KR940004440B1 - Electron gun for cathode-ray tube - Google Patents

Abstract

The electron gun is disclosed in which parallel vertical blades are formed on both edges of electron beam passing holes formed on the outgoing surface of a focus electrode toward a cathode, and horizontal blades extending toward the cathode are formed on the upper and lower portions of electron beam passing holes formed on the incoming surface of a dynamic focus electrode to be inserted into the electron beam passing holes of the focus electrode, thereby compensating for the ununiform magnetic field of a deflection yoke.

Description

Electron gun for colored cathode ray tube

1 is a partially cutaway perspective view of an electron gun for a conventional color cathode ray tube.

2 is a partially cutaway perspective view of an electron gun for a color cathode ray tube according to the present invention;

3 is an exploded perspective view showing an extract of the focus electrode and the dynamic focus electrode shown in FIG.

4 is a view showing the effect of the vertical braid and the horizontal braid shown in FIG. 1 on the electron beam.

* Explanation of symbols for main parts of the drawings

11 cathode 12 control electrode

13 screen electrode 14 focus electrode

14a: emitting side (of focus electrode) 14b: vertical braid

15: dynamic focus electrode 15a: incident side (of focus electrode)

15b: horizontal blade 16: final acceleration electrode

VF: Dynamic Focus Voltage Vfd: Dynamic Focus Voltage

Ve: Anode Wood Voltage

The present invention relates to an electron gun for a color cathode ray tube mounted on the neck portion of a cathode ray tube to emit an electron beam, and more particularly, corrects astigmatism and focus characteristics due to deflection yoke that deflects the electron beam. It relates to an electron gun that can be formed uniformly on the screen.

The resolution of the color cathode ray tube depends on the size and shape of the electron beam landing on the fluorescent surface. Therefore, in order to obtain high resolution, it is important that the electron beam spot landing on the fluorescent surface is as small as possible, free from distortion, and free from halo. However, conventional color cathode ray tube adopts in-line self-convergence method by adopting deflection yoke with R, G, B electron guns arranged inline type and horizontal deflection field with pincushion field and vertical deflection field with barrel field. The non-uniform magnetic field of the deflection yoke causes astigmatism of the electron beam generated from the electron gun and landing on the fluorescent film.

That is, when the electron beam generated from the electron gun is landed at the center of the fluorescent film, it is not influenced by the deflection magnetic field, and thus a circular electron beam spot with no phase spread can be obtained, but when the electron beam is deflected to the periphery of the fluorescent film, Direction and the overconnected state in the vertical direction has a high brightness core portion where the electron beam is long deformed in the horizontal direction, and a low brightness upper spread portion in the vertical direction, thereby degrading the resolution.

Figure 1 shows an example of a conventional electron gun for color cathode ray tube to solve this problem.

This includes the cathode (2), the control electrode (3) and the screen electrode (4) forming the pre-triode tube portion, the focus electrode (5), the dynamic focus electrode (6) and the final acceleration electrode (7) forming the auxiliary and main lens systems. These are arranged in this order, the longitudinal electron beam through hole (5H) and the horizontal electron beam through hole (6H) are formed on the surfaces of the focus electrode (5) and the dynamic focus electrode (6) facing each other, respectively. do. A focus voltage Vf and a final acceleration voltage Ve are applied to the focus electrode 15 and the final acceleration electrode 16, and the focus voltage Vf is a ground voltage to the dynamic focus electrode V5 and is deflected. A parabolic type dynamic focus voltage Vfd, which is changed parabolic according to the vertical synchronizing signal of the yoke and also varies according to the horizontal synchronizing signal, is applied.

In the conventional color cathode ray tube electron gun 1 configured as described above, the dynamic focus voltage Vfd is applied to the dynamic focus electrode 16 when the electron beam is not planarized, that is, when the electron beam emitted from the electron gun 1 is landed at the center of the fluorescent surface. Since only the focus voltage Vf, which is the base voltage, is applied, no quadrupole lens is formed between the focus electrode 5 and the dynamic focus electrode 6, so that the focus electrode 5 and the final acceleration electrode are not applied. The main lens formed between (7) causes the electron beam to land in the optimal state at the center of the fluorescent surface. When the electron beam is deflected to the periphery of the fluorescent film by the non-uniform magnetic field of the deflection yoke, the dynamic focus voltage Vfd, which is varied in accordance with the vertical deflection synchronous signal and the horizontal deflection synchronous signal, is applied to the dynamic focus electrode 6, thereby providing the focus electrode. A quadrupole lens is formed between (5) and the dynamic focus electrode 6. In other words, it is horizontal in the vertical direction by the longitudinal electron beam through hole 5H formed on the exit side of the focus electrode 5 and the horizontal electron beam total pore 6H formed on the incident side of the dynamic focus electrode 6. A focusing lens and a strong diverging lens, which are relatively weak compared to the direction, are formed, and a focusing lens and a weak diverging lens, which are relatively stronger than the vertical direction, are formed in the horizontal direction. Therefore, the electron beam passing through the beam is focused in the horizontal direction and diverges in the vertical direction, and thus has an elongated beam cross section.

