KR20000038579A - Electric gun for color cathode ray tube - Google Patents

Abstract

PURPOSE: An electric gun for a color cathode ray tube is provided to improve the resolution at the peripheral portion of the screen by preventing the weakening of the dynamic magnetic field. CONSTITUTION: A color cathode ray tube is divided into a fixing voltage collecting electrode to which a constant voltage is applied and a variable voltage collecting electrode to which a variable voltage is applied. A dynamic lens is formed between the divided collecting electrodes. A electric beam passing hole is formed on the opposite surface of the fixing voltage collecting electrode and the variable voltage collecting electrode. A plurality of electric beam passing holes are formed on the opposite surface of the variable voltage collecting electrode and the fixing voltage collecting electrode. Correcting electrodes are installed above and under the plurality of electric beam passing holes.

Description

Electron gun for colored cathode ray tube

The present invention relates to a color cathode ray tube, and more particularly, to improve a horizontal level of a correction electrode installed in a variable voltage focusing electrode so as to easily control astigmatism at a periphery of a screen, which is an operation target of a 4-pole lens. The electron gun for a color cathode ray tube.

In the general color cathode ray tube, as shown in FIG. 1, R, G, and B phosphors are coated on the inner surface of the panel 1 to form a fluorescent film 2, and behind the panel 1, a neck portion 3a is disposed. The funnel 3 in which the electron gun 4 is enclosed is fused to maintain a high vacuum inside.

A shadow mask 6, which serves as color screening of the electron beam 5 emitted from the electron gun 4, is fixed to the support frame 7 at a portion adjacent to the fluorescent film 2 coated on the inner surface of the panel 1. And a deflection yoke 8 for deflecting the electron beam 5 emitted from the electron gun 4 in the vertical or horizontal direction is provided on the outer circumferential surface of the funnel 3.

The stem 9 is fixed to the outside of the electron gun 4, that is, at the end of the neck portion 3a to be exposed to the outside, and a voltage is applied to each electrode of the electron gun through a plurality of stem pins 10 fixed to the stem. Will be applied.

On the other hand, the electron gun 4 is largely composed of a triode and a main lens portion as shown in FIG.

The three-pole part has three cathodes 11 each having a heater 12 as a heat source and are arranged side by side horizontally independently of each other, and are arranged to maintain a predetermined distance from the cathode to control hot electrons generated from the cathode. The control electrode 13 and the acceleration electrode 14 arranged to maintain a predetermined distance from the control electrode to attract and accelerate the hot electrons gathered on the surface of the electron-emitting material of the cathode.

The main lens unit includes a focusing electrode 15 for focusing and finally accelerating the electron beam generated in the triode and an anode 16 for finally accelerating the electron beam.

The control electrode 13 is grounded, a low voltage of about 500 to 1000 V is applied to the acceleration electrode 14, a high voltage of about 25 to 35 KV is applied to the anode 14, and an anode voltage to the focusing electrode 15. An intermediate voltage corresponding to 25 to 35% of is applied.

The conventional electron gun 4 configured as described above has an electrostatic lens formed therebetween by a potential difference applied to the focusing electrode 15 and the anode 16 as a predetermined potential is applied to each electrode, thereby generating an electron beam. (5) is focused on the center of the fluorescent surface by the electrostatic lens.

At this time, in order to reproduce an image, an electron beam must be sequentially scanned on each area of the screen, and for this purpose, the electron beam must be deflected to the entire area of the screen, which is typically a color cathode ray using an in-line type electron gun 4. In the tube, the three red, green, and blue electron beams 5 are arranged side by side horizontally, so that each electron beam is converged to one point of the fluorescent surface. A self-convergence deflection yoke using a non-uniform magnetic field ( 8) is applied.

The horizontal and vertical deflection magnetic fields (non-uniform magnetic field) can be divided into two-pole component and four-pole component, as shown in Figure 3a and 3b, the bipolar component serves to deflect the electron beam 5 in the horizontal and vertical direction The 4-pole component focuses the electron beam in the vertical direction and diverges in the horizontal direction, so that the vertical beam is focused at a shorter distance than the horizontal beam, so that the vertical direction of the beam bulges on the screen. It causes a phenomenon and causes deterioration.

