KR20040043266A - Electron gun for cathode ray tube - Google Patents

Abstract

PURPOSE: An electron gun for a cathode ray tube is provided to reduce a spot mirror by magnifying a horizontal main lens mirror for improving a focus of a screen image. CONSTITUTION: An electron gun for a cathode ray tube comprises a triode part including a plurality of cathode radiating an electron beam, a G1 electrode as a control electrode for regulating a radiation quantity of the electron beam, and a G2 electrode for accelerating the electron beam toward a screen; and an electron gun having a plurality of focusing electrode(38) and an anode applied to a high voltage and an inner electrode(38a) mounted by retreating a predetermined distance from an end part of a common rim(38d). The focusing electrode and the anode form the common rim at a mutual opposite surface of the focusing electrode. A horizontal direction length of a single rim of the anode is larger than a horizontal direction length of a single rim of the focusing electrode. A center electron beam through hole of the inner electrode is a long length type in case of a vertical than a horizontal.

Description

Electron gun for cathode ray tube {Electron gun for Cathode Ray Tube}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cathode ray tube, and more particularly, to a structure of an electron line for a cathode ray tube of an in-line three-beam method (In-Line-Three-Beams-System) inserted into a neck portion of a cathode ray tube.

In general, a cathode ray tube (CRT) is a device that converts an electrical signal into an optical beam by scanning an electron beam and converting it into an optical image.

Cathode ray tube as described above is the most widely used display device has the advantage of excellent display quality and cost performance ratio is widely used as a general-purpose image display device. Referring to the general principle of the cathode ray tube (CRT) as described above.

In the cathode ray tube, an electron beam emitted from an electron gun is focused through an electron lens in a vacuum glass tube, and the focused electron beam is refracted to be directed to a predetermined position on the fluorescent surface by a magnetic field of a deflection yoke attached to the neck of the glass tube. The refracted electron beam strikes the phosphor on the phosphor surface to emit light.

Hereinafter, a configuration of a general color cathode ray tube with reference to the accompanying drawings is as follows. 1 is a cross-sectional view showing the structure of a general color cathode ray tube.

As shown in the drawing, a typical cathode ray tube includes a generally rectangular panel part 50, which is a front body, an approximately cylindrical neck part 70, which is a rear body, and the panel part ( 50) and a funnel portion 60, which is a substantially funnel-type vacuum casing connecting the neck portion 70, red, green and blue (R) on the inner surface of the face plate of the panel 50 portion. The fluorescent surface 15 emitting the light emitted by G and B is coated, and a shadow mask 14, which is a porous thin metal material serving as a color selection electrode, is installed while maintaining a predetermined distance from the fluorescent surface 15.

In addition, the neck portion 70 is provided with an electron gun 80 for generating three electron beams 13 of red, green, and blue (R, G, B). The fluorescent mask 15 is reached through the shadow mask 14.

In addition, the funnel portion 60 connects the panel portion 50, which is the cathode ray tube front body, and the neck portion 70, which is the rear body, and is installed inside to reduce the influence of the external geomagnetic field during operation of the cathode ray tube. An inner shield 20 which serves as a shield to receive the frame, a frame 18 supporting the inner shield 20 and the shadow mask 14 by fixing springs 19, and the frame 18 assembly on the panel It includes a spring 17 to be coupled to the portion 50 and a reinforcing band (not shown) surrounding the outside of the funnel 60 to ensure safety.

The electron gun 80 emits an electron beam 13 for controlling a screen signal, and the electron beam 13 generates a deflection yoke 12 around the connection portion between the neck portion 70 and the funnel portion 60. After deflecting up, down, left and right under the influence of the deflecting magnetic field, the light passes through the beam passing holes formed in the shadow mask 14, and then sequentially scans the respective phosphors in the fluorescent surface 15, and then lands separately. A predetermined image is realized in color.

Each electrode of the in-line electron gun 80 has a path through which the electron beam 13 passes so that the electron beam 13 generated from the cathode 3 can be controlled in a constant intensity to reach the screen. They are located at regular intervals from each other to be vertical.

Hereinafter, the structure of the inline electron gun 80 will be described in detail with reference to the accompanying drawings. 2 is a schematic view showing the structure of a conventional inline electron gun.

