KR950012705B1 - Color crt having inline type electron gun - Google Patents

Abstract

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Description

In-line electron gun assembly bundle with electrode unit having electron beam passing holes of different size to form electrostatic lens

1 (a), 1 (b), and 1 (c) are cross-sectional configuration diagrams showing an example of a kettle lens portion of a conventional inline electron gun.

2 is a schematic view showing a color cathode ray tube with an inline electron gun assembly according to an embodiment of the present invention.

3 (a), 3 (b), 3 (c), and 3 (d) are cross-sectional configuration diagrams showing a kettle lens portion of an inline electron gun assembly bundle according to an embodiment of the present invention.

4 (a), 4 (b), and 4 (c) are cross-sectional configuration diagrams illustrating a kettle lens unit of an inline type electron gun assembly bundle according to another embodiment of the present invention.

5 (a), 5 (b), and 5 (c) are cross-sectional configuration diagrams showing a kettle lens unit of an inline-type electron gun assembly bundle according to still another embodiment of the present invention.

6 is a graph showing the relationship between the deformation of the electron beam spot on the fluorescent surface of the cathode ray tube having the inline electron gun assembly according to the embodiment of the present invention and the electron beam passing hole.

* Explanation of symbols for main parts of the drawings

1 panel portion 2 funnel portion

3: neck 4: fluorescent surface

5: shadow mask 6: magnetic shield

7: Deflection yoke 8: Purity adjustment magnet

9: Center beam electrostatic convergence adjustment magnet 10: Side beam electrostatic convergence adjustment magnet

21: G3 electrode unit 22: G4 electrode unit

21B, 121B, 22B, 222B: flat plate member 25,26: central electron beam through hole

27, 28, 33, 34: side electron beam passing hole 29, 30, 31, 32: side electron beam passing cutout

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cathode ray tube used for color image display, and more particularly, to an electron beam of a plurality of electrode units constituting an electrostatic lens or an electron lens in an inline electron gun which emits by arranging three electron beams in a transverse direction toward a fluorescent surface A cathode ray tube provided with an inline electron gun having an improved shape of a through hole.

Conventionally, inline type electron gun assembly bundles equipped with kettle lenses are described, for example, in Japanese Patent Application Laid-Open No. 58-103753 (US Pat. The structure as disclosed in the above) is used.

1 (a), 1 (b), and 1 (c) are cross-sectional views showing the same configuration as that of the conventional inline type electron gun assembly bundle disclosed above. FIG. 1 (a) is a vertical cross sectional view, FIG. 1 (b) is a horizontal cross sectional view along the line Ib-Ib of FIG. 1 (a), and FIG. 1 (c) is a first cross (a) view. It is the horizontal cross section which looked along the line Ic-Ic of a figure.

In FIG. 1 (a), reference numeral 41 denotes a cathode for generating three electron beams, reference numeral 42 denotes a G1 electrode for limiting the diameter of the electron beam emitted from the cathode 41, and reference numeral 43 denotes a G1 electrode ( 42 is a G2 electrode for accelerating an electron beam, and 44 is a cylindrical G3 electrode for accelerating and focusing the electron beam from the G2 electrode 43 and having an opening of approximately elliptical cross section. The flat plate member 46 is formed in the inner wall of the cylindrical member of the G3 electrode 44, and the other flat plate member is formed in the inner wall of the cylindrical member of the G4 electrode 45. As shown in FIG.

The G3 electrode 44 having the plate member 46 and the G4 electrode having the plate member 47 together constitute a kettle lens. Three electron beam through holes having substantially elliptical shape are formed in each of the plate members 46 and 47 of the G3 electrode and the G4 electrode, as shown in FIG. 1 (b) and FIG. 1 (c). . The three said electron beam through holes which value substantially elliptical shape are comprised so that diameter (main diameter) is equal to each other in the longitudinal direction.

The inline electron gun having the above configuration operates in the following manner.

The hot electrons emitted from the three electrodes 41 heated by the heater (not shown) are attracted to the G1 electrode 42 by the positive voltage applied to the G2 electrode 43, thereby forming three electron beams. . The three electron beams pass through the electron beam through hole of the G1 electrode 42 and the electron beam through hole of the G2 electrode 43, and then enter the kettle lens formed by the electrodes 44 and 45, and the G3 electrode 44 and Accelerated by the constant voltage applied to the G4 electrode 45. A low voltage of 5 to 10 KV is applied to the cylindrical member 44 and the plate member 46 of the G3 electrode, and a high voltage of 20 to 35 KV is applied to the cylindrical member and the plate member 47 of the G4 electrode 45. Therefore, an electrostatic field is generated between the G3 electrode 44 and the G4 electrode 45 by the potential difference applied between the G3 electrode 44 and the G4 electrode 45. The trajectory of the three electron beams applied to the kettle lens is bent by the electrostatic field, finally converging the three electron beams.

