KR100267977B1 - Electron gun for cathode ray tube - Google Patents

Abstract

The present invention relates to an electron gun for a cathode ray tube to minimize the deformation of each electrode of the electron gun by the thermal expansion of the bead glass of the electron gun when the cathode ray tube is operated to easily stabilize the brightness characteristics of the screen and to stabilize the cathode current. To reduce the time it takes.

To this end, the present invention is a control electrode 13 and a plurality of control electrode embedding portion 20 is formed to control the electron beam (a) emitted from the cathode 10 supported by the cathode support 12, and the control electrode ( 13, a plurality of focusing electrodes focusing an acceleration electrode 14 having a plurality of acceleration electrode embedding parts 21 formed therein to accelerate the electron beam a controlled in 13, and an electron beam a accelerated by the acceleration electrode 14. The acceleration (15) (16) (17) (18), an anode (19) for finally accelerating the electron beam (a), and a bead glass (9) for fixing the electrodes, the acceleration In order to reduce the change in the distance between the control electrode 13 and the accelerating electrode 14, each accelerating electrode embedding part 21 of the electrode 14 is opposite to the thermal expansion direction of the accelerating electrode 14, that is, the focusing electrode ( It is formed to be inclined at a predetermined angle (β) to face 16).

Description

Electron gun for cathode ray tube

The present invention relates to a cathode ray tube, and more particularly to an electron gun for cathode ray tube.

A typical cathode ray tube generally uses an in-line electron gun, and in the cathode ray tube using the in-line electron gun, three electron beams of red (R), green (G), and blue (B) are arranged side by side. Because of the arrangement, the deflection yoke of the cathode ray tube adopts a self-convergence using a non-uniform magnetic field in order to converge three electron beams in one place of the fluorescent surface.

As shown in FIG. 1, the structure of the cathode ray tube includes a panel 1 mounted on the front surface of the cathode ray tube, and phosphors of red (R), green (G), and blue (B) surfaces on the inner surface of the panel 1. A fluorescent mask 3 coated with a shadow mask, a shadow mask 4 provided behind the fluorescent surface 3 and having a color discrimination function of an electron beam a incident on the fluorescent surface 3, and a rear surface of the panel 1. A funnel (2) coupled to and mounted inside the tubular neck (5) retracted to the rear of the funnel (2) and installed to keep the interior in a vacuum state (6) for firing an electron beam (a) ) And a deflection yoke 7 which surrounds the outer side of the funnel 2 and is arranged to deflect the electron beam a in the horizontal or vertical direction.

In the cathode ray tube of this structure, the panel 1 on which the fluorescent surface 3 is formed on the inner surface of the cathode ray tube and the funnel 2 coated with graphite having electrical conductivity on the inner side thereof are bonded to each other by fusion glass in a furnace at about 450 ° C.

The electron beam a is emitted from the electron gun 6 when an image signal is inputted to the electron gun 6 mounted to emit the electron beam a in the tubular neck portion 5 which is retracted behind the funnel 2. do.

The electron beam a emitted from the electron gun 6 is controlled, accelerated and focused while passing through each electrode of the electron gun 6 by a voltage applied to each electrode of the electron gun 6 and then to the deflection yoke 7. The image is reproduced by passing through the shadow mask 4 in the deflected state and colliding with the fluorescent surface 3 applied to the inner surface of the panel 1 to emit the phosphor.

At this time, the shadow mask 4 has three in-line electron beams (a) corresponding to red (R), green (G), and blue (B) emitted from the electron gun 6, centering on the green in the shadow mask 4. Crossed with each other to perform a color screening function to cause the fluorescent surface (3) of the red (R), green (G), blue (B) of the screen to emit light.

As described above, the rear surface of the funnel 2 coupled to the rear surface of the panel 1 so as to collide with the fluorescent surface 3 applied to the inner surface of the panel 1 of the cathode ray tube to emit phosphors to reproduce an image. The electrode structure of the electron gun 6 mounted inside the retracted tubular neck portion 5 to emit the electron beam a is located at the lower side of the electron gun 6, as shown in Figs. And a stem 8 made of stem glass so as to fusion-fix the lead wire and the lead wire so as to apply a voltage, and to the neck portion 5 of the cathode ray tube, and an upper portion of the stem 8 An inline arranged cathode 10 having a heater 11 therein so as to emit an electron beam a, a cathode support 12 for supporting the cathode 10, and an upper portion of the cathode support 12. The control electrode 13 for controlling the electron beam (a) emitted from the cathode 10, and the first An acceleration electrode 14 disposed above the electrode 13 to accelerate the electron beam a, and a plurality of focusing electrodes 15 and 16 disposed above the acceleration electrode 14 to focus the electron beam a. (17) and (18), and an anode electrode (19) provided above the dynamic focusing electrode (18) to finally accelerate the electron beam (a).