4A and 4B show in more detail how distortion of the electron beam spot appears on the screen.

That is, since the deflection magnetic field is not applied at the center of the screen, the electron beam spot has an accurate circular shape, but at the periphery thereof, as described above, the electron beam spot is diverged in the horizontal direction by the action of the DY lens, and is over-condensed in the vertical direction and is distorted. Since the core 17 and the halo 18 which are low density up-and-down spreading areas generate | occur | produce up and down, it acts as a cause which lowers the resolution especially in the screen periphery part.

FIG. 5A shows the principle that the electron beam spot represented by the deflection yoke generates astigmatism without being focused at the periphery of the screen.

That is, even in the case of a uniform magnetic field, the beam spot is distorted due to astigmatism at the periphery of the fluorescent surface due to the fine pincushion or barrel magnetic component. Therefore, it is natural that the electron beam is distorted at the periphery of the screen even when a non-uniform magnetic field is adopted. Can be.

In addition, this problem is aggravated as the water pipe becomes larger or the angle of deflection becomes larger, and it is one of the tasks that must be solved in consideration of the tendency of consumers who prefer a large water pipe and the increase in the deflection angle according to the size of the water pipe. .

In order to solve the above problem, the four-pole component is generated by the electron gun to cancel the four-pole component generated by the self-focusing deflection yoke 8 so that the electron beam components in the horizontal and vertical directions can be focused at one point at the same time.

That is, to form a four-pole lens, the focusing electrode 15 is divided into a first focusing electrode 19 and a second focusing electrode 20, and a low voltage is applied to the first focusing electrode 19, and a second focusing electrode ( In Fig. 20, astigmatism can be corrected by forming a four-pole lens by generating a potential difference on the dynamic four-pole electrode by applying a high voltage, respectively.

However, when the electron beam is deflected to the periphery of the screen due to the difference of the electron beam moving distance between the center and the periphery of the screen, a dynamic voltage (variable voltage) synchronized with the deflection frequency is applied to weaken the power of the main lens to reduce the focal length of the beam. The method of correcting the astigmatism of the electrostatic lens by adjusting is mainly adopted.

The astigmatism correction means is briefly described with reference to FIGS. 6 to 8 through the conventional embodiments as follows.

FIG. 6 shows correction means disclosed in US Pat. No. 5,061,881 of Matsushita, Japan, wherein three rectangular electron beam through-holes 19a, 19b, 19c are formed in the first focusing electrode 19 in an elongated shape as shown in FIG. In the second focusing electrode 20, a plurality of three rectangular electron beam through-holes 20a, 20b, and 20c having a horizontal shape are formed in the second focusing electrode 20, and a quadrupole lens is formed therebetween. Forming to correct astigmatism at the screen periphery.

That is, the electron beam generated in the triode portion, which is the region in which the electron beam 5 is formed, passes through the first and second focusing electrodes 19 divided by the second focusing electrode 20 and is focused on the main lens, thereby forming an image on the screen.

In particular, when the electron beam 5 is deflected to the periphery, the voltage (constant voltage) applied to the first focusing electrode 19 is fixed, but the voltage (variable voltage) applied to the second focusing electrode 20 is the electron beam 5. Since it changes in synchronization with the deflection amount of?), The quadrupole lens is operated by the quadrupole electrode.

In general, the larger the CRT or the larger the deflection angle, the higher the voltage applied to the second focusing electrode 20 is than the voltage applied to the first focusing electrode 19.

The voltage applied to the second focusing electrode 20 is supplied as a parabola waveform in a circuit of a TV or a monitor, and is usually applied at a level of about 300 to 1000 V higher than the voltage applied to the first focusing electrode 19.