In this way, a focus is formed on the fluorescent surface (not shown) so that a beam spot is formed on the fluorescent surface.

In the conventional inline type electron gun assembly bundle as described above, the cylindrical members of the G3 electrode 44 and the G4 electrode 45 generally have an aperture having an approximately elliptical cross section. However, in the case of using the G3 electrode 44 and the G4 electrode 45 having a cylindrical member having an aperture having a substantially elliptical cross section, a large diameter (diameter in the horizontal direction or a horizontal diameter in the drawing) is small in diameter. Significantly larger than (the diameter in the longitudinal direction or the diameter in the vertical direction on the drawing). For this reason, when an electron beam through hole formed in the plate members of the electrodes 44 and 45 is provided, the focus effect of the three electron beams is different between the vertical direction and the horizontal direction, and the spot shape on the fluorescent surface extends in the horizontal direction. do.

In order to solve the problem, conventionally, like the inline type electron gun, the shape of the electron beam through hole formed in the plate members 46 and 47 of the G3 electrode and the G4 electrode is formed to have an approximately elliptical shape. The elliptical shape is formed in a shape extending in the vertical direction as opposed to the cross-sectional diameter formed in the cylindrical members of the G3 electrode 44 and the G4 electrode 45.

According to the above configuration, three electron beams extending in the horizontal direction by an aperture having an elliptical cross section are perpendicular to the part of the substantially elliptical electron beam through hole formed in the plate members 46 and 47 of the G3 electrode and the G4 electrode. It is focused more in the horizontal direction than in the direction. Therefore, the cross section of the three electron beams after passing through the kettle lens is usually circular, and suppresses the spot shape on the fluorescent surface extending in the horizontal direction.

However, the diameter of the neck of the glass cover of the inline killer cathode ray tube in which the electron gun assembly bundle is fixed minimizes the power to deflect the electron beam in terms of energy saving, and uses an inline electron gun assembly bundle. In order to lower the power supply, etc., the monitor display device of the terminal device becomes smaller. It can be seen from the above fact that the means for increasing the electron beam passing hole of the plate member in the vertical direction is certainly limited to extend the shape vertically. Therefore, the cross section of the electron beam of the prior art is not satisfied. In particular, when an inline type electron gun assembly is used for a color cathode ray tube used as a monitoring display device, which is a terminal device requiring high definition images, the resolution of the killer cathode ray tube has a horizontal extension in the beam spot shape on the screen. It still needs to be higher because it still exists.

In order to meet the above requirements for increasing the resolution, it may be considered to further reduce the diameter in the horizontal direction so that the ratio of the diameter in the vertical direction to the diameter in the horizontal direction of the electron beam through hole formed in the plate member of the G3 electrode is increased. . However, as the above structure of the electrode, another problem arises in that the electron beam is about to collide with the plate member of the G3 electrode. In particular, the central electron beam impinges on the plate member of the G3 electrode, so that unnecessary current flows to the G3 electrode (having the focusing function of the beam) forming the main electrostatic lens and undesirable voltage fluctuation occurs on the electrode. Since the focus adjustment cannot be satisfied due to the voltage fluctuation, the resolution of the screen is blurred or shaken, which reduces the image quality.

In addition, since the electron beam collides on the plate member of the G3 electrode, the electrode is undesirably heated and deformed or damaged, thereby reducing the reliability of the cathode ray tube.

SUMMARY OF THE INVENTION An object of the present invention is to provide an inline electron gun assembly in which the focus effect of the electron beam in each direction is substantially uniform, and also stabilizes the potential of the electrode unit of the electron gun assembly.

Another object of the present invention to provide a color cathode ray tube provided with the electron gun assembly bundle.

