KR910007660Y1 - Electron gun of color crt - Google Patents

Abstract

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Description

Electron gun for color cathode ray tube

1 is a plan sectional view of an electron gun for a color cathode ray tube according to the present invention.

Figure 2 is a side cross-sectional view of the present invention.

FIG. 3 shows an equipotential line formed between the prefocus electrode and the main focus electrode of the electron gun shown in FIGS. 1 and 2, and (a) shows the state of formation in the lateral direction (horizontal direction). The figure shows the formation state in a longitudinal direction (vertical direction).

4 is a waveform diagram of a parabolic type dynamic voltage applied to the main focus electrode of the electron gun shown in FIG. 1 and FIG.

* Explanation of symbols for main parts of the drawings

KP, KG, KB: cathode G1: control electrode

G2: screen electrode G3: prefocus electrode

G4: main focus electrode G5: final acceleration electrode

GV: vertical auxiliary electrode GH: horizontal auxiliary electrode

3R ₀ , 3G ₀ , 3B ₀ : Beam exit hole of the beam exit side of the prefocus electrode

4Ri, 4Gi, 4Bi: Beam passing hole of the beam incidence side of the main focus electrode

Vd: Dynamic Voltage Vf: Focus Voltage

The present invention relates to an electron gun for a color cathode ray tube with improved astigmatism, and relates to the improvement of the structures of the main focus electrode and the prefocus electrode and to the application of an appropriate correction current thereto.

In addition to the flattening of the panel of the color cathode ray tube, the electron beam scanned from the electron gun by the non-uniform magnetic field caused by the deflection coil causes astigmatism at the periphery of the screen. It is a phenomenon that is caused.

Various alternatives to solve this problem have been sought until now, mainly to intentionally distort the electron beam to achieve normal focusing on the screen surface (especially around the screen).

To this end, a non-uniform electric field (or an asymmetric electric field) is formed around the trajectory through which the beam passes. The beam through hole of each electrode is formed in an elliptical or rectangular shape.

However, the astigmatism correction means due to the beam passage is static, and the beam is distorted at random rate regardless of the dice of the electron beam. Therefore, in order to improve the image quality at the periphery of the screen, the image quality reduction at the periphery of the screen is ignored.

However, if possible, it would be desirable to protect the picture quality in the center of the screen as it is and to improve the picture quality around the screen as desired.

The object of the present invention is to provide an electron gun for color cathode ray tube, which can improve the image quality at the periphery of the screen without compromising the image quality of the center portion of the screen.

In order to achieve the above object, the present invention includes a preposition tripole composed of a cathode, a control grid, and a screen grid, and a prefocus triode and a main focus electrode such as a main focus electrode and a final acceleration electrode for which the electron beam is finally accelerated and controlled. Where one or more prefocus electrodes are provided, a plate-shaped auxiliary electrode (GV) (GH) is provided at the beam incidence side beam through hole of the main focus electrode and the beam out side side beam through hole of the prefocus electrode opposite thereto. Auxiliary electrode (GH) is installed in the prefocus electrode between the beam passing holes and outside of the outer beam passing hole in a vertical direction, and the auxiliary focus (GV) is disposed on the main focus electrode in the vertical direction of the beam passing hole. In a vertical direction, and the prefocus electrode has a constant focus voltage (Vf), and the main focus electrode has the focus voltage as a base voltage, and a male deflection. In synchronization with the arc it is characterized in that to be applied to the dynamic voltage (Vd) which is increased or decreased in a parabolic shape.

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

Cathode KR (KG) KB, control electrode G1, screen electrode G2, prefocus electrode G3, main focus electrode G4, and final acceleration electrode G5 are shown in FIGS. The multi-stage focused electron gun with a bar is shown, and the beam passing holes of all the electrodes are formed on the same side.

And a beam passing hole 3R ₀ (3G ₀ ) (3B ₀ ) formed in the beam exit side plane of the prefocus electrode G3 and a beam passing side plane of the beam incident side plane of the main focus electrode G4 facing the beam exit hole 3R ₀ (3G ₀ ) 3B ₀ . In the balls 4Ri (4Gi) 4Bi, the auxiliary auxiliary electrodes GV and GH are attached to the inside of the electrodes. In other words, the horizontal auxiliary electrodes GH (GH) and GH in the horizontal direction are disposed above and below the beam passing holes 4Ri (4Gi and 4Bi) of the main focus electrode G4, and the beam passing holes of the prefocus electrode G3. Vertical auxiliary electrodes GH (GH) (GH) (GH) are attached between (3R ₀ ) (3G ₀ ) (3B ₀ ) and outside the outer beam through hole 3R ₀ (3B ₀ ). . That is, the vertical and horizontal auxiliary electrodes GH and GH form a four-pole lens, and the vertical auxiliary electrode and the horizontal auxiliary electrode are separately installed on the prefocus electrode G3 and the main focus electrode G4. To form an electric field at a certain distance.

