JPH0612656B2 - Electron gun assembly for color picture tube - Google Patents

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to an electron gun assembly for a color picture tube.

[Technical background of the invention]

As shown in FIG. 2, one of the in-line integrated structure electron gun assemblies for the color picture tube that generates the central electron beam and the electron beams on both sides of the central electron beam is a cathode having a heater (1) inside. (2) The first grid electrode (3), the second grid electrode (4), the third grid electrode (5) and the fourth grid electrode (6), which are integrally formed. This is the basic form of the bi-potential type electron gun structure, in which the main electron is composed of the third grid electrode (5) to which a relative low potential voltage is applied and the fourth grid electrode (6) to which a relative high potential voltage is applied. Form a lens. Each electrode has an opening corresponding to the electron beam. Regarding the center electron beam (G), the first grid electrode (3) has an opening (3c) and the second grid electrode (4) has an opening (4c). ), An opening (51c) on the side closer to the cathode (2) of the third grid electrode (5), and an opening on the side closer to the fourth grid electrode (6)
(52c), the fourth grid electrode (6) has an opening (61c) on the side closer to the third grid (5) and an opening on the side farthest from the cathode (2).
It has (62c). Similarly, side electron beams (R), (B)
As for the openings (3s), (4s), (51s), (52s), (61s),
It has (62s).

Here, the central axis (a) of the opening (61s) corresponding to the side electron beam of the fourth grid electrode (6) is the central axis of the opening (52s) corresponding to the side electron beam of the third grid electrode (5). Since the eccentricity is slightly farther from the central axis (X) of the electron gun structure than (b), the electric field formed in the opening (61s) is asymmetric with respect to the central axis (a) and passes through the opening (61s). Side electron beam
(R) and (B) are deflected in the direction of the center electron beam (G), and the three electron beams (R), (G), and (B) are aligned (converged) on a screen (not shown). There is. The amount of eccentricity of the central axis (a) is about 0.1 to 0.2 mm with respect to the central axis (b), although it depends on the size of the picture tube and the shape of the electron gun.

[Problems of background technology]

In the integrated structure electron gun assembly, the structure of each electrode is mechanically simple, and the relative positions of the openings corresponding to the three electron guns are accurately determined. However, there are drawbacks to be improved. Ie 3
In order to focus the electron beam of the book on the screen, the opening of the fourth grid (or the final electrode) corresponding to the side electron beam is eccentric to those of the third grid (or the electrode facing the final electrode). Therefore, the electron lens for the side electron beam is essentially an asymmetric lens. As a result, as shown in FIG. 3, the central electron beam spot (g) becomes a nearly perfect circle, but the side electron beam spot (b) and (r) are not perfect circles, and a halo appears in the lateral direction of the bright spot. It becomes what is called coma aberration. As a result, the focus quality of the central portion of the screen, and eventually the peripheral portion of the screen, is impaired. In the center part of the screen, the electron beam spots on both sides show halos in the lateral direction, which is not preferable per se.
In other words, the focus voltage (voltage applied to the focusing electrode) differs between the center electron beam and the side electron beam, and the halo disappears if the focus voltage of the side electron beam is increased. It is higher than that of the central beam.
However, in this case, the center electron beam is not in the best state. In any case, the halo in the side electron beam is a problem.

Further, a more inconvenient phenomenon occurs in the peripheral portions of both sides, especially in the upper and lower portions of the screen as shown in FIG. It is well known that the recent deflection yoke magnetic field uses a strong pincushion magnetic field as the horizontal deflection magnetic field and a strong parel magnetic field as the vertical deflection magnetic field in order to match the central beam and the both side beams in the peripheral portion of the screen. As a result, the central beam is
As shown in the figure, the horizontally long bright spot, the vertical halo, and the beams on both sides are composed of a horizontally long bright spot inclined at about 45 ° and a halo substantially orthogonal thereto. Now, if a horizontal halo is formed on the surface side beam at the center of the screen, this halo is promoted when it is deflected to the upper and lower parts of the screen, degrading the focus quality of the naked field.

There are many similar techniques to solve this problem. For example, Japanese Examined Patent Publication No. 52-32714 (US Pat. No. 3,772,554)
No.), the aperture axes of both side beams are the same from the first grid electrode to the position facing the fourth grid electrode of the third grid electrode, and are decentered by the opening center axis of the fourth grid. Further, in this electron gun, the electrode facing surface of the main lens is curved in order to prevent mutual interference between the center electron lens and the side electron lens. The present invention does not require this.

In addition, Japanese Utility Model Publication No. 54-33816 discloses an electron gun assembly in which the aperture diameter of both side beams is larger than that of the center beam in the main lens portion in order to correct the aberration of the electron beams on both sides. There is. This electron gun is also eccentric by the central axis of the opening of the fourth grid electrode.