As shown in the figure, three independent cathodes 3, which are independent of each other, a common lattice of three cathodes 3, G1 electrode 4 (control electrode) and G1 electrode ( 4; G2 electrode 5 (acceleration electrode) arranged at regular intervals from the control electrode), G3 electrode 6, G4 electrode 7, G5 electrode 8 (focus electrode), G6 electrode 9 (anode electrode) The G6 electrode 9 (anode electrode) is configured in the order of the BSC for the role of fixing the electron gun 80 to the neck portion 70 of the tube while electrically connecting the electron gun 80 and the tube on the top ( The shield cup 10 to which the 11 is attached is comprised in order.

Referring to the operation of the electron gun consisting of the above configuration is as follows.

First, the electron gun 80 is connected to a power source through the stem pin 1, the heater (2) embedded in the cathode 3 is discharged electrons from the surface of the cathode (3).

The electron beam 13 is controlled by the G1 electrode 4 which is a control electrode, and the electron beam 13 is accelerated by the G2 electrode 5 which is an acceleration electrode, and the G2 electrode 5 and the G3 electrode ( 6), the electron beam 13 is partially focused / accumulated by the shear focusing lens formed between the G4 electrode 7 and the G5 electrode 8, and the G5 electrode 8, also called a focusing electrode which is a main lens forming electrode, The G6 electrode 9, also called an anode electrode, mainly focuses and accelerates, passes through the shadow mask 14 provided on the inner surface of the screen, and collides with the fluorescent surface 15 to emit light.

In addition, a deflection yoke 12 is disposed to deflect the electron beam 13 emitted from the electron gun 80 to the entire screen, thereby deflecting the electron beam 13 to the entire fluorescent surface.

The voltage Vg2 applied to the G2 electrode 5 (acceleration electrode) is about 400 to 1,000 V, the voltage Vg3 applied to the G5 electrode 8 (focusing electrode) is about 6,000 to 10,000 V, and the G6 electrode (9; voltage electrode) applied to the positive electrode is about 20,000 ~ 35,000V.

One common rim 8d, 9d through which three electron beams pass is formed in the G5 electrode 8 (focusing electrode) and the G6 electrode 9 (anode electrode).

The rims 8d and 9d are formed in a shape similar to that of a race track, and three electron beams R, G, and B pass through a plane that is retracted by a predetermined distance from the rims 8d and 9d. Inner electrodes 8a and 9a having electron beam through holes 8b and 9b formed therein are provided.

Figure 3 (a) is a cutaway perspective view showing the configuration of the focusing electrode of the conventional electron gun components, (b) is a front view showing the configuration of a conventional focusing electrode, (c) is a cross-sectional view of a conventional focusing electrode.

And, Figure 4 (a) is a cutaway perspective view showing the configuration of the anode electrode of the conventional electron gun components, (b) is a front view showing the configuration of the conventional anode electrode, (c) is a cross-sectional view of the conventional anode electrode to be.

As shown in the figure, the electron beam passing holes 8b and 9b of the focusing electrode 8 side inner electrode 8a and the anode electrode 9 side inner electrode 9a are composed of one hole. It is composed of elliptical balls that are longer than vertical.

Among the characteristics of the conventional electron gun 80 having the above configuration, the spot size on the screen is generally the spot diameter D _x by the lens magnification and the spot diameter D _st by the space charge repulsion force. And the spot diameter D _ic due to the spherical aberration of the lens.

In other words, The formula of is established.

In particular, as a method of reducing spherical aberration while reducing space charge repulsion, the best method is to enlarge the main lens and reduce the magnification of the spot due to spherical aberration even when an electron beam with a large divergence angle is incident, and the space after passing through the main lens. Charge repulsion can also be reduced, enabling small spots on the screen.

In order to realize the above characteristics, inner and outer electrodes 8a and 9a which are retracted by a predetermined distance from the openings of the G5 electrode 8 (focusing electrode) and the G6 electrode 9 (anode electrode) constituting the main lens are generally built in, and R, G , B to adjust the action of the three lenses in the optimum state, and serves to finely adjust the horizontal and vertical focusing difference of the electron beam 13 through the correction electrode (10a) located at the bottom of the shield cup (10).