That is, when a voltage is applied to the second focusing electrode 20, a quadrupole lens operates due to a voltage difference applied to the first focusing electrode 19 and a voltage applied to the second focusing electrode 20, so that the electron beam spot is operated. The shape changes to an elongate shape, and thus acts in a direction to improve halo, which is a perturbation of the peripheral portion generated by the non-uniform magnetic field of the deflection yoke through the main lens.

5B is a conceptual diagram showing the principle that the path of the electron beam is corrected to match the focal point of the peripheral part when the quadrupole lens is used, and the ratio of the deflection yoke 8 by the quadrupole in the same focusing force of the main lens is shown. It shows the state which compensated the difference of score.

The quadrupole lens focuses in the horizontal direction by the horizontal divergence force of the deflection yoke 8, and the quadrupole lens diverges in the vertical direction by the amount of focusing in the vertical direction of the deflection yoke 8.

For this purpose, a main lens weakening component (dynamic voltage) is required, and this main lens weakening component plays a role of converging the electron beam at any position of the peripheral portion as shown in FIG. 5B to coincide in both horizontal and vertical directions.

In this way, the proper four-pole lens and the dynamic voltage can ensure that the electron beam has an optimal focusing force at the periphery of the screen.

However, such a conventional electron gun cannot correct the fine halo phenomenon (FIG. 9B) caused by the difference in deflection force (FIG. 9A) between the electron beam deflected on the outside and the electron beam deflected on the inside of the three electron beams (fine on the right side of the screen). Halo size: B <G <R, fine halo size on the left side of the screen: R <G <B).

In the case of a deflection yoke using a non-uniform magnetic field, the deflection force becomes stronger toward the periphery (FIG. 9A), whereby the three electron beams generate a difference in deflection force for each of them, thereby causing a path difference for each of them. Since it is impossible to correct, there was a problem that a fine halo is generated in the periphery.

In order to solve the above problems, as shown in Fig. 10 to the plate formed with the electron beam through holes formed on the upper and lower three electron beam through holes 20a, 20b, 20c formed in the second focusing electrode 20 is applied The horizontal flat electrode 21 was formed so as to be perpendicular with respect to the lens, and the astigmatism was corrected.

However, in the above structure, the stability of the image quality can be maintained only when the horizontal flat electrode 21 maintains a more stable state against a slight change in the degree of impact and thermal expansion.

At this time, the parallelism tolerance of the horizontal plate electrode 21 should maintain a high precision within 5㎛, if the deviation of the above-described tolerances of the dynamics acting on each of the three R, G, B electron beam is different According to the load, there is a problem that causes deterioration of image quality on the screen.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and an object thereof is to improve image quality at a screen periphery.

In order to achieve the above object, the present invention divides a focusing electrode into a fixed voltage focusing electrode to which a constant voltage is applied and a variable voltage focusing electrode to which a variable voltage is applied, thereby forming a dynamic quadrupole lens between the divided two focusing electrodes. In a colored cathode ray tube as possible;

One electron beam passing hole is formed on the variable voltage focusing electrode facing surface of the fixed voltage focusing electrode,

A plurality of electron beam through holes are formed on the opposing surface of the fixed voltage focusing electrode of the variable voltage focusing electrode, and a correction electrode protruding in a keyhole shape is provided above and below the plurality of electron beam passing holes. The present invention provides an electron gun for a color cathode ray tube.

1 is a longitudinal cross-sectional view of a typical colored cathode ray tube

2 is a basic configuration of a conventional electron gun

3A is an exploded explanatory diagram of a two-pole component and a four-pole component of a pin cushion type horizontal deflection magnetic field;

3B is an exploded explanatory diagram of the dipole and quadrupole components of the barrel-type vertical deflection magnetic field;

Figure 4a is a view showing the shape of the distorted electron beam spot on a conventional color CRT screen

4B is a view showing a shape in which an electron beam spot is distorted by a deflection magnetic field.

5A is an optical model diagram showing astigmatism and electron beam trajectory caused by deflection yoke

5B is an optical model diagram showing an electron beam trajectory when a 4-pole lens is applied.