According to the first aspect of the present invention, there is provided a cathode unit for generating three electron beams, a low potential side cylindrical electrode unit, and a high potential side cylindrical electrode unit downstream of the low potential side cylindrical electrode unit with respect to the electron beam; In the in-line electron gun assembly in which each of the electrode units has a non-circular elongated cross section which crosses at right angles in the vertical direction and has a diameter smaller in the vertical direction than the horizontal direction in the arrangement direction of the electron beam, respectively. The electrode unit includes a cylindrical member and a flat plate member formed on the inner wall of the cylindrical member and having at least one non-circular electron beam through hole for the central electron beam among three electron beams formed in the non-circular electron beam through hole. Both electrode units constitute an electron lens, and the diameters of the central electron beam through holes of the plate member of both electrode units are different from each other in the vertical direction. In-line electron gun assembly bundles characterized in that. The diameter of the non-circular central electron beam passing hole in the vertical direction of the low potential side electrode unit (hereinafter referred to as electron) and the non-circular central electron beam passing in the vertical direction of the high potential side electrode unit (hereinafter referred to as latter) The correlation between the diameters of the balls provides the following effects.

(a) if the former is longer than the latter:

In this case, the diameter in the vertical direction of the non-circular electron beam passing hole formed in the flat member of the low potential side electrode unit having the beam focusing function is the ratio formed in the flat member of the high potential side electrode unit having the beam dispersing function. It is larger than the diameter of the circular electron beam passing hole in the vertical direction. Therefore, since the radius of curvature in the vertical direction with respect to the diverging side of the electron lens is larger than the radius of curvature in the vertical direction with respect to the convergence side or the focus, the convergence characteristic in the vertical direction can be reinforced. When the incident central electron beam passes through the electron lens, the focusing effect of the electron beam in the vertical direction is weaker than that of the electron lens having the conventional structure. When the electron lens having the above-described structure is used to extend the spot shape obtained by the central electron beam in the horizontal direction using a conventional electron lens, the focusing in the horizontal and vertical directions can be aligned, and the center The spot shape obtained by the electron beam can be corrected to a substantially circular shape.

(b) if the former is shorter than the latter:

In this case, the diameter in the vertical direction of the non-circular electron beam passing hole formed in the flat member of the high potential side electrode unit having the beam focusing function is set to the flat member of the low potential side electrode unit having the beam focusing function or focusing function. It is larger than the diameter in the vertical direction of the formed non-circular electron beam passing hole. Therefore, since the radius of curvature of the electron beam in the vertical direction with respect to the focal point is larger than the radius of curvature with respect to the focusing side, the focus characteristic of the electron lens can be reinforced in the vertical direction. When the incident central electron beam passes through the electron lens, the focusing effect of the electron beam in the vertical direction is higher than that of the electron lens of the prior art structure. When using the electron lens when the spot shape obtained by the electron lens beam is extended in the vertical direction using the electron lens of the prior art structure, the focusing is aligned in the vertical and horizontal directions, and the spot shape obtained by the central electron beam is obtained. As in the case of (a), the correction can be performed in a substantially circular shape.

According to yet another aspect of the present invention, an inline type electron gun assembly includes a cathode unit for generating a central electron beam and two side electron beams, and a first for holding the first and second voltages during operation and for passing the electron beams. It has a second electrode unit. The second electrode unit is on the downstream side of the first electrode unit with respect to the electron beam. It has a cylindrical member of non-circular extension section and a plate member formed on the inner wall of the cylindrical member to focus and form electron beam through holes in parallel in the cylindrical member in a direction parallel to the longitudinal direction of the non-circular extension section of the cylindrical member. . Each plate member has one or more holes that function as electron beam through holes for the central electron beam.

Since the second voltage is higher than the first voltage, the first and second electrode units combine a first function of the first electrode unit to focus the electron beam and a second function of the second electrode unit to cause the electron beam to diverge. The second voltage is higher than the first voltage in order to form and interact with the main electrostatic lens. Aperture of any one of the first and second electrode units measured in the vertical direction of the non-circular extension cross section of the cylindrical member of the first electrode unit, and the longitudinal direction of the non-circular extension cross section of the cylindrical member. The apertures of the other flat plate members measured in a direction substantially perpendicular to the are different from each other, and the difference is that any one of the first and second functions is different from the other functions in the longitudinal direction of the non-circular extension section of the cylindrical member. It will be emphasized in a direction almost perpendicular to.

2 is a schematic configuration diagram showing a color cathode ray tube having an inline electron gun assembly bundle according to an embodiment of the present invention.