Usually, as the basic design characteristics of the main lens, the focusing force of the center beam and the side beam should be designed identically, and at the same time, the center beam and the side beam should be converged at one point of the screen.

However, as described above, as a method of enlarging the main lens diameter in order to reduce the spot diameter, a method of expanding the opening pore diameter of the main lens forming electrode, a method of enlarging the pore diameters of the inner electrodes 8a and 9a, and There is a method of deepening the depth of the inner electrode bodies 8a and 9a which perform a lens correction action.

However, it is almost impossible to expand the opening pore size because of the mechanical constraints of the neck glass.

Therefore, the main lens diameter can be effectively enlarged by increasing the pore size of the electron beam through holes 8b and 9b of the inner electrodes 8a and 9a constituting the main lens as much as possible and deepening the depth of the inner electrodes 8a and 9a. Will be.

Korean Patent Registration No. 10-0322079 and Korean Laid-Open Patent Publication No. 2000-0066308 describe a patent technology characterized in that the center electron beam through-hole of the main lens forming inner electrode has an elongated shape.

The conventional main lens structure has a neck glass diameter of 29.1 mm and is limited to 19 mm of the opening diameter of the focusing electrode 8 and the G6 electrode 9 (anode electrode) and 8 mm of the vertical diameter. The depth of 9a) is limited to 3.5 mm or less on the focusing electrode 8 side and 2.5 mm or less on the G6 electrode 9 (anode electrode) side.

Therefore, when the inner electrodes 8a and 9a are deepened for the purpose of expanding the main lens diameter, the same focusing voltage of the three R and B electron beams is required, and the center beam and the side beam are moved to one point at the center of the screen. It is difficult to satisfy all of the characteristics that need to be concentrated.

Therefore, the maximum main lens diameter obtained from the main lens is about φ 8.0 mm in the horizontal direction and about φ 7.0 mm in the vertical direction.

In order to satisfy the quality of the color cathode ray tube with the large screen and high definition, it is necessary to improve the forks characteristic. In particular, it is urgent to develop a technology for effectively reducing the spot size by expanding the main lens diameter. .

The present invention has been proposed to solve the above problems, and an object of the present invention relates to an electrode forming a main lens of a cathode ray tube electron gun, and in particular, a horizontal main lens mirror for reducing the spot diameter to meet the focus enhancement request on the screen. It is an object of the present invention to provide an electron gun for a cathode ray tube to enlarge.

1 is a cross-sectional view showing the structure of a general color cathode ray tube.

2 is a schematic view showing the structure of a conventional inline electron gun.

Figure 3 (a) is a cutaway perspective view showing the configuration of the focusing electrode of the conventional electron gun components, (b) is a front view showing the configuration of a conventional focusing electrode, (c) is a cross-sectional view of a conventional focusing electrode.

Figure 4 (a) is a cutaway perspective view showing the configuration of the anode electrode of the conventional electron gun components, (b) is a front view showing the configuration of the conventional anode electrode, (c) is a cross-sectional view of the conventional anode electrode.

Figure 5 (a) is a cutaway perspective view showing the configuration of the focusing electrode of the electron gun component according to the present invention, (b) is a front view showing the configuration of the focusing electrode according to the present invention, (c) according to the present invention It is a cross-sectional view of a focusing electrode.

Figure 6 (a) is a cutaway perspective view showing the configuration of the anode electrode of the electron gun component according to the invention, (b) is a front view showing the configuration of the anode electrode according to the invention, (c) is in accordance with the present invention It is a cross-sectional view of an anode electrode.

Figure 7 is a detailed view showing the shape of the side hole of the inner electrode according to the present invention.

8 is a graph comparing spot sizes according to the prior art and the practice of the present invention.

9 is a diagram illustrating a spot improvement state according to an embodiment of the present invention.

10 is a graph showing a spot diameter change when the focusing voltage is changed according to the present invention.

11 is a graph showing a spot diameter change when a conventional focusing voltage is changed.