On the outside of each electrode of the electron gun 6, a plurality of electrode embedding portions 20, 21 are formed in parallel with the electrode and fixed to the bead grass 9, and the electrodes of the electron gun 6 are fixed to each other. The electron gun 6 is enclosed in the neck portion 5 of the cathode ray tube, spaced apart at intervals and sequentially arranged in the tube axis direction.

When the cathode ray tube electron gun configured as described above operates a planar cathode ray tube, a voltage of 6.3 V is applied from the heater 11 installed in the cathode 10 of the electron gun 6 to generate heat of about 1000 ° C., and the cathode 10 It is also heated to about 800 ℃.

The size of the electron beam a is controlled by the control electrode 13 of the electron beam a emitted from the heated cathode 10, and the controlled electron beam a is accelerated by the acceleration electrode 14 to focus. It is focused by the electrodes 15, 16, 17, 18 and then emitted by the electron gun 6 after finally accelerating by the anode electrode 19.

The electron beam a emitted from the electron gun 6 passes through the shadow mask 4 in a state deflected by the deflection yoke 7 and impinges on the phosphor surface 3 applied on the inner surface of the panel 1 to emit phosphors. The image is reproduced.

Here, when the cathode ray tube is activated, a phenomenon in which the brightness of the screen changes over an initial few minutes or several tens of minutes occurs, which is called white balance. This phenomenon is mostly caused by the thermal expansion of the electron gun 6, and in particular, the cathode support 12, the cathode 10, the control electrode 13, the acceleration electrodes 14, 15, and the focusing electrodes 16, 17 Change easily).

In more detail, the bead grass in the length (B) region from the lower end of the negative electrode support 12 for supporting the negative electrode 10 to the plurality of control electrode embedded portion 20 formed on the outside of the control electrode 13 Reference numeral 9 denotes about 13 μm of thermal expansion due to heat, and the bead glass 9 has about 8 μm of thermal expansion in the area A of the length from the control electrode 13 to the acceleration electrode 14. .

In addition, since the control electrode 13 and the acceleration electrode 14 are deformed by the heat generated from the cathode 10 of the electron gun 6, that is, the length D from the upper end of the cathode 10 to the control electrode 13. ) And the length C from the control electrode 13 to the acceleration electrode 14 are varied by the control electrode 13 and the acceleration electrode 14 which are deformed by the heat generated by the cathode 10.

At this time, since the thermal expansion amount of the bead glass 9 is relatively larger than the amount of deformation of the control electrode 13 and the acceleration electrode 14 by the heat generated from the cathode 10, the control electrode 13 and the acceleration electrode ( The spacing between 14 is greatly influenced by the bead grass 9.

Therefore, since the control electrode 13 and the acceleration electrode 14 installed in the horizontal state are deformed as indicated by the dotted lines in FIG. 3 by the heat generated from the cathode 10, the control electrode 13 and the acceleration electrode 14 are separated from each other. The gap becomes smaller and the gap between the upper end of the cathode 10 and the control electrode 13 becomes larger.

Thus, in Japanese Patent Laid-Open No. 6-84481, as shown in FIGS. 5A to 5C, the plurality of acceleration electrode embedding parts 21 formed on the outside of the acceleration electrode 14 maintain the horizontal state of the control electrode 13. The end of each control electrode embedded portion 20 was formed to face upward of the electron gun 6, that is, inclined at a predetermined angle α ₁ with the acceleration electrode 14.

That is, the ends of the control electrode embedding parts 20 are inclined in the thermal expansion direction (dotted direction) to couple the ends of the control electrode embedding parts 20 to the bead glass 9.

Therefore, when the control electrode 13 and the acceleration electrode 1 are deformed by the heat generated in the cathode 10, the control electrode 13 is deformed less than the horizontal state, and thus the upper end of the cathode 10 and The spacing between the control electrodes 13 becomes smaller than when the control electrodes 13 are formed in a horizontal state, but the spacing between the control electrodes 13 and the acceleration electrodes 14 becomes larger.

In addition, as shown in FIGS. 6A to 6C, each control electrode embedding portion 20 of the control electrode 13 maintains a horizontal state, and an end of each accelerating electrode embedding portion 21 of the acceleration electrode 14 is formed. It was formed to face downward of the electron gun 6, that is, to be inclined at a predetermined angle α ₂ with the control electrode 13.

That is, the ends of each of the accelerating electrode embedding parts 21 are formed to be inclined in the thermal expansion direction (dotted direction) to couple the ends of each of the accelerating electrode embedding parts 21 to the bead glass 9.