Further, Japanese Patent Application Laid-Open No. 55-37798 discloses an electron gun in which both side beams incident on the main lens are obliquely incident on the main lens. This electron gun deflects both side beams between the second grid electrode and the grid electrode of FIG. 3, and is not deflected by the main lens portion.

As mentioned above, there are many technologies, but none of them have been fully resolved.

[Object of the Invention]

An object of the present invention is to solve the above-mentioned drawbacks, and an object thereof is to provide an electron gun assembly for a color picture tube capable of obtaining extremely good focus quality even in the central portion and the peripheral portion of the screen.

[Outline of Invention]

The present invention is an in-line type integrated electron gun structure for generating a center electron beam and electron beams on both sides, and at least a cathode and a main electron lens forming electrode means composed of a relative low potential electrode and a relative high potential electrode. In the electron gun structure in which each electrode has an opening corresponding to the electron beam, the central axis of the opening corresponding to the side electron beam on the side closer to the cathode among the openings of the relative low potential electrode has a relative low potential. Of the openings of the electrode, the distance from the center axis of the electron gun structure is slightly farther than the center axis of the opening corresponding to the side electron beam on the side closer to the relative high potential electrode, and An electron gun assembly for a color picture tube, which is slightly closer to a central axis of an electron gun assembly than a central axis of an opening corresponding to a side electron beam near a low potential electrode.

That is, with respect to the central axes of the openings corresponding to both side electron beams, there are at least three types of axes having different distances from the central axis of the electron gun structure. The first axis is the central axis from the cathode to the opening on the side closer to the cathode of the third grid electrode, the second axis is the central axis of the opening on the side closer to the fourth grid electrode (final electrode) of the third grid electrode, The third axis is the central axis of the opening for forming the main lens of the fourth grid electrode (final electrode). It is possible to obtain a good electron beam spot without coma aberration (small) while giving a predetermined deflection to the electron beams on both sides by the eccentricity of these three or more types of central axes.

Example of Invention

An example of a bipotential type electron gun will be described with reference to FIG. Description of the same parts as those in the conventional example shown in FIG. 2 will be omitted.

The center axes of the openings of the electrodes corresponding to the electron beams on both sides are the first axes up to the center axes of the openings on the second grid side of the first grid (3), the second grid (4) and the third grid (50). (80) Opening (520s) of 4th grid (60) of 3rd grid (50)
The central axis of the electron gun structure is more central than the first axis (80) (X)
Is slightly closer to. This is the second axis (90). The opening (610) on the side of the third grid (50) of the fourth grid (60)
The central axis of (s) is the central axis of the electron gun assembly rather than the first axis (80).
Slightly far from (X). This is the third axis (100)
And In addition, the opening (6) of the screen axis of the fourth grid (60)
20s) does not affect the formation of the main lens, so its center is not particularly limited, but the first axis (80) or the third axis (1
00) is preferable.

As described above, the electron gun according to the present invention has a lower voltage side of the main lens forming electrode, that is, the third electron gun, as compared with the conventional electron gun.
Grid opening center axis (90) is the electron gun assembly center axis (X)
The feature is that it is eccentric to the side. The operation principle of the electron gun according to the present invention will be described with reference to FIG. 6 in comparison with FIG. 5 of a conventional electron gun. In FIG. 6, the action of the main lens portion is schematically replaced with an optical lens for ease of explanation.

It is well known that a lens is formed between an opening to which a low voltage is applied and an opening to which a high voltage is applied, and has a focusing effect on the low voltage side and a diverging effect on the high voltage side. Therefore, in the conventional electron gun, it can be considered that the concave lens is eccentric to the outside, as shown in FIG. As a result, the electron beam as a whole is deflected to the central axis (X) side of the electron gun structure, but considering the spread of the electron beam, the direction opposite to the deflected direction on the screen (upper in the figure) is a halo. coming out.

In the present invention, in order to eliminate this halo, as shown in FIG. 6, the convex lens is slightly decentered toward the central axis. Since the convex lens is eccentric to the central axis side, the halo protruding in the direction opposite to the deflection direction is deflected to the central axis side and so-called coma aberration is eliminated.

If the amount of eccentricity toward the central axis of the convex lens is too large,
Since the halo appears in the opposite direction to the conventional one, that is, in the lower part of the figure,
Naturally, there is an optimum value. According to the calculation and the experiment, the optimum values of the eccentricity of the convex lens and the eccentricity of the concave lens are as follows.

Focusing voltage, that is, the applied voltage of the 3rd grid is 24 to 34% of the applied voltage of the 4th grid, and the eccentricity in the 20 type picture tube when the opening diameter of the 3rd grid and the 4th grid is 4.52mm d ₁ = 0.04 mm and d ₂ = 0.06 mm. The distance from the first axis (80) to the central axis (X) is 4.92 mm.