* Description of the symbols for the main parts of the drawings *

1: stem pin 2: heater

3: cathode 4: G1 electrode (control electrode)

5: G2 electrode (acceleration electrode) 6: G3 electrode

7: G4 electrode 8: G5 electrode (focusing electrode)

9: G6 electrode (anode electrode) 10: shield cup

11: BSC 12: deflection yoke

13: electron beam 14: shadow mask

15: fluorescent surface 17: spring

18: Frame 20: Inner Shield

50: panel portion 60: funnel portion

70: neck part 80: electron gun

Cathode ray tube electron gun according to the present invention for achieving the above object is a three-pole consisting of a plurality of cathodes for emitting an electron beam, G1 electrode which is a control electrode for controlling the radiation amount of the electron beam, G2 electrode to accelerate to the screen And a plurality of focusing electrodes and an anode electrode to which a high pressure is applied, and a focusing electrode and a cathode electrode forming the main lens have a common rim formed on a surface opposite to the focusing electrode. Including the inner electrode installed by retreating a certain distance from the end of the rim,

The horizontal length of the single rim of the anode electrode is greater than the horizontal length of the single rim of the focusing electrode, and the center electron beam passing hole of the inner electrode is longer than vertical.

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

First, referring to FIG. 2 to describe the structure of the inline electron gun according to the present invention, the same reference numerals will be given to the same parts as in the prior art.

Accordingly, the structure of the electron gun of the present invention is a G1 electrode 4 (control electrode) which is a common lattice of three independent cathodes 3 and three cathodes 3 which are arranged at a predetermined distance from the cathode 3. And an acceleration electrode, a G3 electrode 6, a G4 electrode 7, a G5 electrode 38 (focusing electrode), and a G6 electrode 39 arranged at a predetermined interval from the G1 electrode 4 (control electrode). ; Positive electrode), and the B6 is attached to the upper portion of the G6 electrode 39 (anode electrode) while fixing the electron gun 80 to the neck portion of the tube while electrically connecting the electron gun 80 and the tube. The shield cup 10 is configured in order.

In addition, the electron gun 80 is a heater (2) embedded in the cathode (3) is connected to the power supply through the stem pin (1) to emit electrons from the surface of the cathode (3), the electron is the control electrode (4) The electron beam 13 is controlled by the G1 electrode 4 (control electrode), and the electron beam 13 is accelerated by the acceleration electrode 5, the G2 electrode 5 which is the acceleration electrode 5, and the G2 electrode 5; ), The electron beam 13 is partially focused and accelerated by the shear focusing lens formed between the G3 electrode 6, the G4 electrode 7, and the G5 electrode 38 (focusing electrode), and is also called a focusing electrode which is a main lens forming electrode. Focusing / acceleration is mainly carried out by the G5 electrode 38, which is called, and the G6 electrode 39, which is also called the anode, passes through the shadow mask 14 provided on the inner surface of the screen and collides with the fluorescent surface 15 to emit light.

In addition, a deflection yoke 12 is disposed outside the electron gun 80 to deflect the electron beam 13 emitted from the electron gun 80 to the entire screen, thereby deflecting the electron beam 13 to the entire fluorescent surface 15.

In addition, the G5 electrode 38 (focusing electrode) and the G6 electrode 39 (anode electrode) have one rim 38d and 39d which are common to the opposite surfaces, and have a predetermined distance from the ends of the rims 38d and 39d. It consists of the inner electrodes 38a and 39a provided retreating.

The horizontal length of the rim 39d of the G6 electrode 39 (anode electrode) is greater than the horizontal length of the rim 38d of the G5 electrode 38 (focusing electrode), and the horizontal length of the inner electrodes 38a and 39a. The center electron beam through hole has a vertical shape that is longer than horizontal.

The vertical length of the center electron beam through hole of the inner electrodes 38a and 39a and the vertical length of the side electron beam through hole are substantially the same, and are perpendicular to the horizontal maximum length of the side electron beam through hole of the inner electrodes 38a and 39a. The maximum length is configured approximately the same.

The rim 38d on the focusing electrode 38 and the rim 39d on the positive electrode 39 are burred to a predetermined length in order to maintain mechanical strength.

5 and 6 is a block diagram showing a part of the main lens according to the present invention, Figure 5 (a) is a cutaway perspective view showing the configuration of the focusing electrode of the electron gun components according to the present invention, (b) A front view showing the configuration of the focusing electrode according to the invention, (c) is a cross-sectional view of the focusing electrode according to the present invention.

Figure 6 (a) is a cutaway perspective view showing the configuration of the anode electrode of the electron gun component according to the invention, (b) is a front view showing the configuration of the anode electrode according to the invention, (c) is in accordance with the present invention It is a cross-sectional view of an anode electrode.