Meanwhile, the plurality of auxiliary electrodes in the horizontal direction may be integrally formed with the upper side and the lower side, respectively.

As shown in FIG. 4, a double parabola type dynamic voltage Vd is applied to the electron gun having such a structure. The dynamic voltage Vd is applied to a horizontal synchronizing signal of one period (1V) synchronized with the vertical synchronizing signal. As synchronized, the voltage changes in the form of high, low, and high during one horizontal period (1H), and the base voltage also changes in the form of high, low, and high during one horizontal period. Fluctuate. The focus voltage, which is the lowest voltage of the dynamic voltage applied to the dynamic electrode, is applied to the prefocus electrode.

According to the present invention, astigmatism at the periphery of the screen is corrected, which will be described in detail.

What is important here is the prefocus lens and the main focus What is important here is the relationship between the prefocus electrode and the auxiliary electrode attached to the main focus electrode and the dynamic voltage and the focus voltage applied thereto. That is, the dynamic voltage is changed with the focus voltage as the lowest base voltage, but when the focus voltage and the dynamic voltage are the same (that is, when the electron beam is scanned at the center of the screen), the prefocus electrode and the main focus electrode are changed at 1/2 horizontal periods. Because of the equipotential, the electrostatic lens cannot be formed with respect to the electron beam, and when the dynamic voltage is higher than the focus voltage (that is, when the electron beam is scanned around the screen), a potential difference is generated between the prefocus electrode and the main focus electrode. In this case, the four-pole lens by the complementary electrode acts, and when the electron beam passes through the prefocus electrode G3, firstly by the auxiliary electrodes GV (GV) (GV) in both vertical directions. The beam beam in the horizontal direction is subjected to a strong focusing force in the horizontal direction by an electric field as shown in FIG. Then, the beam passes through the main focus electrode G4 in a vertical direction by an electric field as shown in (b) of FIG. 3 formed by the auxiliary electrodes GV (GV) (GV) in the vertical direction. The inside is strongly focused.

That is, the electron beam is first focused in the horizontal direction, and then slightly advanced, then focused in the vertical direction.

Therefore, the focusing position in the longitudinal and horizontal directions is corrected by the electron beam focused at different positions in the horizontal and vertical directions as in the prior art, and the focusing force is applied at a predetermined distance to each other as described above. At this time, the four-pole lens acts strongly toward the periphery of the screen because the astigmatism increases toward the periphery of the screen.

That is, when the electron beam is scanned at the center of the screen where astigmatism is not large, the 4-pole lens does not work, and thus the distortion of the unnecessary electron beam is prevented, and when the electron beam is scanned around the screen where the astigmatism increases, the 4-pole lens is To correct astigmatism.

As such, the present invention enables the production of a color cathode ray tube with a very improved image quality by ensuring the image quality evenly at the center of the screen and the periphery of the screen, and has a very excellent astigmatism correction means than any conventional astigmatism correction means.

Claims (1)

A color is provided with a pre-triode consisting of a cathode, a control grid, and a screen grid, a main focus electrode and a final acceleration electrode for the final acceleration control of the electron beam, and one or more prefocus electrodes positioned between the pre-triode and the main focus electrode. In the electron gun for cathode ray tube, an auxiliary electrode (GH) is disposed in the vertical direction between the electron beam through hole inside the beam incidence side plane of the main focus electrode and outside the outer beam through hole, facing the main focus electrode. Auxiliary electrode GV is provided in the horizontal direction above and below the beam passing hole inside the plane of the beam exit side of the prefocus electrode, a predetermined focus voltage Vf is applied to the prefocus electrode, and the focus voltage is applied to the main focus electrode. It is characterized by applying a dynamic voltage (Vd) which increases parabolic in synchronism with the horizontal deflection signal with the base voltage as the base voltage. Color cathode-ray tubes that gun.