KR100249214B1 - Color cathode ray tube - Google Patents

Abstract

The present invention relates to a color cathode ray tube, so that two or more focusing voltages can be applied to an electron gun employed in a cathode ray tube having a necked neck in order to reduce power consumption when driving the cathode ray tube.

To this end, the neck portion in the cathode ray tube composed of a panel 1 to which the phosphor layer 2 is applied, and a thin neck portion 4a in which the electron gun 5 is accommodated, and a funnel 4 fused to the panel. In the case where the stem 6 mounted with the electron gun is sealed, the stem pin 9 fixed to the stem is bent outward so that the pin circle located inside the neck is extended to apply a dynamic voltage between the plurality of stem pins. The stem pin 10 is positioned, or the pin circles φ ₁ and φ _{2 of} the stem pins 9 and 10 located inside the neck are zigzag differently from the stem pins.

Description

Colored cathode ray tube

The present invention relates to a color cathode ray tube, and more specifically, to reduce power consumption when driving the cathode ray tube, so that at least two focusing voltages can be applied to an electron gun employed in a cathode ray tube having a thin neck portion. .

In general, as shown in FIG. 1, a color cathode ray tube includes a panel 1 in which a phosphor layer 2 is formed on an inner surface thereof, and a shadow mask 3 is fixed to be maintained at a predetermined distance from the phosphor layer. A thin neck portion 4a is formed at the rear, and a funnel 4 fused and fixed to the panel, and an electron gun 5 accommodated in the neck portion to radiate the electron beam 7 to the phosphor layer side; And, the electron gun is mounted and consists of a stem (6) is sealed (sealing) in the neck portion, after the stem (6) is sealed in the neck portion (4a) through the exhaust pipe 6a formed in the stem By making the inside of the cathode ray tube in a vacuum state and melting and sealing the exhaust pipe 6a formed in the stem 6, the cathode ray tube is made.

A deflection yoke 8 for deflecting the electron beam 7 radiated from the electron gun 5 is provided on the outer circumferential surface of the neck portion 4a of the cathode ray tube constructed as described above.

Therefore, when a heater installed inside a cathode (not shown) located on the stem 6 side of the electron gun 5 generates heat, electrons are emitted from the oxide coated on the upper surface of the cathode.

The electrons emitted from the oxide of the cathode pass through each of the electrodes arranged at regular intervals to form an electron beam having a desired characteristic.

The electron beam thus formed is deflected by the magnetic field formed by the deflection yoke 8 and then passes through the shadow mask 3 which serves as color screening, and then hits the phosphor layer 2 applied on the inner surface of the panel 1 to emit phosphors. The image is reproduced.

In order for the above operation to be performed smoothly, the inside of the cathode ray tube must be maintained in a vacuum state. For this, a stem 6 having a plurality of stem pins 9 for supplying power to the electron gun and an exhaust pipe 6a for exhausting is formed. ) Is assembled to the neck portion 4a, and the connection surfaces thereof are melted by heat melting to seal the inside of the cathode ray tube through the exhaust pipe 6a, and then the exhaust pipe 6a is melted and sealed to obtain the cathode ray tube. The inside can be kept in a vacuum state.

The electron gun is operated so that the electron beam emitted from the cathode oxide of the electron gun applied to the cathode ray tube as described above reaches the phosphor layer 2 coated on the inner surface of the panel 1 by the magnetic field generated by the deflection yoke 8. When the current flowing through the coil constituting the deflection yoke 8 is generated as the outer diameter of the neck portion 4a is smaller, the power consumption required to drive the electron gun is reduced. You get

Accordingly, in recent years, a lot of research and development has been conducted in the related art in order to form the outer diameter of the neck portion 4a smaller, but there are many restrictions as follows to form the outer diameter of the neck portion 4a small.

First, if the outer diameter of the neck portion 4a is reduced, the resolution of the electron gun accommodated inside the neck portion may be deteriorated. Therefore, a high-performance electron gun having an optimal design should be developed.

Second, when the outer diameter of the neck portion 4a is reduced, the shape and dimensions of the stem having the metallic pins for supplying power to the electron gun should be set appropriately.

If not, complete sealing is not performed at the connecting portion of the stem 6 and the neck portion 4a, or cracks are generated at the sealed portion even if the sealing is performed. Not only can it be maintained, but it also causes a breakdown voltage characteristic due to a problem with the compatibility with the base.