Therefore, when the control electrode 13 and the acceleration electrode 14 are deformed by the heat generated from the cathode 10, the acceleration electrode 14 is deformed less than the horizontal state, thereby accelerating with the control electrode 13. The distance between the electrodes 14 becomes larger than when the control electrode 13 and the acceleration electrode 14 are kept horizontal.

As described above, the control electrode 13 and the acceleration electrode 14 are formed in a horizontal state, or the end of the control electrode embedding portion 20 of the control electrode 13 is inclined in the thermal expansion direction (α ₁ ) or the acceleration By forming the end of the accelerating electrode embedding portion 21 of the electrode 14 inclined in the thermal expansion direction (α ₂ ), the electron beam a cannot be stably emitted from the cathode 10 of the electron gun 6.

That is, as shown in the graph shown in FIG. 12, the cathode current lk is initially low, the dispersion between the cathodes is large, and the cathode current lk takes a long time to stabilize. Not only is it difficult to manufacture, but also the luminance change is large during the initial operation of the cathode ray tube, resulting in a visually bad image, which in turn causes a poor luminance.

The present invention has been made to solve the above problems, and when the cathode ray tube is operated to minimize the deformation of each electrode of the electron gun by the thermal expansion of the bead glass of the electron gun to easily stabilize the brightness characteristics of the screen and Together, the objective is to reduce the time it takes for the cathode current to stabilize.

In order to achieve the above object, the present invention provides a control electrode formed with a plurality of control electrode embedding portion to control the electron beam emitted from the cathode supported on the cathode support, and a plurality of acceleration electrodes to accelerate the electron beam controlled by the control electrode An acceleration electrode having a buried portion, a focusing electrode for focusing an electron beam accelerated by the acceleration electrode, an anode electrode for finally accelerating the electron beam, and a bead glass for fixing the electrodes, wherein each of the acceleration electrodes Provided is an electrode structure of an electron gun for a cathode ray tube, characterized in that the acceleration electrode embedding portion is formed to be inclined at a predetermined angle (β) to face the focusing electrode.

1 is a schematic structural diagram for explaining the structure of a typical cathode ray tube.

2 is a cross-sectional view showing a conventional electron gun of a cathode ray tube.

3 is a cross-sectional view showing a triode of a conventional electron gun.

4A and 4B are diagrams illustrating acceleration electrodes of a conventional electron gun.

4C and 4D show control electrodes of a conventional electron gun.

Figure 5a is another embodiment showing a triode of a conventional electron gun.

5B and 5C are diagrams illustrating control electrodes of a conventional electron gun.

Figure 6a is another embodiment showing a triode of a conventional electron gun.

6B and 6C are diagrams illustrating acceleration electrodes of a conventional electron gun.

7 is a cross-sectional view showing a three pole portion of the electron gun for a cathode ray tube of the present invention.

8A and 8B are views showing an acceleration electrode of the electron gun of the present invention.

9 is another embodiment showing the three-pole portion of the electron gun for the cathode ray tube of the present invention.

10a and 10b are views showing an acceleration electrode of the electron gun of the present invention.

11A and 11B show control electrodes of the electron gun of the present invention.

12 is a graph showing a conventional cathode current change diagram.

13 is a graph showing a cathode current change diagram of the present invention.

Explanation of symbols for main parts of the drawings

9: bead grass 10: cathode

11: cathode support 13: control electrode

14: acceleration electrode 16: focusing electrode

20: control electrode embedding portion 21: acceleration electrode embedding portion

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 7 to 8B.

Since the structure of the electron gun for cathode ray tubes has been mentioned in the conventional configuration, overlapping portions are omitted, and only the same structure is given the same reference numeral as in the prior art.

7 is a cross-sectional view showing a three-pole portion of the electron gun for the cathode ray tube of the present invention, Figures 8a and 8b is a view showing the acceleration electrode of the electron gun of the present invention, the present invention is released from the cathode 10 supported by the cathode support 12 A control electrode 13 in which a plurality of control electrode embedding portions 20 are formed to control the electron beam a is provided, and a plurality of acceleration electrode embeddings to accelerate the electron beam a controlled by the control electrode 13 are provided. An acceleration electrode 14 having a portion 21 formed thereon is provided.

A focusing electrode 16 for focusing the electron beam a accelerated by the accelerating electrode 14 is provided, and an anode electrode 19 for finally accelerating the electron beam a is provided. Bead glass 9 to be fixed is provided.

The ends of the control electrode embedding portions 20 and the acceleration electrode embedding portions 21 are embedded in the bead glass 9 and fixed.

Each accelerating electrode embedding part 21 of the accelerating electrode 14 has a control electrode 13 in the opposite direction to the thermal expansion direction of the accelerating electrode 14, that is, in order to reduce the change in the gap between the accelerating electrodes 14. It is formed to be inclined at a predetermined angle β to face the electrode 16.