When the elongated electron beam is deflected to the periphery of the fluorescent film after passing through the main lens, the distortion of the electron beam due to the non-uniform magnetic field of the deflection yoke is corrected to form a circular electron beam at the periphery of the fluorescent film. However, the above-described electron gun 1 for the color cathode ray tube passes through an elongated electron beam through hole 5H and an elongated electron beam through the exit side of the focus electrode 5 and the incident side of the dynamic focus electrode 6, respectively. Since the holes 6H are formed, it is difficult to assemble these elongated electron beam through holes 5H and the horizontally elongated electron beam through holes 6H so as to intersect correctly. In particular, since the dynamic focus electrode 6 and the focus electrode 5 forming the quadrupole lens are spaced apart from each other by a predetermined distance, there is a problem that the electrostatic lens is distorted by an external electric field, that is, a leakage field flowing through the neck portion.

The present invention has been made to solve the above problem, and by correcting the astigmatism and focus characteristics of the electron beam due to the non-uniform magnetic field of the deflection yoke to form a uniform beam spot that does not occur in the fluorescent surface of the entire fluorescent surface to improve the resolution It is an object of the present invention to provide an electron gun for colored cathode ray tubes.

In order to achieve the above object, the present invention provides a cathode for a color cathode ray tube provided with a cathode, a control electrode, and a screen electrode, and a focus electrode, a dynamic focus electrode, and a final acceleration electrode forming an auxiliary and main lens system. A vertical blade parallel to both edges of each electron beam through hole formed on the emission side of the focus electrode is formed on the cathode side, and the cathode beam is formed on the incident side of the dynamic focus electrode on the cathode side toward the cathode side. It characterized in that the horizontal blade is formed so that the horizontal blade is inserted into the electron beam through hole of the focus electrode.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

The electron gun 10 for the color cathode ray tube according to the present invention shown in FIG. 2 forms an auxiliary and main lens system with the cathode 11 control electrode 12 and the screen electrode 13 constituting the pre-triode tube part, and the focus electrode. 14 and the dynamic focusing electrode 15 and the final accelerating electrode 16 are arranged in this order and formed at both edges of the electron beam passing hole 14H formed at the emission side surface 14a of the focus electrode 14. As shown in FIG. 3, in accordance with the features of the present invention, the vertical braids 14b parallel to each other are formed on the cathode 11 side, and the electron beam passing holes formed on the incident side surface 15a of the dynamic focus electrode 15 ( A horizontal blade 15b extending a predetermined length from the cathode side 11 is formed in the upper and lower portions of the 15H) so that the horizontal blade 15b is formed on the emission side surface 14a of the focus electrode 14. Inserted into 14H) . The horizontal blade 15b formed on the incident side surface 15a of the dynamic focus electrode 15 is preferably formed by lancing the incident side surface 15a. The electron beam through hole 14H formed in the emission side surface 14a of the focus electrode 14 has an elongated rectangular hole shape in which the vertical width WV is larger than the horizontal width WH. The horizontal width WH is formed to be substantially equal to the diameter D of the electron beam passing hole 15H formed in the incident side surface 15a of the dynamic focus electrode 15. In addition, a predetermined focus voltage Vf is applied to the focus electrode 14, and the focus voltage Vf is applied to the dynamic focus electrode 15 as a base voltage, and is changed parabolic according to a vertical synchronization signal of deflection yoke. In addition, the dynamic focus voltage Vfd, which is variable according to the horizontal synchronization signal, is applied, and the high voltage anode voltage Ve is applied to the final acceleration electrode 16.

Referring to the operation of the electron gun for color cathode ray tube according to the present invention configured as described above are as follows.

In the electron gun for the color cathode ray tube according to the present invention, a prefocus lens is formed on the screen electrode 13 and the focus electrode 14 as a respective potential is applied to each electrode, and the focus electrode 14 and the dynamic focus electrode are provided. A quadrupole lens is formed between the fifteen lenses depending on whether the dynamic focus voltage Vfd is applied, and a main lens is formed between the dynamic focus electrode 15 and the final acceleration electrode 16. Therefore, the electron beam emitted from the cathode 11 passes through the electrostatic lens formed between the electrodes, and then lands on the entire fluorescent film. The electron beam is not deflected by the deflection yoke and lands in the central portion of the fluorescent film. In this case, the dynamic focus voltage Vfd is not applied to the dynamic focus electrode 15, and only the focus voltage Vf, which is a base voltage, is applied. Thus, an equipotential is formed between the focus electrode 14 and the dynamic focus electrode 15. The focus voltage Vf is applied. Therefore, a quadrupole lens is not formed between the focus electrode 14 and the dynamic focus electrode 15, and the electron beam emitted from the cathode 11 passes through the prefocus lens, and then the final acceleration is performed with the dynamic focus electrode 15. Passing through the central portion of the main lens formed between the electrodes 16 is landing in the optimal state in the center of the fluorescent film.