In FIG. 2, (1) is a panel portion, (2) is a funnel portion, (3) is a neck portion, (4) is a fluorescent surface, (5) is a shadow mask, and (6) is a magnetic shield (7) is deflection yoke, (8) fury adjustment magnet, (9) center beam electrostatic convergence adjustment magnet, (10) side beam electrostatic convergence adjustment magnet, and (11) inline type It's an electron gun assembly. B _c and B _s represent the center beam and the side beam, respectively.

The convergence adjustment (static convergence) of the color cathode ray tube is carried out so that the convergence point of the center beam coincides with the convergence point of the side beam after the convergence of the two side beams.

A thin film containing SnO ₂ , In ₂ O ₃ or the like for preventing reflection and filling is formed, if necessary, on one or a plurality of layers on the outer surface of the panel 1. Although not shown in the figure, an internal conductive film made of graphite or the like is formed on the inner surfaces of the funnel portion 2 and the neck portion 3. By adding titanium dioxide to the conductive film in addition to graphite, the arc can be suppressed and the resistance value can be limited. The conductive film is connected to the electron gun assembly bundle 11 through a high voltage terminal (not shown).

3 (a) is a vertical cross-sectional view showing the configuration / arrangement of the electronic unit constituting the electron lens portion of the inline type electron gun assembly according to an embodiment of the present invention, Figure 3 (b) is a line of Figure 3 (a) It is a horizontal sectional view of the aperture of this electrode unit 21 along (IIIb-IIIb). FIG. 3 (c) is a horizontal cross-sectional view of the electrode unit 22 seen along the line IIIc-IIIc in FIG. 3 (a), and FIG. 3 (d) is an electrode unit 21, 22 forming an electron lens. It is an operation explanatory diagram showing the equipotential lines in the inside.

3 (a) to 3 (d), (21) is a G3 electrode unit having a cylindrical member 21A having a bore of a non-circular extended end face, that is, an elliptical cross section, and (22) A G4 electrode unit having a cylindrical member 21B having a diameter of a circular extended cross section and an approximately elliptical cross section, 21B is a flat plate member formed on the inner wall of the cylindrical member 21A, and 22B is a cylindrical member 22A. A flat plate member formed on an inner wall of the flat plate, 25 is a central electron beam through hole of the flat plate member 21B, 26 is a central electron beam through hole of the flat plate member 22B, and 27 and 28 are flat plates. Both sides of the member 21B are electron beam through holes, and 29 and 30 are concave ends formed on the flat plate member 22B to interact with the inner wall of the cylindrical member 22A to form side beam through holes. For example, this recessed end is a notch. The members 41 to 43 are the same members as shown in FIG. 1 (a).

The G3 electrode unit 21 and the G4 electrode unit 22 located downstream of the G3 electrode with respect to the electron beam are arranged so that the direction of the large side in the elliptic sphere is substantially coincident with the horizontal direction. A low voltage of ₅ to 10 KV is applied to the G3 electrode unit 21 through the power supply terminal Ec ₃ , and a high voltage of 20 to 35 KV is applied to the G4 electrode unit 22 through the power supply terminal E _b . The G3 electrode unit 21, the G4 electrode unit 22, the plate member 21B inside the electrode unit 21, and the plate member inside the electrode unit 22 constitute an electron lens. The central electron beam through hole 25 of the plate member 21B and the central electron beam through hole 26 of the plate member 22B are substantially elliptical, and the direction of the longitudinal axis of the through hole coincides with the vertical direction. In addition, the center electron beam passage hole (2S) vertical dimension (d ₁₎ and the ball vertical dimension center electron beam passage of the plate members (22B) of (d _O) of the plate member (21B) satisfies the relation of d _1> d ₀ . The side electron beam through holes 27 and 28 of the plate member 21B have a shape obtained by cutting and connecting a semi-ellipse divided into half in the vertical direction and a semicircle having the same diameter as the vertical dimension. . The side electron beam passing cutouts 29 and 30 have a shape obtained by dividing and cutting an ellipse in half in the vertical direction. 500-600V and about 0V are applied to the G2 electrode 43 and the G1 electrode 42 through the power supply terminals Ec ₂ and Ec ₁ , respectively.