As another embodiment of the electrode structure of the electron gun of the present invention, as shown in FIGS. 9A to 11B, each of the acceleration electrode embedding portions 21 of the acceleration electrode 14 installed in the electron gun 6 faces the focusing electrode 16. It is formed to be inclined at a predetermined angle β so that each control electrode embedding portion 20 of the control electrode 13 faces the focusing electrode 16 to appropriately adjust the amount of the cathode current lk and the settling time. It is formed to be inclined at a predetermined angle β ₁ so as to.

The operation of the present invention configured as described above is as follows.

First, when the cathode ray tube is operated, a voltage of 6.3 V is applied to the heater 11 installed at the cathode of the electron gun 6 to generate heat of about 1000 ° C., and the cathode 10 is also heated to about 800 ° C.

At this time, the control electrode 13 is deformed to the acceleration electrode 14 side and the acceleration electrode 14 to the control electrode 13 side by the heat generated from the cathode 10 of the electron gun 6, that is, the acceleration electrode 14 ), The plurality of acceleration electrode embedding parts 21 formed at the outside of the acceleration grease 9 at an end thereof are inclined in a direction opposite to the thermal expansion direction (dotted line in FIG. 7) of the acceleration electrode 14. 16 is formed to be inclined at a predetermined angle β so that the deformation of the accelerating electrode 14 is reduced by the heat generated from the cathode 10, and thus, between the control electrode 13 and the accelerating electrode 14. The gap change is reduced.

Therefore, as shown in the graph shown in FIG. 13, the cathode current lk can be initially higher than the conventional one, and the time required for stabilization of the cathode current lk is reduced and the luminance change during the initial operation of the cathode ray tube is reduced. It becomes small.

In another embodiment of the present invention, as shown in FIGS. 9 to 11B, when the cathode ray tube is operated, the electron beam a is emitted from the electron gun 6, wherein the cathode 10 of the electron gun 6 is released. ), The control electrode 13 of the electron gun 6 is deformed to the acceleration electrode 14 side, and the acceleration electrode 14 is deformed to the control electrode 13 side.

At this time, the plurality of acceleration electrode embedding portions 21 formed at the outside of the acceleration electrode 14 and fixed to the bead glass 9 are opposite to the thermal expansion direction of the acceleration electrode 14, that is, the focusing electrode. A plurality of control electrode embedding parts 20 are formed to be inclined at a predetermined angle β so as to face the 16 and are formed outside the control electrode 13 and fixed to the bead glass 9 at the ends thereof. Since it is formed to be inclined at a predetermined angle (β ₁ ) to face the 16, the cathode 10 as the deformation of the control electrode 13 and the acceleration electrode 14 by the heat generated from the cathode 10 is made less The distance between the top of the control electrode 13 and the control electrode 13 is reduced than when the control electrode 13 is horizontal, the change in the distance between the control electrode 13 and the acceleration electrode 14 is reduced.

Therefore, as shown in the graph shown in FIG. 13, the cathode current lk can be initially higher than the conventional one, and the time required for stabilization of the cathode current lk is reduced and the luminance change during the initial operation of the cathode ray tube is reduced. It becomes small.

As described above, according to the present invention, each control electrode embedding part of the electron gun is fixed to the bead glass in a horizontal state, and each acceleration electrode embedding part of the electron gun is fixed in a direction opposite to the thermal expansion direction of the acceleration electrode, that is, toward the focusing electrode. By forming the inclined at an angle (beta), the deformation caused by the thermal expansion of the bead glass by the heat generated from the cathode is buffered to reduce the change in the distance between the acceleration electrode and the control electrode.

Therefore, the cathode current lk of the electron gun may not only come out higher than conventionally as shown in the graph shown in FIG. 13 but also the manufacturing time of the cathode ray tube is easy as the time required for the cathode current lk to be stabilized is reduced. It's losing.

In addition, since the luminance change is small during initial operation of the cathode ray tube, the luminance characteristic of the screen is stabilized.

Claims (2)

A control electrode having a plurality of control electrode embedding portions formed thereon to control the electron beam emitted from the cathode supported by the cathode support, an acceleration electrode having a plurality of acceleration electrode embedding portions formed to accelerate the electron beam controlled by the control electrode, and at the acceleration electrode A focusing electrode for focusing an accelerated electron beam, an anode for finally accelerating the electron beam, and a bead glass for fixing the respective electrodes, Electron gun for cathode ray tube, characterized in that formed to be inclined at a predetermined angle (β) so that each of the acceleration electrode embedded portion of the acceleration electrode toward the focusing electrode. The method of claim 1, Electron gun for cathode ray tube, characterized in that each control electrode embedded part of the control electrode is inclined at a predetermined angle (β ₁ ) to face the focusing electrode.