KR0166906B1 - Electronic gun for color cathode tube - Google Patents

Abstract

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 specifically, to cause deterioration of focus at the periphery of a screen due to the use of a self-converging deflection yoke, an increase in the deflection angle and a screen size of the deflection yoke. It is to prevent.

To this end, the first and second grid electrodes 11 and 12 for controlling and accelerating the electron beam in order to focus the electron beam 3 emitted from the cathode 8 on the screen on which the phosphor is applied, and a uni-type The third, fourth and fifth grid electrodes 13, 14 and 15 forming the lens and the fifth and sixth grid electrodes 15 and 16 forming the bi-shaped electrode are sequentially arranged in the tube axis direction. The fifth grid electrode 15 is divided into at least two electrodes 15a and 15b so that a variable voltage is applied to at least one electrode in synchronization with the deflection yoke 7. The third grid electrode 13 is also divided into two or more electrodes 13a and 13b so that the electron beam through hole of the electrode 13a adjacent to the fourth grid electrode 14 is axisymmetric and the deflection yoke is provided on the electrode. A variable voltage is applied in synchronization with or divided into at least three or more fifth grid electrodes 15. The electron beam passing holes of the electrodes adjacent to the fourth grid electrode 14 among the divided electrodes are axially symmetrical, and the respective electrodes adjacent to the fourth and sixth grid electrodes 14 and 16 of the electrodes The deflection yoke 7 is tuned so that a variable voltage is applied.

Description

Electron gun for color cathode ray tube

1 is a longitudinal sectional view showing a general color cathode ray tube.

2 is a longitudinal cross-sectional view and a cross-sectional view showing a conventional in-line uni-electron gun.

3 is a schematic diagram showing a horizontal and vertical deflection magnetic field of the screen.

4 is a graph showing a correlation of focusing voltages required for focusing on a screen.

5 is a longitudinal sectional view and a cross sectional view of an electron gun to which a conventional dynamic voltage is applied.

6 is a waveform diagram showing a dynamic voltage applied to a screen in the configuration of FIG.

7 is a potential distribution diagram due to a voltage difference between a static electrode and a dynamic electrode.

8 is a graph showing the relationship between the screen position and the voltage of the dynamic electrode to form a phase.

9 is a longitudinal cross-sectional view showing an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

3: electron beam 4: electron gun

7: deflection yoke 8: cathode

11: first grid electrode 12: second grid electrode

13: third grid electrode 13a, 13b: electrode

14: fourth grid electrode 15: fifth grid electrode

15a: static electrode 15b: dynamic electrode

16: sixth grid electrode

The present invention relates to an electron gun for a color cathode ray tube, and more specifically, to the deterioration of focus at the periphery due to the use of a self-converging DY, an increase in the deflection angle and the screen size of the deflection yoke. It is to prevent.

1 is a longitudinal cross-sectional view showing a general color cathode ray tube, in which a explosion-proof glass (not shown) is fixed to maintain the explosion-proof property on the front surface, and the front surface is fused to the panel to form a vacuum tube. A panel (2) having a neck portion (2a) integrally formed at the rear portion, an electron gun (4) enclosed in the neck portion, and emitting an electron beam (3) of red, green, and blue colors to the panel side; Red, green, and blue fluorescent surfaces (5) coated in a dot or stripe type on the inner surface of (1), and fixed to the panel so as to maintain a predetermined distance from the fluorescent surface, and serve as color screening, and on the surface, voids It consists of a shadow mask 6 in which numerous small or circular holes are formed, and a deflection yoke 7 which is provided on an outer circumferential surface of the panel and deflects an electron beam emitted from an electron gun.

Therefore, the electron beam radiated from the electron gun hits a predetermined phosphor applied to the inner surface of the panel 1 through the minute hole of the shadow mask 6, which plays a role of color discrimination, thereby reproducing the image signal applied to the electron gun 4 Done.

