam, a focus electrode and an anode electrode for focusing the electron beam on a screen, and the main lens; A focus opening electrode portion and an anode opening electrode portion formed on opposing surfaces of the electrodes constituting the lens to become a common opening of three electron beams, a focus inner electrode portion disposed to be retracted into the electrode from the opening electrode portion of the main lens; An anode inner electrode portion, wherein a projection portion is formed at an outer corner of a side electron beam through hole in the focus opening electrode portion or the anode opening electrode portion, wherein the electron gun for a color cathode ray tube is used. The method of claim 3, wherein An electron gun for a color cathode ray tube, wherein the protruding portion is formed at upper or lower symmetrical shapes and formed at least four corners of an opening surface. A main lens comprising a plurality of cathodes emitting an electron beam, a triode consisting of a first electrode and a second electrode for adjusting the radiation amount of the electron beam, a focus electrode and an anode electrode for focusing the electron beam on a screen, and the main lens; A focus opening electrode portion and an anode opening electrode portion formed on opposing surfaces of the electrodes constituting the lens to become a common opening of three electron beams, a focus inner electrode portion retracted and disposed inside the electrode from the opening electrode portion of the main lens; An anode inner electrode portion, wherein an indentation portion or a protrusion is formed in an outer corner of each of the electron beam through holes of the focus opening electrode portion and the anode opening electrode portion. The method of claim 5, An electron gun for a color cathode ray tube, wherein the recessed part or the projecting part is formed on the upper, lower, left, and right symmetrical shapes at least four corners of the opening surface.