KR20010017763A - electron gun for color cathode ray tube - Google Patents

Abstract

The present invention relates to a structure of a connector connected between a stem pin and a dynamic electrode in order to apply a dynamic voltage to the dynamic electrode and a dynamic electrode to which the dynamic voltage is applied. By minimizing the discharge of the electric field to the side to minimize the amount of charge generated between the electron gun and the inner wall of the neck portion to remove the noise generated inside the cathode ray tube and to improve the withstand voltage characteristics of the cathode ray tube.

To this end, the cathode 10 to which electrons are emitted, the first and second electrodes 11 and 12 that control and accelerate the amount of electron beams emitted from the cathode, and are sequentially installed on one side of the second electrode and accelerated In the electron gun for color cathode ray tube consisting of the 3rd, 4th electrode 13,14 which shear-concentrates the electron beam which were carried out, and the several electrode which is installed in order on one side of the said 4th electrode, and narrowly condenses the electron beam which was focused. In order to minimize the amount of charge distributed between the inner wall of the unit 3a and the electron gun 4, the surface of the connector 21 connecting the stem pin 20 and the dynamic electrode 15b or the dynamic electrode 15b to which a dynamic voltage is applied is applied. It is made by coating the insulating material (23, 24) on the outer surface of the).

Description

Electron gun for color cathode ray tube

The present invention relates to an electron gun used in a color cathode ray tube or a high-definition industrial monitor, and more particularly, a dynamic electrode to which a dynamic voltage is applied, and a stem pin and a dynamic electrode to apply a dynamic voltage to the dynamic electrode. It relates to the structure of the connector (Connector) connected between.

FIG. 1 is a side view showing a general color cathode ray tube in a partial cross section, and red, green, and red phosphors are applied to an inner surface of a panel 1 to form a fluorescent surface 2, and a neck portion 3a behind the panel. The funnel 3, in which the electron gun 4 is enclosed, is fused by glass, and the inside thereof maintains a high vacuum of about 10 ^-7 Torr.

In the region proximate to the fluorescent surface 2 of the inner surface of the panel 1, a shadow mask 6 serving as color discrimination of the electron beam 5 scanned by the electron gun 4 is supported by the support frame 7. It is installed.

In addition, a deflection yoke 8 is provided at the interface between the funnel 3 and the neck portion 3a to deflect the electron beam 5 scanned by the electron gun to the entire fluorescent surface. An electron beam 5 is provided on the outer circumferential surface of the neck portion. Magnets 2, 4, and 6 poles are provided to correct the trajectory of the trajectory so as to strike the predetermined phosphor.

The electron gun 4 which emits an electron beam in the cathode ray tube constructed as described above is constructed from three electron beams (not shown) applied to the surface as three are arranged inline and applied with voltage as shown in FIG. A cathode 10 for emitting an electron beam, a first electrode 11 disposed close to the cathode to control an amount of radiation of the electron beam, and placed close to the first electrode to accelerate and pull an electron beam emitted from the cathode. Third and fourth electrodes 13 and 14 disposed adjacent to the second electrode 12, the second electrode to form a shear focusing lens between the electrodes, and disposed between the electrode and the fourth electrode. In the fifth and sixth electrodes 15 and 16 forming the electrostatic focusing lens, and a shield cup 17 fixed to the sixth electrode to shield the external electric field and the magnetic field. Plum between bead glass (18) Is maintains a constant interval.

A connector 21 is connected between each electrode and the stem pin 20 fixed through the stem 19 so that a different voltage is applied to each electrode through the connector, and the stem 19 is necked. It is fixed at the end of the part 3a in a sealed state.

Therefore, when electric power is applied from the stem pin 20 to the heater 22 in the cathode 10 constituting the triode of the electron gun 4 and the heater generates heat, the hot electrons are emitted from the electron emission material applied to the tip of the cathode.

The hot electrons emitted as described above are accelerated and focused while passing through a plurality of electrodes in order to be maintained at a constant distance from the fluorescent surface 2, and then pass through a shadow mask 6 that serves as color screening, and then collide with the fluorescent surface 2 to be predetermined. Since the phosphor emits light, the screen is reproduced.

At this time, in order to reproduce an image, the electron beam 5 must be sequentially scanned over the entire area of the screen. For this purpose, a self-convergence deflection yoke using a non-uniform magnetic field is applied.