2 is a longitudinal cross-sectional view and a cross-sectional view showing a conventional in-line Uni-Bi electron gun. The cathode 8 of the electron gun 4 has a heater 9 embedded in the cathode. When the power is supplied from the pin 10 and is heated, it is heated by the heat generated to radiate hot electrons from the cathode. Thus, the emitted three-color electron beam 3 is inlined at a predetermined interval in the direction of the screen from the cathode 8. Through the plurality of electrode holes positioned to reach the screen.

The electron beam 3 starting from the cathode 8 reaches the screen in more detail as follows.

The electron beam 3 emitted from the cathode 8 of the electron gun 4 has a beam forming region consisting of the first grid electrode 11, the second grid electrode 12, and the third grid electrode 13. Uni-Potential Electro Static Lens is formed by a voltage difference applied to the third grid electrode 13, the fourth grid electrode 14, and the fifth grid electrode 15 by controlling and accelerating appropriately. Electron beam is re-focused and accelerated at and then by a Bi-Potential Electro Static Lens formed by a voltage difference applied to the fifth grid electrode 15 and the sixth grid electrode 16. Focus and accelerate.

The electron beam passing through the above-mentioned electrostatic lens, which is the main lens of the electron gun 4, has its path due to the influence of the magnetic field formed by the intensity of the electric current applied to the deflection yoke 7 installed to be wrapped around the outer circumferential surface of the panel 2. Is determined.

As a result, the electron beam 3 traveling through the determined path passes through the microholes (not shown) of the shadow mask 6 provided to be maintained at a predetermined distance from the fluorescent surface 5 and hits the fluorescent surface to emit phosphors. This is reproduced.

In addition, as described above, the electron beams 3 of blue, green, and red are matched at the center of the screen when passing through the electrodes, and the outer beams (electron beams implementing blue and red) are formed on the electrodes constituting the electrostatic lens. Off-set the hole through which is passed through to the hole side formed in the center, or form an electrostatic lens to direct the path of the outer beam toward the center beam (electron beam for green).

Self-convergence deflection yoke is used to ensure that the electron beam 3, which implements the colors of blue, green, and red, as described above in the in-line electron gun, is uniformly matched throughout the screen.

Since the deflection yoke forms a pincushion magnetic field in the horizontal direction and a barrel magnetic field in the vertical direction as shown in FIG. 3, the three electron beams coincide with the entire screen.

At this time, the blue, green, and red electron beams diverge in the horizontal direction and are focused in the vertical direction due to the magnetic field formed by the deflection yoke 7, and the electron beam is applied to the panel 1 geometry. This results in a halo phenomenon that is over-focused in the vertical direction and a very small halo phenomenon in the horizontal direction compared to the vertical direction.

This can be easily seen from the graph of FIG. 4 showing the relationship between the position of the screen and the focusing voltage required for focusing at the location point.

Accordingly, researches for removing the halo phenomenon in which the screen is generated in the vertical direction of the electron beam at the periphery have been conducted for a long time, and FIG. 5 shows an example thereof, which will be described in detail later.

The fifth grid electrode 15 is formed by dividing into an electrode 15a to which a static voltage is applied (hereinafter referred to as a static electrode) and an electrode 15b to which a dynamic voltage is applied (hereinafter referred to as a dynamic electrode). have.

The static electrode 15a is formed with a racetrack-shaped hole h through which three electron beams simultaneously pass to the dynamic electrode 15b side, and at a point retreating from the racetrack-shaped hole at a predetermined interval 3 The plate-shaped electrode 18, each of which has two electron beam through-holes, is positioned, and is vertical to one side of each of the electron-beam passing-holes facing the dynamic electrode 15b side from the plate-shaped electrode 18 located in the static electrode 15a. The partition electrodes 19 are respectively fixed.

A pair of horizontal bulkhead electrodes 20 are fixed to the dynamic electrode 15b parallel to the in-line direction of the electron beam through hole formed toward the static electrode 15a.

At this time, a part of the horizontal bulkhead electrode 20 fixed to the dynamic electrode 15b is configured to be inserted into the inside through a race track-shaped hole h formed in the static electrode 15a.