In the stem 6, as shown in FIG. 2A, a plurality of stem pins 9 are embedded to form a circle at a predetermined distance from the center of the stem 6, each of which maintains proper insulation. It is arranged at equal intervals to each other, in which the radius between the center of the stem pin (n) inside the neck and the radius (n ') between the center of the stem pin outside the neck consists of a straight pin shape.

The diameter (d) of the circle formed by the stem pins 9, that is, the pin circles are approximately 15.24 mm and 12.0 mm.

And in order to increase the strength retention and insulating properties of the metallic stem pins (9), a glass projection (6b) made of a material of the stem (6) around the stem pin (9) is formed integrally with the stem, As described above, when the thin neck portion 4a is applied, the stem 6 having a pin circle having a diameter of 15.24 mm has a larger outer diameter f than the inner diameter D 'of the neck portion 4a, and thus the glass protrusion 6b. Is likely to be fused to the neck portion 4a, which causes a crack and an unfavorable cause of breakdown voltage, and therefore cannot be applied.

In addition, in the stem (6) having a pin circle of 12.0 mm in diameter equipped with a high-performance electron gun, a separate stem pin for supplying a dynamic voltage in addition to the static voltage for driving the electron gun prevents discharge between stem pins. Additional stems must be installed to maintain the proper spacing (S) between the stem pins. The stem (6) with a pin circle of 12.0 mm in diameter has a separate stem pin for applying a dynamic voltage because the pin circle (d) is too small. There were many difficulties in securing the space for installation.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem in the related art, and an object thereof is to improve the structure of the stem on which the electron gun is mounted so that at least two focusing voltages can be applied to improve the focus performance of the electron gun. .

According to an aspect of the present invention for achieving the above object, a stem on which the electron gun is mounted in the neck portion in a cathode ray tube composed of a panel coated with a phosphor layer and a thin neck portion for receiving an electron gun, and a funnel fused with the panel. In this sealed, a collar cathode tube provided with a stem pin for applying a dynamic voltage between the plurality of stem pins is provided by bending the stem pin fixed to the stem so that the pin circle located inside the neck is expanded.

According to another aspect of the present invention, in a cathode ray tube composed of a panel coated with a phosphor layer and a thin neck portion accommodating an electron gun, and having a funnel fused to the panel, the stem mounted on the neck portion is sealed. In addition, a colored cathode ray tube is provided in which the stem pins are zigzagly positioned differently from the pin circles of the stem pins located inside the neck.

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

Figure 2a is a longitudinal cross-sectional view of the stem coupled to the neck portion

FIG. 2B is a bottom view of FIG. 2A

Figure 3a is a longitudinal cross-sectional view showing an embodiment of the present invention

FIG. 3B is a top view of the stem shown in FIG. 3A

Figure 4a is a longitudinal cross-sectional view showing another embodiment of the present invention

4B is a plan view of the stem shown in FIG. 4A

Explanation of symbols for main parts of the drawings

1: panel 3: shadow mask

4: funnel 4a: neck portion

6: stem 9,10: stem pin

Hereinafter, with reference to the accompanying Figures 3a to 4b showing an embodiment of the present invention in more detail as follows.

3A is a longitudinal sectional view showing one embodiment of the present invention and FIG. 3B is a plan view of the stem shown in FIG. 3A.

The present invention maintains the pin circle (D) so that the lower end (K) outside the neck of the metallic stem pin (9) embedded in the stem (6) draws a circle as in the prior art, while the upper end (J) inside the neck (J). The pin circle (D ') of the stem pin (9) located in the) is bent outwardly and the stem pin (9) fixed to the stem (6) so as to extend larger than the conventional pin circle (D) between the plurality of stem pins There is a separate stem pin 10 for applying a dynamic voltage (high voltage).

The stem pins 9 and 10 are arranged at specific equal intervals to maintain proper insulation.

In order to sufficiently maintain the strength and insulation distance of the plurality of metallic stem pins 9 and 10, a protrusion 6b of the same material as the stem material is integrally formed with the stem 6 around the stem pin 9. Is formed.