As shown in the figure, the shape of the focusing electrode 38 side inner electrode 38a is the same as that of the anode electrode 39 side inner electrode 39a, and as shown in the drawing, the side electron beam passing holes are horizontal and vertical. The length is the same, indicating that the center electron beam passing hole is longer than the horizontal in the vertical.

Preferably, the side beam passing holes of the inner electrodes 38a and 39a are circumscribed in a circle as shown in FIG. 7, and the outer beam side is composed of a semicircle at the center of the side ball, and a certain amount of eccentricity to the center beam side ( After the offset, it is composed of ellipses that are longer than vertical.

More preferably, the relation between the side hole eccentricity Os of the inner electrodes 38a and 39a and the horizontal diameter of the rims 38d and 39d is (Ha-Hf) / Os ≥ 0.7. .

The electron gun 80 for the cathode ray tube of the present invention as described above is the same of the lens for the three electron beam appearing when the depth of the inner electrode 38a, 39a of the main lens portion to enlarge the main lens diameter, which is a problem of the conventional main lens. Solving design limitation factors of less than 3.5 mm depth of the main lens inner electrodes 38a and 39a of the focus electrode and less than 2.5 mm depth of the inner electrode 39a of the G6 electrode 39 (anode electrode) due to the difficulty in designing the action As shown in FIGS. 5 and 6, the G5 electrode 38 (focusing electrode) and the G6 electrode 39 (anode electrode) are constituted, so that the depth of the inner electrodes 38a and 39a of the main lens of the focus electrode and the G6 electrode ( 39; the depth of the inner electrode 39a of the positive electrode can be extended to 4.0 mm.

In addition, instead of configuring the inner electrode 38a on the focusing electrode 38 side and the anode electrode 39 side on the focusing electrode 38 side to concentrate the three electron beams at one point, the focusing electrode 38 side is formed. The above convergence can be satisfied by making the horizontal diameter of the rim 39d of the anode electrode 39 larger than the horizontal diameter of the rim 38d.

8 is a graph comparing spot sizes according to the prior art and the practice of the present invention. As shown in the figure, the present invention was applied to a 20-inch 90-degree deflection-color cathode ray tube, and as a result, the horizontal diameter of the rim 39d of the anode electrode 39 side was expanded from 19.0 mm to 19.5 mm. The lens horizontal diameter has been expanded from Φ8.0 mm to Φ9.0 mm, and the main lens vertical diameter has been expanded from Φ7.0 mm to Φ 8.0 mm, and the spreading amount of the R and B spots at the screen center is within 2.0 mm. Could get

As a result, the spot diameter was reduced by 10% compared with the conventional one, as shown in FIG.

Meanwhile, in the side holes of the inner electrodes 38a and 39a, the electric field action with the rims 38d and 39d is closer to the focusing electrode 38 than the anode electrode 39. Therefore, a small amount of distortion of the side electron beam shape is generated.

Therefore, a more preferable shape of the side holes of the inner electrodes 38a and 39a is circumscribed to a circle as shown in FIG. 7, and the outer side at the center of the side hole is composed of a semicircle, and is vertically centered by a certain amount Os. By constructing a long ellipse of, the spot shape of the side beam can be realized close to a circle, and the spot diameter can be further reduced.

The present invention is a 21-inch embodiment, the horizontal / vertical diameter of the side hole of the inner electrode (38a, 39a) is formed to 6.4mm, the outer side is semicircle at the center of the side hole, the inside is 0.5mm straight After eccentricity, the shape of the vertical ellipse improves the spot shape of the conventional side beam to a circular shape as shown in FIG. 9, thereby reducing the spot diameter to 12% compared with the conventional one, thereby improving the focus characteristic.

The eccentric amount Os from the center of the side holes of the inner electrodes 38a and 39a to the center hole side, the horizontal diameter Hf of the rim 38d of the focusing electrode 38, and the anode electrode 39 It can be seen that a certain ratio relationship is established in the relationship with the horizontal mirror Ha of the side rim 39d as follows.

(Ha-Hf) / Os ≥0.7

10 is a graph showing a spot diameter change when the focusing voltage changes, and FIG. 11 is a graph showing a spot diameter change when the focusing voltage is changed in the related art.