Therefore, as shown in FIG. 7 by the difference from the constant voltage applied to the static electrode 15a as the voltage shown in FIG. 6 that is variable in synchronization with the deflection yoke 7 is applied to the dynamic electrode in the electrode configuration as described above. Since a quadrupole lens is formed between the static electrode 15a and the dynamic electrode 15b, the electron beam passing through the electrode is made into an elongated electron beam whose horizontal direction is smaller than the vertical direction.

When the electron beam is deflected to the corner of the screen due to the deflection yoke 7 of the electron gun, it compensates for the phenomenon of overfocusing in the vertical direction of the electron beam due to the deflection magnetic field (shortening of the focal length). This will eliminate the halo of the direction.

FIG. 8 is a graph showing the relationship between the position of the screen and the dynamic voltage required to focus the vertical and horizontal directions of the electron beam at the position of the screen when the electron gun having the electrode structure as shown in FIG. 5 is applied to the color cathode ray tube. to be.

As shown in FIG. 5, a general cathode ray tube having an in-line electron gun employing a quadropole lens is used to eliminate the halo phenomenon of the electron beam generated in the vertical direction at the periphery of the screen by using a self-convergence deflection yoke. This results in a cleaner screen.

However, the conventional electron gun has a problem that the resolution of the periphery of the screen is degraded because the halo phenomenon is deepened at the periphery of the screen as shown in FIG.

In addition, when the dynamic voltage is increased to remove the vertical halo of the electron beam at the periphery of the screen, the halo phenomenon is further deepened in the horizontal direction as shown in FIG. 8.

In other words, applying the electron gun of the above-described structure to a more horizontal screen deteriorates the horizontal focusing of the electron beam at the periphery of the screen caused by the self-convergence deflection yoke and cathode ray geometry. The problem arises.

The present invention has been made to solve such a problem in the prior art, by improving its structure to reduce the halo phenomenon of the electron beam in the periphery of the screen caused by the self-convergence deflection yoke and the cathode ray tube geometry. The purpose is.

According to an aspect of the present invention for achieving the above object, the first and second grid electrodes and the uni-type lens for controlling and accelerating the electron beam to focus the electron beam emitted from the cathode on the screen coated with the phosphor The fifth, sixth, and fifth grid electrodes forming a bi-type electrode and the fifth and sixth grid electrodes forming a bi-type electrode are sequentially arranged in the axial direction, wherein the fifth grid electrode is divided into at least two electrodes. In addition, at least one of the electrodes is tuned to the deflection yoke so that a variable voltage is applied, and the third grid electrode is also divided into two or more, so that the electron beam passing hole of the electrode adjacent to the fourth grid electrode is axially symmetric. The electrode is provided with an electron gun for a color cathode ray tube, characterized in that a variable voltage is applied in synchronization with the deflection yoke.

According to another aspect of the invention, the first and second grid electrodes for controlling and accelerating the electron beam in order to focus the electron beam emitted from the cathode on the screen coated with the phosphor, and the third, forming a uni-type lens, Wherein the fifth and sixth grid electrodes and the fifth and sixth grid electrodes forming the bi-shaped electrode are sequentially arranged in the tube axis direction, wherein the fifth grid electrode is divided into at least three or more to form a first electrode. The electron beam through hole of the electrode adjacent to the four-grid electrode is axially symmetrical, and a variable voltage is applied to each of the electrodes adjacent to the fourth and sixth grid electrodes in synchronization with the deflection yoke. An electron gun for a color cathode ray tube is provided.

Hereinafter, with reference to Figure 9 of the accompanying drawings showing an embodiment of the present invention in more detail as follows.

9 is a longitudinal cross-sectional view and a cross-sectional view showing an embodiment of the present invention. The present invention provides a cathode 8 to which electrons are emitted, a first grid electrode 11 to control an electron beam emitted from the cathode, and an acceleration to Second grid electrode 12, third, fourth and fifth grid electrodes 13, 14 and 15 which form a uni-shaped lens to properly focus and accelerate the electron beam so as to focus on the screen on which the phosphor is applied. ), When the fifth and sixth grid electrodes 15 and 16 are arranged on one side of the fourth grid electrode to form a bi-shaped lens, the second grid electrode 12 and the fourth grid electrode are sequentially arranged in the tube axis direction. A third grid electrode 13 positioned between the grid electrodes 14 is divided into at least two electrodes 13a and 13b so that the divided electrodes are provided to be maintained at a predetermined interval.