When the electron beam emitted from the cathode 11 is deflected to the periphery of the fluorescent film by the deflection yoke, a dynamic focus voltage Vfd is applied to the dynamic focus electrode 15, thereby providing the focus electrode 14 and A quadrupole lens is formed between the dynamic focus electrodes 15. Therefore, the electron beam emitted from the cathode 11 passes through the prefocus lens and the quadrupole lens and is lengthened to pass through the main lens, and is deflected by the deflection yoke to be scanned at the periphery of the fluorescent film. When the elongated electron beam is deflected by the deflection yoke, the electron beam spot that is distorted by the uneven magnetic field and landed on the fluorescent film is circular. That is, the focus electrode 14 and the dynamic focus electrode 15 forming the quadrupole lens are respectively formed in the electron beam through hole 14H formed at the emission side surface 14a and the electron beam through hole 15H formed in the incident side surface 15a. Since the vertical blade 14b and the horizontal blade 15b are formed and the horizontal blade 15b is inserted into the electron beam passing hole 14H formed on the emission side surface 14a of the focus electrode 15, the electron beam passing hole ( The electron beam B passing through 14H and 15H receives a weak divergence force and a strong focusing force under the influence of the vertical blade 14b to which the focus voltage Vf is applied in the horizontal direction as shown in FIG. In the vertical direction, a strong divergence force and a weak focusing force are received by the horizontal blade 15b to which the dynamic focus voltage Vfd is applied. Therefore, the electron beam passing through this forms an elongate cross section. The electron beam, which is elongated while passing through the quadrupole lens, passes through the main lens and then deflects to the periphery of the fluorescent surface by the deflection yoke. The distortion caused by the compensation is compensated to have a circular electron beam spot when landing around the fluorescent surface. In addition, since the dynamic focus voltage Vfd and the base voltage focus voltage Vf are applied to the dynamic focus electrode 15, the potential difference between the voltage applied to the dynamic focus electrode 15 and the final acceleration electrode 16 is small. As a result, the intensity of the main lens is weakened and the focal length of the electron beam becomes long, so that an optimal focus can be obtained when the electron beam is deflected around the fluorescent surface.

In the electron gun 10 according to the present invention, the focusing electrode 14 and the dynamic focusing electrode have an electron beam passing hole 14H and an electron beam passing hole 14H and 15H formed therein, respectively, when the focusing electrode 14 and the dynamic focusing electrode are assembled. Since the position is set by the horizontal width (WH) and the diameter (D) of), not only can the assembly accuracy be improved as compared to the conventional electron gun, but the focus electrode 14 is slightly shifted in the vertical direction to the electrode array direction. Since the length of the vertical blade 14b of the focus electrode 14, that is, the vertical width WV of the electron beam through hole 14H is wider than the width WH between the horizontal blades 15b of the dynamic focus electrode 15, the quadrupole Since the formation of the lens is not affected, the tolerance range due to assembly is widened.

As described above, the electron gun for the color cathode ray tube improves astigmatism and focus characteristics by correcting a non-uniform magnetic field of the deflection yoke by a quadrupole lens formed between the focus electrode and the dynamic focus electrode when the electron beam is deflected by the deflection yoke. As a result, a cathode ray tube having a clear image can be produced.

Claims (5)

An electron gun for a color cathode ray tube having a cathode, a control electrode, and a screen electrode forming a pre-triode tube portion, a focus electrode, a dynamic focus electrode, and a final acceleration electrode forming an auxiliary and main lens system, wherein the emission side of the focus electrode 14 is provided. Vertical beams 14b parallel to both edges of the electron beam passing holes 14H formed in the 14a are formed on the cathode 11 side, and the electron beams formed on the incident side surface 15a of the dynamic focus electrode 15 are formed. Upper and lower portions of the through holes 15H are provided with horizontal blades 15b extending a predetermined length toward the cathode 11 so that the horizontal blades 15b are inserted into the electron beam through holes 14H of the focus electrode 14. Electron gun for color cathode ray tube, characterized in that. The electron gun for color cathode ray tube according to claim 1, wherein the horizontal blade (15b) formed on the dynamic focus electrode (15b) is lancing processed on the incident side surface (15a). The electron gun for a color cathode ray tube according to claim 1, wherein the vertical width WV of the electron beam passing hole 15H formed in the emission side surface 14a of the focus electrode 14 is larger than the horizontal width WH. The electron gun for a color cathode ray tube according to claim 3, wherein the electron beam through hole (14H) formed in the emission side surface (14a) of the focus electrode (14) is an elongated rectangular hole. The method of claim 1, wherein the horizontal width (WH) of the electron beam through hole formed on the emission side of the focus electrode 14 and the diameter (D) of the electron beam through hole formed on the incidence side of the dynamic focus electrode 15 are formed to be approximately equal. Electron gun for color cathode ray tube, characterized in that.