The pin circle D 'formed from the center of the stem 6 in the stem pin 9 located inside the neck should be designed to have a proper distance from the inner wall of the neck portion 4a, furthermore the stem 6 Should be determined to maintain an optimal relationship between the critical dimension of c) and the critical dimensions of the neck portion 4a.

When sealing is performed by combining the stem 6 mounted with an electron gun inside the neck portion 4a in a cathode ray tube having an outer diameter of the neck portion 4a having a narrow neck portion 4a of less than 23.0 to 28.5 mm. If the pin circle (D ') of the stem pin (9) located inside the neck is too extended, the protrusion part (6b) melts during sealing work, and sufficient insulation distance between the stem pins (9) cannot be secured, and thus the withstand voltage required by the cathode ray tube Care should be taken because defects that do not satisfy the characteristics are generated.

4A and 4B are longitudinal cross-sectional views and plan views showing another embodiment of the present invention, in which the lower end portion K of the outer side of the neck of the metallic stem pins 9 embedded in the stem 6 has a circle as in the prior art; While holding the pin circle (D) to draw, the stem pin (9) located in the upper end (J) inside the neck is zigzag differently in diameter (φ ₁ ) (φ ₂ ), which is the pin circle (D ') A separate stem pin 10 for applying a dynamic voltage (high voltage) is disposed between the plurality of stem pins.

The neighboring stem pin is bent inward, and the stem pin adjacent to the inwardly bent stem pin is repeated in the form of a straight line. And are arranged in a zigzag.

In another embodiment of the present invention described above, as shown in Figure 4b by arranging the spacing of the stem pins (9) 10 located inside the neck differently, it is possible to maximize the space utilization.

That is, the stem pins 9 to which low pressure is applied are arranged at narrow intervals, and the stem pins to which high pressure is applied are arranged at wide intervals so as to have sufficient intervals as in the prior art while maintaining the insulation distance between the stem pins 9 and 10. By securing enough, it is possible to additionally install a separate stem pin 10 to which a high voltage dynamic voltage is applied between the stem pins 9 as a whole.

This will be described with reference to the accompanying Figure 4b.

When the pin circle formed inside the neck is 12,0 mm and 10 stem pins 9 are installed in the neck portion 4a, the stem pins 9 embedded in the conventional stem 6 are each 3.768 mm apart. (S) is maintained.

However, in the present invention, a relatively high pressure is applied to the space secured by reducing the stem pin spacing (S) from the stem pin 9, which is the stem pin 9 to which the low pressure is applied, to the stem pin 9, to which the relatively low pressure is applied, to 3.3 mm. 11 stem pins can be installed as a whole by installing a spacing (S ') of the remaining stem pins to which high voltage is applied, including a separate stem pin 10 for applying a voltage, at 3.768 mm like a conventional stem pin spacing. It will be able to free space.

The present invention is applicable to a type in which a pin circle which is a diameter of a circle formed by a stem pin installed from the center of the stem in the stem pin fixed to the stem 6 is 12.0 mm.

As described above, since the present invention can maximize the space inside the neck, a high voltage dynamic voltage is applied to the stem 6 fixed to the narrow neck portion 4a to reduce power consumption. It is possible to install an additional stem pin.

Claims (6)

In a cathode ray tube composed of a panel coated with a phosphor layer and a thin neck portion accommodating an electron gun and a funnel fused to the panel, a stem mounted with an electron gun on the neck portion is sealed. A color cathode ray tube in which a stem pin fixed to the stem is bent outwardly so that the stem pin is positioned to apply a dynamic voltage between the plurality of stem pins. The method of claim 1, Color cathode ray tube with 12.0mm pin circle of stem pin located outside of stem. In the cathode ray tube composed of a panel coated with a phosphor layer and a thin neck portion accommodating an electron gun and a funnel fused to the panel, a stem mounted on the neck portion is sealed, and a stem pin located inside the neck. Color Cathode Tube with different pin circles in different stem pins. The method of claim 3, wherein Color cathode ray tube with different spacing of stem pins located inside the neck. The method of claim 4, wherein Low pressure stem pins are arranged in narrow intervals, high pressure stem pins are arranged in a wide interval color cathode ray tube. The method of claim 5, When the pin circle is 12,0mm, the interval between the stem pin is applied to the high pressure is set to 3.768mm, the spacing of the stem pin is applied to the low pressure is set to 3.3mm, the color cathode ray tube.

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