KR100339349B1 - electron gun in 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 a color cathode ray tube, and in particular, it is possible to reduce the electric field density between the focusing electrodes by widening the interval between the focusing electrodes among the electrodes of the electron gun.

The present invention for this purpose, shearing focusing the first and second electrodes for controlling and accelerating the amount of electron beam emitted from the cathode, and sequentially installed on one side of the second electrode to accelerate the electron beam A third and fourth electrodes, a plurality of focusing electrodes sequentially installed on one side of the fourth electrode and focusing the electron beam focused at the front end, and a dynamic voltage applied to at least one of the focusing electrodes;

The distance between the fourth electrode and the other electrodes located on both sides thereof is 0.9 to 1.5 mm.

Description

Electron gun in color cathode ray tube

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color cathode ray tube, and more particularly, to an electron gun for a color cathode ray tube, in which an electric field density between focusing electrodes can be reduced as the interval between focusing electrodes of each electrode of the electron gun is widened.

In general, as shown in FIG. 1, a color CRT tube is formed on the inner surface of the panel 1 by applying red, green, and blue phosphors to form a fluorescent surface 1a, and a bottleneck shaped neck at the edge of the inner surface of the panel 1. The funnel 2 having the portions 2a is fused by frit glass.

The neck portion 2a is filled with an electron gun 5 that emits an electron beam 4, and a mask that serves to color-select the electron beam 4 inside the junction of the funnel 2 on the inner surface of the panel 1. (6) is fixed by the frame (7).

In addition, a deflection yoke 8 is provided at the outer boundary of the funnel 2 and the neck 2a to deflect the electron beam 4 emitted by the electron gun 5 to the entire fluorescent surface 1a. At the end of (2a), a magnet 9 is provided to correct its trajectory so that the electron beam 4 can strike the fluorescent surface 1a accurately.

Meanwhile, as shown in FIG. 2, the electron gun 5 includes three cathodes 50 each emitting red, green, and blue electron beams according to the application of a voltage, and the electron guns 5 are disposed in close proximity to the cathodes. The first electrode 51 for controlling, the second electrode 52 which is installed in proximity to the first electrode and accelerates the emitted electron beam 4 in the advancing direction, and the auxiliary focusing lens which is installed in proximity to the second electrode. It is fixed to the third and fourth electrodes 53 and 54 to be formed, the fifth and sixth electrodes 55 and 56 which are provided in close proximity to the fourth electrode to form a main electrostatic focusing lens, and are fixed to the sixth electrode. It is comprised by the shield cup 57 which shields an external electric field and a magnetic field, and each of these electrodes is supported by the bead glass 58 so that mutually predetermined space may be maintained.

Therefore, when a heater (not shown) installed in the cathode 50 is generated by the power applied by the stem pin 10, hot electrons are emitted from the electron emission material applied to the tip of the cathode 50.

The emitted electrons are accelerated and focused while passing through the plurality of electrodes, pass through the mask 6 maintaining a constant distance from the fluorescent surface 1a, and then collide with the fluorescent surface 1a to emit phosphors. This is reproduced.

At this time, in order to reproduce the image, the electron beams 4 must be sequentially scanned over the entire area of the screen. For this purpose, a self-converging deflection yoke 8 using a non-uniform magnetic field is applied.

That is, as shown in FIGS. 3A and 3B, the distribution of the magnetic field generated in the deflection yoke 8 to which the self-focusing type is applied is a pin cushion type, and the vertical deflection field is a barrel. By preventing the misconvergence at the periphery of the fluorescent surface, the electron beam 4 is deflected in the horizontal and vertical directions by Fleming's left hand law.

However, as illustrated in FIGS. 3C and 3D, the above-described horizontal and vertical deflection magnetic fields can be described by dividing the bipolar component and the quadrupole component, and the bipolar component serves to deflect the electron beam 4 in the horizontal and vertical directions. And the quadrupole component moves the electron beam 4 in the vertical direction. By focusing and diverging in the horizontal direction, the electron beam in the vertical direction is focused at a shorter distance than the electron beam in the horizontal direction, causing a halo phenomenon in which the vertical direction of the electron beam rises convexly on the screen. Will cause deterioration.

This problem can be caused by the four-pole component generated in the electron gun to cancel the four-pole component generated in the self-focused deflection yoke as shown in Figures 3c and 3d so that the electron beam in the horizontal and vertical direction can be focused at one point at the same time.

That is, in order to form a quadrupole lens, the fifth electrode 55 is divided into two, a low voltage is applied to one electrode, and a high voltage is applied to the other electrode, thereby generating a potential difference at the dynamic quadrupole electrode. By forming a lens, astigmatism can be corrected.

However, the halo phenomenon still occurs as the electron beam is focused in front of the screen due to the difference in the electron beam moving distance between the center and the peripheral portion of the screen.

To solve this problem, when the electron beam is deflected to the periphery of the screen, a dynamic voltage (variable voltage) of a parabola waveform synchronized with the deflection frequency is applied to any one of the fifth electrodes 55 to weaken the intensity of the main electrostatic focusing lens. A method of adjusting the focal length of the electron beam is mainly employed.

At this time, a constant charge due to emission from the electrode is induced between each of the electrodes to which the constant voltage is applied and the neck portion, and the amount of the charge increases as the charge increases.

When the dynamic voltage of the parabola waveform, which is a variable voltage, is applied to the dynamic electrode through the connector, irregular motion of mobile electrons is induced between the charges generated in an unstable state. Collision causes ionization.

When electrons collide and are ionized as described above, cations and electrons are generated, and the electrons increased by two collide with another molecule to form four electrons, and the above process is repeated, resulting in an electron avalanche phenomenon.

