KR940000847B1 - Electron gun - Google Patents

Abstract

The electron gun comprises the first electrode having a large electron beam through-hole and the second electrode having three independent small holes, between which an auxiliary electrode (23) is disposed with a small electron beam hole for passing in common red, green and blue color beams, and the electrode terminals (25).

Description

Electron gun for colored cathode ray tube

1 is a cross-sectional view of a typical tank for a color cathode ray tube.

2 is a view showing a conventional focus electrode and a final acceleration electrode, (a) is a planar cross-sectional view, (b) is a front view of the focus electrode or the final acceleration electrode shown in (a).

3 is a cross-sectional view of a magnetron for color cathode ray tube according to the present invention.

4 is a perspective view of the final acceleration electrode shown in FIG.

FIG. 5 is a perspective view of another embodiment of the auxiliary electrode piece shown in FIG.

6 is a front view of the final accelerating electrode shown in FIG.

* Explanation of symbols for main parts of the drawings

11 cathode 12 control electrode

13 screen electrode 14 focus electrode

20: final acceleration electrode 21: the first electrode

21H: Common large diameter electron beam through hole

21HR, 21HG, 22HB: Independent small diameter electron beam through hole

22: second electrode 23: auxiliary electrode

23a: electron beam passing hole 25: electrode piece

26: projection C: cathode lens

P: prefocus lens M: main lens

The present invention relates to an electron gun for a cathode ray tube, and more particularly to an electron gun having a field extension focusing lens.

There are many kinds of electron guns for cathode ray tubes according to their characteristics, but as shown in FIG. 1, the cathode 2, the control electrode 3, the screen electrode 4, and the main lens system forming the pre-triode tube part are formed. The focus electrode 5 and the final acceleration electrode 6 for final focusing and accelerating the electron beam are arranged in sequence. In the electron gun 1 configured as described above, the electron beam emitted from the cathode 2 passes through a pre-focus lens formed between the screen electrode 4 and the focus electrode 5 to be preliminarily contacted and accelerated. Passed through the main lens formed between the (5) and the final acceleration electrode 6, the final connection and acceleration is landing on the fluorescent surface to form a pixel. Therefore, in order to obtain a clear image at the full screen, it is desirable that the diameter of the beam spot landing on the fluorescent screen is as small as possible and high density. However, the conventional electron gun 1 as described above receives a lot of spherical aberration by the main lens when the electron beam emitted from the cathode 2 passes through the main lens, so that the electron beam spot is small on the fluorescent surface and the electron beam spot is increased. In addition, there was a problem in that the image quality of the cathode ray tube employing the same deteriorated. In order to solve the effect of the spherical aberration, the diameters of the electron beam through holes of the focus electrode 5 and the final acceleration electrode 6 forming the main lens have been increased. Since the electron beam passing holes are arranged in an inner line and inserted into the neck portion of the cathode ray tube in (6), it is impossible to make the electron beam passing hole diameter larger than the eccentric distance of two adjacent electron beam passing holes. Increasing the eccentric distance in order to increase the diameter lowers the convergence characteristic of the electron gun, so that a large improvement effect cannot be expected. Therefore, in order to improve spherical aberration in the conventional main lens, as shown in US Patent No. 4,370,592 and shown in FIG. 2, the exit side 7a of the focus electrode 7 and the incident side of the final acceleration electrode 8 are shown. The large-diameter electron beam passing hole 7H (8H) through which R, G, and B electron beams pass through a predetermined depth in each of the portions except for the most magnetic portion (hereinafter referred to as burring portions 7b and 8b) in (8a). ), And R, G, and B independent small-diameter electron beam through holes 7H 'and 8H' are formed at positions where a predetermined length is drawn from the burring portions 7b and 8b.

The electron beam passing through the main lens formed by the focus electrode 7 and the final accelerating electrode 8 is a large independent electron diameter electron beam passing hole because the large diameter electron beam passing holes 7H and 8H are asymmetrical. The vertical and horizontal focusing components of the electron beam passed through and the independent small-diameter electron beam passing holes on both sides were different from each other to uniformly form an electron beam spot landing on the fluorescent surface. That is, as shown in FIG. 2 (b), both side electron beams RB (BB) having passed through the large-diameter electron beam through hole of the focus electrode 7 or the final acceleration electrode 8 are low voltage or high voltage in the horizontal direction. Close to the distributed burring portions 7b and 8b, and the central electron beam through hole is located far from the burring portions 7b and 8b, so that the electron beams RB and BB on both sides in the horizontal direction are relatively. It is strongly connected and focused at the center electron beam GB, relatively weakly. Both side electron beams RB and BB have a distance from the burring portions 7b and 8b in a vertical direction approximately equal to a distance in a horizontal direction, and therefore approximately equal to a focusing action in the horizontal direction in a vertical direction. The central electron beam GB is subjected to a large focusing force due to the influence of many electric fields in the vertical direction because the vertical distance between the burring portions 17b and 18b is closer than the horizontal distance. Therefore, the electron beams RB and BB on both sides passing through the main lens have a substantially circular beam cross section and a horizontal beam cross section, respectively, so that a uniform electron beam cross section can be obtained on the typical light plane. There will be no.