In the case of the conventional electron gun, the eccentricity of the concave lens is d = 0.12 mm under the same conditions as described above. Therefore, the eccentricity of the convex lens and the concave lens is approximately the same as that of the conventional type in the present invention. Less.

FIG. 7 shows an electron beam spot shape on the screen of a color picture tube using the electron gun assembly of the present invention. As shown in the figure, the halo is small over the entire screen, and the electron beam spot shape is good.

As described above, the electron gun of the present invention is similar to the conventional example.
It is completely different in its structure and operating principle.

Next, another embodiment of the present invention will be described with reference to FIG. The structure of this electron gun is called a quadra-potential type, and the present invention can be applied to its main lens portion. Heater (1), cathode (2), first grid (3), second
Grid (4), 3rd grid (500), 4th grid (60
0), the fifth grid (700), and the sixth grid (800) are arranged in this order. The voltage applied to each electrode is, for example, 150 V for the cathode (2), ground for the first grid (3), 600 V for the second grid (4), 8 KV for the third grid (500), and fourth. The grid (600) is the second grid in the pipe
The fifth grid (700) is also connected to the third grid (500), and 25 KV is applied to the sixth grid (800). The main lens is the 5th grid (700)
And the sixth grid (800). The distance (9) from the center axis of the aperture corresponding to both side beams to the center axis (X) of the electron gun assembly is from the first grid (3) to the fifth grid (70).
It is 4.92 mm up to the castot side (2) of 0). Fifth
Center axis (X) from the center axis of the opening on the main lens side of the grid (700)
The distance to (10) is 4.88 mm. The distance (11) from the center axis of the opening of the sixth grid (800) to the center axis (X) is 4.98 mm. In addition, the opening diameter of the main lens forming portion is the fifth grid (70
0), the center hole of the sixth grid 800 and both holes are 4.52 mm.

The electron gun assembly according to the present invention can be applied regardless of the size of the picture tube or the main lens system. Eccentricity
Parameters related to d ₁ and d ₂ (Fig. 6) include the size of the picture tube, the distance between the electron gun axis and the first axis (Sg), the aperture diameter of the main lens forming electrode (D), and the focus. It is the ratio (E _F / E _b ) of the voltage to the final voltage (anode).

The eccentricity amounts d ₁ and d ₂ are large when L _sg is small, Sg is large, D is large, and E _F / E _b is large. At this time, d ₁ / D is approximately 0.024, and d ₂ / D is about 0.025.

On the other hand, the eccentricities d ₁ and d ₂ are small because L _sg is large and Sg is large.
Is small, D is small, and E _F / E _r is small, where d ₁ / D is about 0.002 and d ₂ / D is about 0.003. That is, 0.002 ≦ d ₁ /D≦0.024 0.003 ≦ d ₂ /D≦0.025 is a preferable range. By the way, in the above embodiment, d ₁ / D = 0.
04 / 4.52 = is 0.00885, d ₂ /D=0.06/4.52=0.013
It is 2.

〔The invention's effect〕

As described above, the electron gun assembly of the present invention can eliminate the coma aberration of both side beams, which is a drawback of the conventional electron gun assembly, with a relatively simple structure. Therefore,
The focus quality of the central portion of both surfaces of the color picture tube, and hence the peripheral portion of the screen, can be greatly improved, and its industrial value is extremely large.

[Brief description of drawings]

1 and 8 are schematic views of an electron gun assembly of the present invention, FIG.
The figure is a schematic view of a conventional electron gun assembly, FIGS. 3 and 4 are diagrams showing the electron beam spot shape by the conventional electron gun assembly, and FIG. 5 is a view for explaining the action of the main lens of the conventional electron gun assembly. 6 and 6 are views for explaining the action of the main lens of the electron gun assembly of the present invention, and FIG. 7 is a view for explaining the electron beam spot shape by the electron gun assembly of the present invention. 1 ... Cathode 5,50,500 ... Third grid electrode 6,60,600 ... Fourth grid electrode 700 ... Fifth grid electrode X ... Central axis of electron gun assembly 51S, 52S, 61S, 62S, 510S, 520S, 610S 620S… Aperture corresponding to side electron beam

Claims (1)

[Claims] 1. An in-line integrated electron gun assembly for generating a center electron beam and electron beams on both sides, comprising:
An electron gun assembly having at least a cathode, a relative low potential electrode, and a main electron lens forming electrode means composed of a relative high potential electrode, each electrode having an opening corresponding to an electron beam, wherein the relative low potential electrode The central axis of the opening corresponding to the side electron beam on the side closer to the cathode is the central axis of the opening corresponding to the side electron beam on the side closer to the relative high potential electrode among the openings of the relative low potential electrode. Slightly more distant from the central axis of the electron gun structure than the central axis of the opening corresponding to the side electron beam on the side of the opening of the relative high potential electrode closer to the relative low potential electrode. Electron gun assembly for color picture tubes characterized by being slightly closer to