The magnetic field distribution generated in the deflection yoke 8 using the self-focusing type can be described by dividing the bipolar component and the quadrupole component, as shown in FIGS. 3A and 3B. The DY lens, which is a four-pole component, focuses the electron beam in the vertical direction and diverges in the horizontal direction, so that the electron beam in the vertical direction is focused at a shorter distance than the electron beam in the horizontal direction. This convex rise causes halo, which leads to deterioration of image quality.

Therefore, in order to solve the above problem, as shown in FIGS. 3C and 3D, the quadrupole component is generated in the electron gun to cancel the quadrupole component generated in the self-focusing deflection yoke, thereby allowing the electron beams in the horizontal and vertical directions to be simultaneously moved on the screen. It is focused to the point.

That is, in order to form a quadrupole lens, the fifth electrode 15 is divided into two parts of the first focusing electrode 15a and the second focusing electrode 15b, and a low voltage is applied to the first focusing electrode 15a. High voltages are applied to the focusing electrodes 15b, respectively.

Accordingly, a potential difference is generated between the first and second focusing electrodes 15a and 15b to form a quadrupole lens, thereby solving the above-described problem.

However, due to the difference in electron beam travel distance between the center and the periphery of the screen, the electron beam is still focused at the front of the screen, causing a halo phenomenon.

Therefore, in order to solve this problem, when the electron beam is deflected to the periphery of the screen, a parabola type dynamic voltage (variable voltage) synchronized with the deflection frequency is applied to the second focusing electrode (hereinafter referred to as "dynamic electrode") 15b. A method of adjusting the focal length of the electron beam is adopted while reducing the intensity of the electrostatic focusing lens.

Here, a constant charge is induced between each electrode to which a constant voltage is applied and the neck portion 3a due to the field emission from the electrode, and the amount of charge increases as the voltage increases.

When the dynamic voltage of the parabola waveform, which is a variable voltage, is applied to the dynamic electrode 15b through the connector 21 between the charges generated in this unstable state, irregular movement of mobile electrons is induced. It collides with microparticles that may exist inside, causing ionization.

As described above, when electrons collide and are ionized, cations and electrons are generated, and two increased electrons collide with another molecule to generate four electrons. As the above process is repeated, an avalanche phenomenon occurs.

Due to such an avalanche, noise amplified by collision of electrons is generated inside the cathode ray tube, and the degree of the noise is measured about 20 to 70 db at a frequency of 6 to 12 kHz.

In addition, the inside of the cathode ray tube is almost insulated with a high vacuum of about 10 ^-7 Torr, but the larger the avalanche proportional to the number of electrodes to which voltage and dynamic voltage is applied and the number of fine molecules in the cathode ray tube, that is, The higher the number of fine molecules, the lower the breakdown voltage caused by an avalanche, so that a stray phenomenon occurs in the inside of the cathode ray tube, which causes sparks due to the breakdown.

As a way to prevent the withstand voltage characteristics of the cathode ray tube from being degraded, the knocking method of removing foreign substances from the electrode by electrolytically polishing each electrode and applying high pressure to the electrode through six processes is disclosed in Korean Patent No. 95-43310. Has been filed.

The knocking method can improve the withstand voltage characteristics by instantaneous removal of foreign substances present in the cathode ray tube, but it is easier to discharge the electric field from the electropolished electrode, which is caused by the foreign matter that can be generated during operation of the cathode ray tube. Because it causes stray phenomenon, the fundamental problem cannot be solved.

The present invention has been made to solve such a problem in the prior art, by improving its structure to suppress the phenomenon that the electric field is emitted to the neck portion from each electrode to the maximum to minimize the amount of charge generated between the electron gun and the inner wall of the neck portion cathode The purpose is to remove the noise generated inside the tube and to improve the withstand voltage characteristics in the cathode ray tube.

According to an aspect of the present invention for achieving the above object, the first and second electrodes for controlling and accelerating the amount of the electron beam emitted from the cathode, and the first electrode, and the second electrode to sequentially An electron gun for a color cathode ray tube composed of third and fourth electrodes for shear-focusing an accelerated electron beam, and a plurality of electrodes that are arranged on one side of the fourth electrode in order to narrowly focus the electron beam that is shear-focused, wherein the inner wall of the neck portion and the electron gun An electron gun for a color cathode ray tube is provided, wherein an insulating material is coated on a surface of a connector connecting a stem pin and a dynamic electrode or an outer surface of an electrode to which a dynamic voltage is applied in order to minimize the amount of charges distributed to the electrode.