The present invention has been made to solve the above problems, and by improving the spherical aberration of the main lens system to prevent the distortion of the electron beam passing through it to obtain a beam spot with a small and high-density electron beam, and furthermore, An object of the present invention is to provide an electron gun for cathode ray tubes capable of improving resolution.

In order to achieve the above object, the present invention forms a main lens system, the first electrode having a large-diameter electron beam through hole sharing the three R, G, B electron beams on the incident side, and a predetermined length from the large-diameter electron beam through hole. An electron gun for a color cathode ray tube including a final acceleration electrode provided with a second electrode having three independent small diameter electron beam through holes, wherein the large diameter electron beam through hole of the first electrode and the independent small diameter electron beam through hole of the second electrode are provided. It is characterized in that the auxiliary electrode provided with an electron beam passing hole through which the red, green, and blue electron beams pass.

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

As shown in FIG. 3, the electron gun 10 for the color cathode ray tube according to the present invention includes a cathode 11, a control electrode 12, and a screen electrode 13 constituting a pre-triode tube portion, and a focus electrode constituting a main rene system ( 14) and the final acceleration electrode 20. The final acceleration electrode 20 has a common large-diameter electron beam passing hole 21H through which three electron beams of red, blue, and green pass through, as shown in FIG. And a first electrode 21 having a burring portion formed at an edge thereof, and positioned inside the first electrode so as to be spaced apart from a cross section of the first electrode 21 by a predetermined interval, and having three independent small diameter electron beam through holes ( 22H) (22HG) and 22HB are formed, with a second electrode 22 having a central independent small diameter electron beam through hole 22HG formed in a horizontal shape. Here, between the end of the first electrode 21, that is, the cross section where the burring portion 21a is formed, and the second electrode 22 having the independent small diameter electron beam passing holes 22HR, 22HG, and 22HB spaced apart from each other by a predetermined distance. According to the characteristics of the present invention, the auxiliary electrode 23 is formed with an electron beam through hole 23a through which three electron beams of red, blue, and green pass through. The auxiliary electrode 23 has the electron beam through hole 23a. The vertical width W is smaller than or equal to the vertical width W 'of the common large-diameter electron beam passing hole 21H, and is perpendicular to the independent small-diameter electron beam passing hole 22HR, 22HG, and 22HB of the second electrode 22. It is formed wider than or equal to the width. As another embodiment of the auxiliary electrode 23, as shown in FIG. 5A, plate-shaped upper and lower portions of the independent small-diameter electron beam passing holes 22HR, 22HG, and 22HB of the second electrode 22 are respectively formed. The member 25 can be provided and used. In addition, the auxiliary electrode 23 may be formed by pressing the second electrode 22 to form a single body with the second electrode 22. As shown in FIG. 5 (b), the second electrode 22 may be formed. The central portion of the auxiliary electrode 23 corresponding to the independent small diameter electron beam through hole 22HG in the center among the independent small diameter electron beam through holes 22HR, 22HG of the predetermined length is extended to the central axis in the traveling direction of the electron beam. It is preferable to form the projections 26 to be used.

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

When a predetermined voltage is applied to each electrode constituting the electron gun 10 for the color cathode ray tube according to the present invention, a cathode lens C is formed between the control electrode 11 and the screen electrode 12 and the screen A prefocus lens P is formed between the electrode 13 and the focus electrode 14, and a main lens M is formed between the focus electrode 14 and the final acceleration electrode 20. Therefore, the electron beam B emitted from the cathode 11 is preliminarily connected and accelerated in the cathode lens C and the prefocus lens P, and finally accelerated and connected in the main lens M to be the screen surface of the cathode ray tube. The spherical aberration in the main lens M is caused by the auxiliary electrode 23 provided between the edge of the first electrode 21 and the second electrode 22 of the final acceleration electrode 20. Is corrected to obtain a uniform electron beam cross-sectional shape on the entire screen. That is, the electron beam in the center of the electron beam emitted from the cathode 11 and passing through the main lens M formed between the focus electrode 14 and the final acceleration electrode 20, that is, the green electron beam is the center of the second electrode. The independent small-diameter electron beam through hole 22HG is formed in the horizontal shape and the auxiliary electrode 23 having the common large-diameter electron beam through hole 23a is provided, so that the electron beam through hole 22HG 23a is used in the vertical direction. As a result, strong divergence and weak focusing power are received, and in the horizontal direction, weak divergence and strong focusing power are received. In addition, the electron beams on both sides, that is, the red and blue electron beams, receive strong divergence in the vertical direction and weak divergence in the horizontal direction by the auxiliary electrode 23. Lateralization of the electron beam generated by the non-uniform electric field is prevented, and further, the cross section of the electron beam can be obtained circularly on the screen surface.