10 and 11, as the main lens aperture of the present invention is enlarged, the amount of change in spherical aberration is decreased when the focusing voltage is changed, and as a result, the change in spot diameter is insensitive.

That is, when the spot diameter becomes insensitive as the focusing voltage changes, the change in focus characteristic due to dispersion in the cathode ray tube manufacturing process is reduced, and thus the focus characteristic is improved.

The present invention as described above can reduce the spot size at the center of the screen, the change in the vertical spot size is insensitive when the focusing voltage forming the main lens is insensitive, thereby reducing the halo component due to deflection aberration at the screen corners. Peripheral resolution is improved to obtain good focus.

In addition, the horizontal diameter of the rim portion of the anode electrode 39 side is expanded from 19.0 mm to 19.5 mm, and the main lens horizontal diameter is from Φ8.0 mm to Φ9.0 mm, and the main lens vertical diameter is from Φ7.0 mm to Φ8. It has been enlarged to .0 mm, and the spreading amount of the R and B spots in the screen center is less than 2.0 mm, so that the spot diameter is reduced by 10% compared with the prior art, thereby improving the focus characteristic.

Then, the horizontal / vertical diameter of the side hole of the inner electrode is 6.4 mm, the outer side is centered at the center of the side hole, and the center hole side is centered at a straight line of 0.5 mm, and then formed of an ellipse longer than the horizontal side. By improving the shape of the spot close to the circular shape, the spot diameter is reduced by 12% compared with the prior art, which has the effect of further improving the focus characteristic.

Claims (8)

It comprises a plurality of cathodes for emitting an electron beam, a G1 electrode which is a control electrode for controlling the radiation amount of the electron beam, a tripolar portion consisting of a G2 electrode for accelerating to the screen, the plurality of focusing electrodes and a cathode electrode to which high pressure is applied The focusing electrode and the anode electrode forming the main lens may include an electron gun formed of an inner electrode formed by retreating a predetermined distance from an end of the common rim and having a common rim formed on a surface opposite to the focusing electrode. And the horizontal length of the single rim of the anode electrode is greater than the horizontal length of the single rim of the focusing electrode, and the center electron beam through hole of the inner electrode has a longer vertical shape than the horizontal length. The method of claim 1, And the vertical length of the center electron beam through hole of the inner electrode and the vertical length of the side electron beam through hole are substantially the same. The method of claim 1, Electron gun for cathode ray tube, characterized in that the horizontal maximum length and the vertical maximum length of the side electron beam through hole of the inner electrode is approximately equal. The method of claim 1, And the common rim of the converging electrode 38 and the common rim of the positive electrode 39 are curled to a predetermined length into the electrode. The method of claim 1, The inner electron beam passing hole of the inner electrode is circumscribed in a circle, and the outer side of the inner electron beam passing hole is composed of a circle, and is formed of an ellipse that is vertically longer than the horizontal after being delimited by a predetermined amount toward the center hole. Electron gun. The method of claim 1, The predetermined eccentricity from the center of the side electron beam through hole of the inner electrode to the center hole is Os, the horizontal length of the common rim of the focusing electrode 38 is Hf, and the horizontal length of the rim of the anode electrode 39 side. An electron gun for a cathode ray tube, characterized by satisfying the formula (Ha-Hf) / Os ≥ 0.7. The method of claim 1, The horizontal diameter of the rim of the anode electrode 39 side extends from 19.0 mm to 19.5 mm so that the main lens horizontal diameter is expanded from Φ8.0 mm to Φ9.0 mm, and the main lens vertical diameter is from Φ7.0 mm to Φ8. An electron gun for cathode ray tubes, which is expanded to .0 mm and has a spot diameter of 10 mm less than that of the prior art by allowing the gap of R and B spots in the screen center to be within 2.0 mm. The method of claim 1, The horizontal / vertical diameter of the side hole of the inner electrode is formed to be 6.4 mm, the outer side is formed in a semicircle at the center of the side hole, and the inside is formed in a vertical ellipse with a center of 0.5 mm, so that the spot of the side beam is Electron gun for cathode ray tube, characterized in that to make the shape close to the circular shape to reduce the spot diameter by 12% than conventional.