6 is a longitudinal sectional view showing conventional astigmatism correction means;

FIG. 7 is a front view of the first focusing electrode shown in FIG. 6. FIG.

FIG. 8 is a front view of the second focusing electrode shown in FIG. 6. FIG.

9a to 9d are views showing a fine halo phenomenon due to a difference in deflection force of an electron beam;

10 is a longitudinal sectional view of a conventional focusing electrode provided with a horizontal flat electrode to correct astigmatism;

11 is a perspective view showing a first embodiment of the present invention variable voltage focusing electrode

12 is a perspective view showing a second embodiment of the present invention variable voltage focusing electrode

13 is a perspective view showing a third embodiment of the present invention variable voltage focusing electrode

14 is a perspective view showing a fourth embodiment of the present invention variable voltage focusing electrode;

15 is a longitudinal cross-sectional view showing a state in which the variable voltage focusing electrode and the fixed voltage focusing electrode of the present invention are coupled;

Explanation of symbols for main parts of the drawings

15: focusing electrode 22: fixed voltage focusing electrode

23 variable voltage focusing electrode 24 flat plate

25: correction electrode 25a: groove

220, 230, 231, 232: electron beam through hole

11 is a perspective view showing a first embodiment of the variable voltage focusing electrode of the present invention, FIG. 12 is a perspective view showing a second embodiment of the variable voltage focusing electrode of the present invention, and FIG. 13 is a perspective view of the variable voltage focusing electrode of the present invention. 3 is a perspective view showing a third embodiment, and FIG. 14 is a perspective view showing a fourth embodiment of the variable voltage focusing electrode of the present invention, and FIG. 15 shows a state in which the variable voltage focusing electrode and the fixed voltage focusing electrode of the present invention are coupled. As a longitudinal cross-sectional view, the electron gun for color cathode ray tubes of this invention is demonstrated in detail with reference to these accompanying drawings as follows.

According to the present invention, a dynamic voltage is applied between the focusing electrodes by applying a constant voltage to the focusing electrodes on one side of the focusing electrodes divided by dividing the focusing electrodes 15 and applying a variable voltage in synchronization with the deflection current to the focusing electrodes on the other side. The lens was allowed to form.

In this case, the focusing electrode to which the constant voltage is applied will be referred to as the fixed voltage focusing electrode 22, and the focusing electrode to which the variable voltage is applied will be referred to as the variable voltage focusing electrode 23.

A single electron beam through hole 220 having a race track shape is formed on a surface of the fixed voltage focusing electrode 22 opposite to the variable voltage focusing electrode.

In addition, a plurality of (three) electron beam through holes 230 may pass through the flat plate 24 of the variable voltage focusing electrode 23 facing the single electron beam through hole 220 so that R, G, and B beams may pass through, respectively. 231 and 232 are formed.

In addition, the flat plate 24 is provided with a correction electrode 25 protruding in the vertical direction to correct astigmatism, and the correction electrode 25 has images of the plurality of electron beam passing holes 230, 231, 232. , A plurality of grooves 25a protruding downward are formed.

Since the end of the correction electrode 25 is fixed to the flat plate 24 by welding, the curved electrode 25 may have a curved shape rather than a flat shape to improve weldability, as well as fixing force and stability to heat of the flat plate 24. The groove 25a formed in the correction electrode 25 is formed based on this reason because it can be strengthened.

As described above, the correction electrode 25 for the purpose of enhancing weldability, fixing force, and stability to heat may be applied in various forms as shown in FIGS. 11 to 14.

That is, as shown in FIG. 11, the outer shape of the correction electrode 25 is formed in a keyhole shape, but is installed around the electron beam passing holes 230, 231, 232 formed in the flat plate 24, and FIG. As shown in FIGS. 12 to 13, the correction electrode 25 is divided into two parts and installed at the upper and lower portions of the electron beam passing holes 230, 231, and 232, respectively, or the correction electrode 25 is divided into six parts to pass the electron beam. The balls 230, 231 and 232 can be applied to the upper and lower portions respectively.