The electrons collide with the electrodes, and vibrations of the electrode and the bead glass are transferred to a BSC (bulb space contact spring) 11 for fixing the electron gun 5 to the neck portion 2a. Noise is generated through 2a).

In this way, the amplified noise generated by the collision between electrons is usually measured at about 20 to 70 db at a frequency of 6 to 12 kHz.

In addition, the inside of the CRT is almost insulated because of the high vacuum of 10 ⁻⁷ , but the insulation is caused by the avalanche as the number of avalanches proportional to the number of electrodes to which voltage and dynamic voltage are applied and the number of fine molecules in the CRT are increased. The breakdown voltage is lowered, so that a so-called stray is generated inside the CRT due to insulation breakdown, which causes the breakdown voltage characteristic of the CRT.

In particular, in the conventional electron gun, even if a dynamic voltage is applied to at least two focusing electrodes in order to obtain improved focusing characteristics, a distance d between the electrodes adjacent to the front and rear surfaces of the fourth electrode 54 is about 0.6 mm. Therefore, there is a problem in that a stray emisson is generated in which electrons move irregularly due to an increase in electric field density between electrodes.

In addition, when a high dynamic voltage is applied to the focusing electrode, the noise generation rate is doubled, resulting in a failure of the CRT.

The present invention has been made to solve the conventional problems as described above, the object of which is to minimize the amount of charge between the electron gun and the neck portion, each electrode of the electron gun.

Embodiment of the present invention for achieving the above object,

First and second electrodes for controlling and accelerating the amount of electron beams emitted from the cathode, third and fourth electrodes sequentially installed on one side of the second electrode to focus the accelerated electron beam; A plurality of focusing electrodes sequentially installed at one side of the fourth electrode and focusing the electron beam focused at the front end, and a dynamic voltage applied to at least one of the focusing electrodes;

There is provided an electron gun for a color cathode ray tube having a distance of 0.9 to 1.5 mm between the fourth electrode and other electrodes located on both sides thereof.

1 is a longitudinal sectional view showing an example of a general electron gun;

2 is a block diagram of a conventional electron gun

3A is a distribution diagram of a pin-cushioned horizontal deflection field

3b is a distribution diagram of the barrel-type vertical deflection field;

3C is an exploded explanatory diagram of the dipole and quadrupole components of a pincushioned horizontal deflection magnetic field;

3D is an exploded explanatory diagram of the dipole and quadrupole components of the barrel-type vertical deflection field;

4 is an embodiment of the present invention

5 is another embodiment of the present invention

Explanation of symbols for main parts of the drawings

54: fourth electrode 55a: fifth-1 electrode

59: focusing electrode

4 is an embodiment of the electron gun of the present invention, and FIG. 5 is another embodiment of the electron gun of the present invention. Hereinafter, the electron gun for the color cathode ray tube of the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, as shown in Figs. 4 and 5, the third electrode 53 and the fifth electrode which are electrodes located on both sides of the fourth electrode 54 for focusing the electron beam 4 irrespective of the amount of application of the dynamic voltage. The distance d ₁ between the electrodes 55a is about 0.9 to 1.5 mm.

In particular, FIG. 4 illustrates an embodiment in which the dynamic voltage Vd is applied to at least two of the plurality of focusing electrodes 59 including the fourth electrode 54. As the distance (d ₁ ) between the and the adjacent focusing electrodes is extended, the electric field density thereof can be lowered, so that the irregular electron movement can be alleviated somewhat.

FIG. 5 illustrates an embodiment in which the dynamic voltage Vd is applied to only one of the plurality of focusing electrodes 59 including the fourth electrode 54. 54) by extending the distance (d ₁ ) between the focusing electrode and the adjacent focusing electrode, the electric field density can be lowered, thereby making it possible to reliably reduce irregular electron transfer.

When comparing the above two embodiments, the former (in the case of applying the dynamic voltage to the two electrodes) is a high voltage is applied, so that the rate of decrease of the electric field density is slightly reduced, the advantage that the focus characteristic can be maintained.

In the latter case (when the dynamic voltage is applied to only one electrode), since the low voltage is applied, the rate of decrease of the electric field density is good, but the focus characteristic may be slightly lowered.

In any case, by solving the dense electric field density between the focusing electrodes, it is possible to reduce the amount of irregular interelectrons and thereby reduce the noise.

On the other hand, the reason why the distance d ₁ between the fourth electrode 54 and the focusing electrode adjacent thereto is limited to 0.9 to 1.5 mm is because it can have the best electric field density when having such a distance, If the spacing has a problem of increasing the electric field density, and having a spacing greater than or equal to the above range causes a problem that the focus characteristic is degraded due to the strengthening of the shear focusing lens.

As such, the present invention minimizes the amount of charge generated between the electrode and the neck portion to which the dynamic voltage is applied, and between the electrodes, thereby increasing the noise cancellation and withstand voltage characteristics caused by irregular electron transfer.

Claims (2)

First and second electrodes for controlling and accelerating the amount of electron beams emitted from the cathode, third and fourth electrodes sequentially installed on one side of the second electrode to focus the accelerated electron beam; A plurality of focusing electrodes sequentially installed at one side of the fourth electrode and focusing the electron beam focused at the front end, and a dynamic voltage applied to at least one of the focusing electrodes; An electron gun for color cathode ray tubes, wherein an interval between the fourth electrode and other electrodes located on both sides thereof is 0.9 to 1.5 mm. The method of claim 1, Electron gun for color cathode ray tubes in which a dynamic voltage is applied to only one of a plurality of focusing electrodes.