According to the above configuration, the central electron beam emitted from the cathode unit 41 passes through the G1 electrode unit 42 and the G2 electrode unit 43 and enters the G3 electrode unit 21. At this time, the vertical dimension d _O of the substantially elliptical central electron beam through hole 26 of the plate member 22B of the G4 electrode unit 22 and the plate member 21B inside the G3 electrode unit 21 of the electron lens. It is set smaller than the vertical dimension (d ₁ ) of the center electron beam through hole (25). In addition, the equipotential lines of the electron lens are shown in FIG. 3 (d) and are different from the equipotential lines shown in FIG. 1 (a).

The radius of curvature of the electron lens in the direction perpendicular to the dispersion side is smaller than the radius of curvature on the convergent side. That is, the beam dispersion function or beam divergence function of the electrode unit 22 in the vertical direction should be emphasized more than the beam convergence function or focusing function of the electrode unit 21 in the vertical direction, and in the vertical direction with respect to the central electron beam. The focus effect of is weakened.

FIG. 6 shows the center electron beam through hole 25 of the G3 electrode unit 21 having a diameter of 5.8 mm in the vertical direction by using the electron gun assembly bundle as shown in FIGS. 3 (a) to 3 (d). Has a diameter d ₁ between the deformation (vertical diameter / horizontal diameter) of the electron beam spot on the fluorescent surface and the vertical diameter d _O of the central electron beam through hole 26 of the G4 electrode unit 22. Shows the relationship.

As can be seen from FIG. 6, the beam spot becomes a complete circle having a diameter (d ₀ = 5.2 mm), that is, a d ₀ / d ₁ ratio = 0.897. According to the investigation of the present invention, assuming that the deformation of the electron beam spot is much larger than 1.2, the electron beam spot extends in the vertical direction so that the focus effect for the electron beam is degraded in the vertical direction (vertical resolution). On the other hand, assuming that the deformation of the electron beam spot is much smaller than 0.8, the electron beam spot is extended in the horizontal direction so that the focusing effect on the electron beam is reduced in the horizontal direction (vertical resolution). Therefore, the ratio of d _O / d ₁ should be 0.81 ≦ d _O / d ₁ ≦ 0.98.

Preferably, the deformation of the electron beam spot should be in the range of 1.0 to 1.1 from the viewpoint of the actual manufacture of the electron gun assembly bundle. In this case, the ratio of d _O / d1 is 0.85≤d _O / d ₁ ≤0.90. If the deformation of the electron beam spot is out of the above range, a halo is generated at the periphery of the screen and the focus is not uniform for all the screens, so that the color image having the electron gun assembly bundle even when corrected using a dynamic focus circuit is used. The image quality of the camera is somewhat degraded.

The above description with respect to FIG. 3 is applicable to the electron gun assembly bundles in which the electron beam passing holes have different sizes.

Therefore, in the inline type electron gun assembly having the electron lens of the prior art structure, when the kettle lens of this embodiment is used when the spot shape obtained by the central electron beam is to be extended in the horizontal direction, the focus effect in the vertical direction is horizontal. The spot shape obtained by the central electron beam can be corrected to a substantially circular shape.

Next, FIG. 4 (a) shows the structure / array of the electrode unit constituting the electron lens of the inline type electron gun assembly according to another embodiment of the present invention, and FIG. 4 (b) is shown in FIG. 4 (a). A horizontal sectional view seen along the lines IVb-IVb, showing a sectional view of the aperture of the electrode unit 21 seen in the horizontal direction. 4 (c) is a sectional view showing a cross section of the aperture viewed in the horizontal direction along the line IVc-IVc in FIG. 4 (a).

In FIG. 4 (b), (31) and (32) are side beam through holes of the plate member 121B of the G3 electrode unit provided with the cylindrical member 121A integrally on the inner wall of the cylindrical member 121A. It is a recessed end part as a notch part which forms a recess. The same reference numerals as the components in FIGS. 3 (a) to 3 (d) show the same configurations. E is the moving direction of the electron beam, and the cathode unit, G1 electrode unit, and G2 electrode unit are omitted in the drawing.

The side electron beam passing cutout of the flat plate member 121B is an electron beam passing cutout of the flat plate member 22B of the G4 electrode unit 22 including the cylindrical member 22B. It has a shape formed by dividing into.

When comparing this embodiment with the embodiment shown in Figs. 3 (a) to 3 (d), in this embodiment, the side electron beam transmission hole 27 of the flat plate member 21B of the G3 electrode unit, (28) has a shape obtained by adjoining a semicircle having vertically equal diameters and one semi-ellipse formed by dividing an ellipse vertically by half, and in this embodiment, ellipses in the direction of a large axis. The cutout portions 31 and 32 having a shape obtained by dividing into half form a side electron beam through hole integrally on the inner wall of the cylindrical member 121A. The rest of the configuration is the same.