In the above configuration, the fifth grid electrode 15 is divided into the static electrode 15a and the dynamic electrode 15b and sequentially arranged. The fifth grid electrode 15 is vertically partitioned in the vertical direction of the electron beam passing hole h of the static electrode 15a. The electrode 19 is fixed, and the horizontal beam electrode 20 is formed in the horizontal direction of the electron beam passing hole h 'of the dynamic electrode 15b, and is tuned to the dynamic electrode 15b to the deflection yoke 7 so as to be variable. Allow voltage to be applied.

In addition, the fourth grid electrode is connected to the static electrode 15a of the fifth grid electrode 15 so that the focusing voltage is applied to the electrode 13a positioned on one side of the second grid electrode 12. The electron beam through hole of the other electrode 13b adjacent to the grid electrode 14 is axially symmetrical and connected to the dynamic electrode 15b of the fifth grid electrode so that a variable voltage is applied in synchronization with the deflection yoke 7. .

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

When the electron beam 3 radiated from the cathode 8 moves to the periphery of the screen through the electron beam passing holes formed in the plurality of electrodes arranged inline, the electron beam 3 is positioned adjacent to the fourth grid electrode 14 of the third grid electrodes. The uni-lens formed by the electrodes 13a and 13b, the fourth grid electrode 14 and the fifth grid electrode 15 constituting the third grid electrode by the increased voltage of the electrode 13b is formed in the electron beam. By adjusting the path appropriately, as shown in FIGS. 4 and 8, the electron beam is concentrated in the horizontal direction of the periphery of the screen, thus preventing the electron beam from converging in a horizontal direction.

Due to the formation of the uni-lens, it is possible to reduce the dynamic voltage applied to reduce the vertical halo of the electron beam at the periphery of the screen.

That is, the width of the applied dynamic voltage can be reduced.

Meanwhile, according to another exemplary embodiment of the present invention, the static electrodes 15a of the fifth grid electrode 15 are divided into two to position the divided electrodes to be maintained at a predetermined interval and adjacent to the fourth grid electrode 14. Electron beam through-holes are axisymmetric to the split-formed electrodes that are positioned so that a variable voltage is applied to the electrodes in synchronism with the deflection yoke 7 to exhibit the same operation and effect as the above-described embodiment.

Claims (2)

First and second grid electrodes for accelerating and accelerating the electron beam at the bottom to focus the electron beam emitted from the cathode on a screen coated with phosphors, and third, fourth and fifth grid electrodes forming a uni-type lens; The fifth and sixth grid electrodes forming the bi-type electrode are sequentially arranged in the tube axis direction. The fifth grid electrode is divided into at least two electrodes, and at least one electrode is tuned to the deflection yoke. A variable voltage is applied and the third grid electrode is also divided into two or more so that the electron beam through hole of the electrode adjacent to the fourth grid electrode is axially symmetrical, and the electrode has a variable voltage in synchronization with the deflection yoke. An electron gun for a color cathode ray tube, characterized by being applied. First and second grid electrodes for controlling and accelerating the electron beam to focus the electron beam emitted from the cathode on a screen coated with phosphors, third, fourth and fifth grid electrodes forming a uni-type lens, and The fifth and sixth grid electrodes forming the electrode of the shape are arranged in the axial direction sequentially, wherein the fifth grid electrode is divided into at least three or more to form the electrode of the electrode adjacent to the fourth grid electrode. The electron beam passing hole is an axis symmetrical, and the electron gun for the color cathode ray tube, characterized in that the variable voltage is applied to each of the electrodes adjacent to the fourth, sixth grid electrode adjacent to the deflection yoke is applied.