In addition, as shown in FIG. 14, the thickness of the correction electrode 25 is increased to increase the contact area with the flat plate 24, thereby welding the flat plate to prevent the horizontal state from being changed due to external influences. Applicable

On the other hand, the correction electrode 25 is inserted into a single electron beam through hole 220 formed in the fixed voltage focusing electrode 22, so that the dynamic action is further enhanced.

Referring to the operation of the present invention configured as described above are as follows.

The present invention divides the focusing electrode 15 into two and applies a low voltage to the fixed voltage focusing electrode 22 and a high voltage to the variable voltage focusing electrode 23 to generate a potential difference on the dynamic quadrupole electrode. Astigmatism was corrected by allowing the lens to form.

At this time, the correction electrode 25 formed on the flat plate 24 of the variable voltage focusing electrode 23 forms a four-pole lens for dynamic operation, and the dynamic power is determined according to its horizontality.

In other words, when the correction electrode 25 is at an equilibrium level, an improved dynamic effect can be obtained. On the contrary, when the level is lowered due to expansion and contraction due to external fine impact or heat conducted from the outside, the dynamic action is weakened, resulting in astigmatism. The correction degree of is weak.

Accordingly, the grooves 25a are formed in the vertical direction of the electron beam through holes 230, 231, and 232 of the correction electrode 25, so that the flat plate 24 of the variable voltage focusing electrode 23 is larger than the flat correction electrode. By increasing the contact area with), the weldability and the fixing force after welding can also be improved, thereby solving the problem that the horizontality is changed by the external action described above.

Particularly, in order to obtain a more powerful fixing force, as shown in FIG. 11, the correction electrode 25 has an integral rectangular tube shape and is welded around the electron beam passing holes 230, 231, 232 formed in the flat plate 24. 12, the correction electrode 25 is divided into two parts as shown in FIG. 12, and the upper and lower portions of the electron beam passing holes 230, 231 and 232 are respectively fixed or fixed as shown in FIG. 13. By dividing the into six parts it can be applied to the form of fixing by welding the upper and lower portions of the electron beam through hole 230, 231, 232, respectively.

However, as shown in FIG. 12 and FIG. 13, the divided electrode 25 is divided into two parts, as shown in FIG. The shape of the correction electrode 25 has a more advantageous advantage in the position for welding as well as weldability can be said to be the most recommended form.

In addition, as shown in FIG. 14, when the thickness of the correction electrode 25 is increased, the contact area with the flat plate 24 is increased, thereby improving the welding strength and horizontally without significantly affecting external effects. Of course, the degree can be maintained.

Meanwhile, when the fixed voltage focusing electrode 22 and the variable voltage focusing electrode 23 are coupled as shown in FIG. 15, the correction electrode 25 formed on the variable voltage focusing electrode is positioned inside the fixed voltage focusing electrode 22. In this case, a more powerful dynamic magnetic field can be obtained, which further improves astigmatism correction.

The present invention as described above has the advantage of improving the resolution at the periphery of the screen by preventing the weakening of the dynamic magnetic field by maintaining the constant constant constant by strengthening the fixing force of the variable voltage focusing electrode to the fixed voltage focusing electrode Will be equipped.

Claims (3)

A color cathode ray tube in which a focusing electrode is divided into a fixed voltage focusing electrode to which a constant voltage is applied and a variable voltage focusing electrode to which a variable voltage is applied, so that a dynamic quadrupole lens is formed between the divided focusing electrodes; One electron beam passing hole is formed on the variable voltage focusing electrode facing surface of the fixed voltage focusing electrode, A plurality of electron beam through holes are formed on the opposite surface of the fixed voltage focusing electrode of the variable voltage focusing electrode. An electron gun for a color cathode ray tube, characterized in that the upper and lower portions of the plurality of electron beam passing holes are provided with a correction electrode protruding in a keyhole shape. The method of claim 1, Electron gun for color cathode ray tube, characterized in that the correction electrode is a unitary body. The method of claim 1, Electron gun for color cathode ray tube, characterized in that the correction electrode is divided into a plurality.