In this embodiment, the function of the electron lens for the center electron beam is the same as the function of the electron lens for the center electron beam of the above embodiment. Therefore, further detailed description is omitted.

FIG. 5 (a) shows the structure / array of an electrode unit for forming an electron lens of an inline type electron gun assembly according to another embodiment of the present invention, and FIG. 5 (b) is a line of FIG. 5 (a) A cross-sectional view showing the cross section of the aperture in the horizontal direction along Vb-Vb).

FIG. 5 (c) is a sectional view showing the cross section of the bore in the horizontal direction along the line Vc-Vc in FIG. 5 (a).

In Fig. 5C, 33 and 34 are electron beam through holes of the flat member 222B of the G4 electrode unit 222 having the cylindrical member 222A. The same reference numerals are used for the same configuration as in FIG. 3 (d). E denotes the moving direction of the electron beam, and the cathode unit, G1 electrode unit, and G2 electrode unit are omitted in the drawing.

The side electron beam through holes 33 and 34 of the plate member 222B are the side electron beam through holes 27 and 28 of the plate member 21B of the G3 electrode unit 21 having the cylindrical member 21A. As shown in Fig. 2), a semicircle having the same diameter in the vertical direction and one semi-ellipse divided in half in the vertical direction have a shape obtained by adjacent connection.

In the first embodiment, the recessed portions forming the side electron beam through holes of the plate member 22B of the G4 electrode unit 22 are cutouts 29 and 30 obtained by cutting the ellipse in half in the vertical direction. to be. The present embodiment differs from the first embodiment in that electron beam through holes 33 and 34 having a shape obtained by adjacently connecting semi-ellipses cut in half in the vertical direction and having semi-circles having the same diameter in the vertical direction are used. , The rest of the configuration is the same.

In addition, in this embodiment, the function of the electron lens for the center electron beam is the same as the function of the electron lens for the center electron beam in the first embodiment. Therefore, detailed description is omitted.

According to the third embodiment as described above, the spot-shaped extension in the horizontal direction of the fluorescent surface with respect to the central electron beam has a cylindrical G3 electrode unit 21 having a substantially elliptical cross section having a longitudinal axis in the arrangement direction of the three electron beams. By using (121), (21) and G4 electrode units (22), (22), and (222), it can be prevented. Further, the collision of the electron beams facing the plate members 21B, 121B, 21B of the G3 electrode unit is to increase the ratio of the vertical diameter to the horizontal diameter of the central electron beam through hole of the plate member. Since the horizontal diameter of the central electron beam through hole of the plate member of the G3 electrode unit does not have to be reduced any more, it can be prevented. For example, for a color cathode ray tube having an inline electron gun assembly bundle having an electrode unit of the size shown in FIGS. 3 (b) and 3 (c), the central electron beam through hole of the G3 electrode unit 21 is provided. It can be seen that when the horizontal diameter of 25 is 4.0 mm or less, the central beam collides with the flat plate member 21B of the G3 electrode unit 21. However, according to the above embodiment, the horizontal diameter of the central electron beam through hole 25 of the G3 electrode 21 is 2.12 x 2 = 4.24 mm, so that a predetermined focusing effect can be achieved, see FIG. As described, it does not need to be reduced to 4.0 mm or less.

This embodiment deals with the case where the central electron beam incident on the electron lens is enlarged in the horizontal direction. When the central electron beam incident on the electron lens is extended in the vertical direction by the configuration and arrangement of the electrode units of the previous stages such as the G1 electrode unit and the G2 electrode unit, the spot shape extension to the fluorescent surface obtained by the central electron beam, the G3 electrode The vertical dimension d _l of the central electron beam through hole 25 of the flat plate members 21B, 121B, and 21B of the unit, and the flat plate members 22B, 22B, 222B of the G4 electrode unit. the vertical dimension (d ₀₎ of the center electron beam passage hole may be previously prevented by the embodiment and the like to configure so as to satisfy the relationship d ₁ <d _0.

The shape of the electron beam through hole in the above embodiment is an ellipse, but other shapes obtained by connecting semicircles to both ends of two parallel lines can be used in the present invention. As another example of the electron beam passing hole, there are non-rotating symmetrical shapes such as flat circular shape, quadrangular shape, hexagonal shape and the like extending in the vertical direction.