Figure 1 is a side view showing a typical color cathode ray tube in some cross section

2 is a longitudinal cross-sectional view of the electron gun applied to FIG.

3A to 3D illustrate distortion of an electron beam spot due to a non-uniform magnetic field of a self-focusing deflection yoke.

3A is a distribution diagram of a pin cushion type horizontal deflection magnetic field

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

4 is a schematic view showing first and second focusing electrodes;

5 is a schematic view for explaining a state in which an electric field is emitted between the neck portion and the electrode;

6 is a longitudinal sectional view showing the connector of the present invention;

7 is a front view showing the dynamic electrode of the present invention.

Explanation of symbols for main parts of the drawings

3a: neck part 4: electron gun

10 negative electrode 11 first electrode

12 second electrode 13 third electrode

14: fourth electrode 15b: dynamic electrode

20: stem pin 21: connector

23, 24: insulation material

Hereinafter, the present invention will be described in more detail with reference to FIGS. 6 and 7 as an embodiment.

6 is a longitudinal cross-sectional view showing a connector of the present invention and Figure 7 is a front view showing a dynamic electrode of the present invention, the present invention is a conductive material connecting the stem pin 20 and the dynamic electrode 15b as shown in FIG. The insulating material 23 is coated on the surface of the connector 21 at a predetermined thickness.

The coating thickness of the insulating material 23 must be set to 10 kPa or more to realize the coating thickness.

If the thickness of the insulating material 23 is less than or equal to 10 μs, electrons move through the insulating material 23 to the other side due to the tunnel effect, thereby failing to obtain a desired effect.

In addition, as shown in FIG. 7, the insulating material 24 is coated with a predetermined thickness on the circumferential surface (border) of the dynamic electrode 15b. In this case, the thickness of the insulating material 24 is 10 Å or more as described above. It is covered.

At this time, the supporter 15c portion of the dynamic electrode 15b does not need to cover the insulating material 24.

This is because when the dynamic electrode 15b is fixed to the bead glass 18 together with the other electrode, a portion where the insulating material 24 is not coated is buried in the bead glass.

Accordingly, by restraining and minimizing the movement of electrons generated between the dynamic electrode 15b and the inner wall of the neck portion 3a of the cathode ray tube during operation of the electron gun, noise generated by irregular movement of the electrons can be eliminated.

In addition, when the electrical characteristics were examined, the leakage current generated by the current flowing through the inside of the dynamic electrode 15b and the connector 21 and the current flowing along the surface thereof was 0 μA, indicating that the withstand voltage characteristics were enhanced. Could.

As described above, the present invention minimizes the amount of charge generated between the electron gun 4 and the neck portion 3a by the simple structure of covering the insulating material 23 and 24 on the connector 21 and the dynamic electrode 15b. As a result, the amount of leakage current of the cathode ray tube can be maintained at almost " 0 " (zero), thereby improving noise cancellation and withstand voltage characteristics caused by irregular electron transfer.

Claims (4)

First and second electrodes for controlling and accelerating the amount of electron beams emitted from the cathode, third and fourth electrodes sequentially arranged on one side of the second electrode to shear-focus the accelerated electron beam; In the electron gun for a color cathode ray tube consisting of a plurality of electrodes that are sequentially installed on one side of the fourth electrode for narrowly focusing the sheared electron beam, the insulating material is coated on the surface of the connector connecting the stem pin and the dynamic electrode Electron gun for colored cathode ray tubes. The method of claim 1, An electron gun for color cathode ray tubes, characterized in that the thickness of the insulating material coated on the outer surface of the connector is 10Å or more. First and second electrodes for controlling and accelerating the amount of electron beams emitted from the cathode, third and fourth electrodes sequentially arranged on one side of the second electrode to shear-focus the accelerated electron beam; In the electron gun for a color cathode ray tube composed of a plurality of electrodes that are sequentially installed on one side of the fourth electrode for narrowly focusing the electron beam focused in front, the insulating material is coated on the outer peripheral surface of the dynamic electrode to which the dynamic voltage is applied Electron gun for colored cathode ray tubes. The method of claim 3, wherein An electron gun for color cathode ray tubes, characterized in that the thickness of the insulating material coated on the circumferential surface of the dynamic electrode is 10 kPa or more.