In more detail, the auxiliary electrodes 23 of the final accelerating electrode 20 are close to each other in the vertical direction with respect to the three electron beams of red, green, and blue, and a high voltage of an anode voltage is applied to both the blue The red and red electron beams are weakly emitted in the horizontal direction and strongly in the vertical direction. The green phosphorus central electron beam 22HG is formed from the edges of the common large diameter electron beam through hole 21H and the electron beam through hole 23a of the first electrode 21 and the auxiliary electrode 23 of the final acceleration electrode 20. Because it is located far in the horizontal direction and the central independent small-diameter electron beam through hole 22HG of the second electrode 22 is formed in a horizontal shape, it receives very weak divergence in the horizontal direction and very strong divergence in the vertical direction. The force is applied to compensate for the distortion of the electron beam in the horizontal shape due to the uneven development of the main lens (M). That is, as shown in FIG. 6, when the horizontal and vertical divergence forces acting on the central electron beam are called Fhc Fvc, respectively, and the horizontal and vertical divergence forces acting on the outside of both electron beams are called Fhs 'Fvs', respectively, inside the two electron beams. When the vertical and horizontal divergence force acts as Fhs Fvs, the magnitude relation of the divergence force of the electron beams on both sides has a relationship of Fvs> Fhs> Fhs', and the central electron beam has the auxiliary electrode 23 and the second electrode 22. The central electron beam through hole (22HG) has a relationship of Fvc »Fhc. Therefore, the magnitude of divergence force acting on the central electron beam has a relationship of Fvc> Fvs> Fhs> Fhs '> Fhc, which is offset by the focusing force of Fvc> Fvs> Fhs> Fhs'> Fhc of the conventional focus electrode. The cross section of the electron beam is circular when both electron beams are landed on the fluorescent surface. Therefore, the electron beam emitted from the electron gun can be landed at the best state for the entire screen surface, thereby improving the resolution.

In particular, according to the experiments of the present inventors, the divergence of the central electron beam in the vertical direction when a projection is formed in the center of the auxiliary electrode 23 corresponding to the central independent small diameter electron beam through hole 22HG of the second electrode 22 is observed. In addition, the resolution of the cathode ray tube employing the same can be improved by more than 30% compared to the conventional art. As described above, the electron gun for the color cathode ray tube of the present invention corrects the distortion of the electron beam cross section by the nonuniform electric field of the main lens system. The aberration and astigmatism can be improved, and furthermore, there is an advantage of improving the reliability and product value of the cathode ray tube employing the same.

Claims (6)

Forming the main lens system, the first electrode formed with a large-diameter electron beam through hole sharing the three electron beams R, G, B on the incident side, and is installed at a position lengthened from the large-diameter electron beam through hole, three independent small diameter electron beam passes In the electron gun for a color cathode ray tube including a final acceleration electrode provided with a second electrode having a ball, the large diameter electron beam through hole (21H) of the first electrode 21 and the independent small diameter electron beam through of the second electrode (22) An electron gun for a color cathode ray tube, characterized in that an auxiliary electrode (23) having an electron beam passing hole (23a) through which red, green, and blue electron beams pass through is formed between the balls (22HR) (22HG) and (22HB). The vertical width (W) of the electron beam through hole (23a) of the auxiliary electrode (23) is narrower than the vertical table (W ') of the large-diameter electron beam through hole (21H) of the first electrode (21). An electron gun for a color cathode ray tube, which is equal to and wider than or equal to the vertical width of the independent electron beam passing holes (22HR) (22HG) (22HB) of the second electrode (22). The electron gun for a color cathode ray tube according to claim 1, wherein the auxiliary electrode (23) and the second electrode (22) are integrally formed. The electron gun for a color cathode ray tube according to claim 1, wherein the auxiliary electrode (23) is provided with electrode pieces (25) attached to upper and lower edges of the independent small diameter electron beam through holes (22HR) (22HG) and (22HB), respectively. . 5. The predetermined length of one of claims 1 to 4, wherein the second electrode 22 extends a predetermined length in the center direction of an edge of the auxiliary electrode 23 corresponding to the central independent small diameter electron beam passing hole 22HG. 6. Electron gun for a color cathode ray tube, characterized in that the projection 26 is formed. 2. The three independent small diameter electron beam through holes 22HR, 22HG, and 22HB formed in the second electrode 22 are formed in a horizontal shape. Electron gun for color cathode ray tube characterized by the above-mentioned.