The large axis of the electron beam passing hole exists in the vertical direction, but the beam passing hole having the large axis in the horizontal direction is suitable depending on the arrangement position of the plate member of the G3 electrode unit and the G4 electrode unit or the shape of the diameter of the electrode unit. Sometimes.

As described above, the non-circular central electron beams formed on the plate members of the electrode unit on the low potential side and the high potential side constituting the electron lens each have different large axis dimensions. Therefore, since the focus adjustment of the center electron beam in the vertical direction can be appropriately corrected for the electron lens and can be made approximately the same as the focus adjustment in the horizontal direction, the spot shape on the fluorescent surface obtained by the center electron beam is formed in a substantially circular shape. can do.

In addition, since the spot shape on the fluorescent surface obtained by the central electron beam becomes substantially circular, astigmatism of the central electron beam can be eliminated, and the resolution of the image can be improved.

Claims (8)

A cathode unit for generating a central electron beam and two side electron beams, and being kept at first and second voltages during operation, passing the electron beams, and the first and second electrode units having a cylindrical member having a non-circular extension section; And a flat plate member formed on the inner wall of the cylindrical member, wherein three electron beam through holes are formed in parallel in the cylindrical member in the longitudinal direction of the non-circular extension section of the cylindrical member, and the flat plate member connects the central electron beam. An in-line electron gun assembly having at least one hole used as an electron beam through hole for said second electrode unit, said first and second electrode units being downstream of said first electrode unit with respect to the electron beam. The second voltage is associated with a first function of the first electrode unit in which the first electrode unit and the second electrode unit interact with each other to focus the electron beam. It is higher than the first voltage to form a main electrostatic lens combining the second function of the second electrode unit for emitting an electron beam, and perpendicular to the elongation of the elliptical cross section formed in the cylindrical member of the one electrode unit. The aperture of one of the first and second electrode units measured in the direction and the aperture of the plate member of the other electrode unit measured in a direction perpendicular to the longitudinal direction of the non-circular extended section of the cylindrical member. These different from each other, and due to the difference in diameter, either one of the first and second functions is emphasized in a direction perpendicular to the longitudinal direction of the non-circular extension section formed on the cylindrical member, compared to the other function. Inline electron gun assembly bundle, characterized in that possible. The diameter of the flat plate member of the first electrode unit is set so as to emphasize the second function as compared to the first function in a direction perpendicular to the longitudinal direction of the non-circular extension section of the cylindrical member. In-line electron gun assembly bundle, characterized in that larger than the diameter of the plate member of the second electrode unit. A cathode unit for generating a central electron beam and two side electron beams, passing three electron beams from the cathode unit, and maintained at a first voltage during operation, the elliptical cross section of the first cylindrical member and the first cylindrical member A first flat plate member formed on the inner wall, and having three electron beam through holes formed in parallel in the first cylindrical member in a direction parallel to the longitudinal axis of the elliptical cross section of the first cylindrical member, The first plate member has at least one elliptical hole serving as an electron beam through hole for the central electron beam, the elliptical hole having a short axis parallel to the long axis of the elliptical cross section of the first cylindrical member, and 3 Two electron beams emerge from the first electron beam with respect to the electron beam, and are maintained at a second voltage during operation, and the second cylindrical member having an elliptical cross section and the A second flat plate member formed on the inner wall of the second cylindrical member, wherein three electron beam through holes are formed in parallel in the second cylindrical member in a direction parallel to the axial direction of the elliptical cross section of the second cylindrical member; And the second flat plate member has at least one hole serving as an electron beam through hole for the central electron beam, and diverges the electron beam with the first function of the first electrode unit focusing the electron beam. In-line electron gun assembly bundle having a second electrode unit whose second voltage is higher than the first voltage so as to form a main electrostatic lens combining the second function of the second electrode unit so that the first and second electrode units work together. The diameter of the first flat plate member measured in a direction perpendicular to the longitudinal axis of the elliptical cross section of the first cylindrical member is the longitudinal axis of the elliptical cross section of the first cylindrical member. Perpendicular to the constriction of the elliptical cross section of the second cylindrical member in order to emphasize the second function in the direction perpendicular to the constriction of the elliptical cross section of the second cylindrical member compared to the first function in the vertical direction. In-line electron gun assembly bundle, characterized in that greater than the diameter of the elliptical shape of the second flat plate member measured in the direction. 4. The first ellipsoidal member of claim 3, wherein the first flat plate member has an elliptical shape and has three elliptical holes arranged in parallel in a direction parallel to the longitudinal axis of the first elliptic plate member. The second flat plate member has a short axis parallel to the elongated axis of the flat plate member, and the second flat plate member has one hole serving as the electron through hole for the central electron beam, and on the inner wall of the second cylindrical member, the two An in-line electron gun assembly bundle having a concave end for forming two electron beam through holes for a side electron beam facing each other. 4. The apparatus of claim 3, wherein the first and second plate members each have one hole that serves as the electron beam through hole for the central electron beam, and further, on the inner wall of the associated cylindrical member, for the two side electron beams. An inline electron gun assembly bundle comprising: a concave end portion that forms two electron beam through holes facing each other. 4. The flat panel of claim 3, wherein each of the first and second flat plate members is elliptical in shape, and has three holes in parallel in a direction parallel to the elongated flat member of the elliptical flat plate member. Inline electron gun assembly bundle characterized in that it has a parallel short axis. A cathode unit for generating a central electron beam and two side electron beams, and being kept at first and second voltages during operation, passing the electron beams, and the first and second electrode units having a cylindrical member having a non-circular extension section; And a flat plate member formed on the inner wall of the cylindrical member, wherein three electron beam through holes are formed in parallel in the cylindrical member in the longitudinal direction of the non-circular extension section of the cylindrical member, and the flat plate member connects the central electron beam. A color cathode ray having at least one hole used as an electron beam through hole for the second electrode unit, the in-line electron gun assembly bundle having first and second electrode units downstream of the first electrode unit with respect to the electron beam; In the tube, the second voltage is the first electrode in which the first electrode unit and the second electrode unit work together to focus the electron beam. And formed in the cylindrical member of one of the electrode units higher than the first voltage so as to form a main electrostatic lens combining the first function of the pole unit and the second function of the second electrode unit emitting the electron beam. The diameter of one of the first and second electrode units measured in the direction perpendicular to the longitudinal axis of the elliptical cross section, and the other measured in the direction perpendicular to the longitudinal direction of the non-circular extended section of the cylindrical member. The apertures of the flat plate members of the electrode unit are different from each other, and due to the difference in the apertures, either one of the first and second functions differs from the other in the longitudinal direction of the non-circular extension section formed in the cylindrical member. Color cathode ray tube with in-line electron gun assembly, characterized in that the emphasis in the vertical direction. A cathode unit for generating a central electron beam and two side electron beams, passing three electron beams from the cathode unit, and maintained at a first voltage during operation, the elliptical cross section of the first cylindrical member and the first cylindrical member A first flat plate member formed on the inner wall, and having three electron beam through holes formed in parallel in the first cylindrical member in a direction parallel to the longitudinal axis of the elliptical cross section of the first cylindrical member, The first plate member has at least one elliptical hole serving as an electron beam through hole for the central electron beam, the elliptical hole having a short axis parallel to the long axis of the elliptical cross section of the first cylindrical member, and 3 Two electron beams emerge from the first electron beam with respect to the electron beam, and are maintained at a second voltage during operation, and the second cylindrical member having an elliptical cross section and the And having a second flat plate member formed on the inner wall of the two cylindrical members, and forming three electron beam through holes in parallel in the second cylindrical member in a direction parallel to the axial direction of the elliptical cross section of the second cylindrical member. And the second flat plate member has at least one hole serving as an electron beam through hole for the central electron beam, and the first function of the first electrode unit focusing the electron beam and the second beam diverging the electron beam. An inline type electron gun assembly having a second electrode unit having a second voltage higher than the first voltage so that the first and second electrode units work together to form a main electrostatic lens combining the second functions of the electrode unit. In one color cathode ray tube, the diameter of the first flat plate member measured in a direction perpendicular to the longitudinal axis of the elliptical cross section of the first cylindrical member is an ellipse of the first cylindrical member. Elliptical top of the second cylindrical member to emphasize the second function in a direction perpendicular to the longitudinal axis of the elliptical cross section of the second cylindrical member as compared to the first function in the direction perpendicular to the longitudinal axis of the cross section of the image. A color cathode ray tube with an inline electron gun assembly bundle characterized in that it is larger than an elliptical aperture of the second flat plate member measured in a direction perpendicular to the longitudinal axis of the surface.