KR100551044B1 - A cathode ray tube - Google Patents

Abstract

A cathode ray tube utilized as a color television or a computer monitor, comprising: a panel having a screen formed on an inner surface thereof so as to be provided to a user as a product having reduced power consumption by reducing deflection power without a problem of the electron beam; A funnel connected to the panel and having a deflection yoke installed on an outer circumference thereof, the funnel comprising: a cylindrical neck having an electron gun inserted therein; A cone portion connected to the neck side; A body disposed between the cone portion and the panel and connected to the panel side, wherein the neck side end portion of the cone portion is a starting point (0), and a vertical distance from the tube axis of the cathode ray tube to the outer periphery of the cone portion is h; In this case, the average change rate R of h within 25% of the total length L of the cone portion set on the tube axis from the starting point 0 satisfies a condition of 0.26 <R <0.43.

Cathode ray tube, cone part, funnel, deflection efficiency, power consumption, BS

Description

Cathode Ray Tube {A CATHODE RAY TUBE}

1 is a side cross-sectional view showing a cathode ray tube according to an embodiment of the present invention,

2 is a schematic diagram showing important portions of a cathode ray tube according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cathode ray tube, and more particularly, to a cathode ray tube configured to reduce deflection power by improvement of a funnel portion in which a deflection yoke is mounted.

As is well known, a cathode ray tube deflects an electron beam emitted from an electron gun in a horizontal and vertical direction with respect to a screen, thereby causing the electron beam to strike a corresponding phosphor of the screen to implement a predetermined character or image with light emitted.

Such a cathode ray tube is mainly provided as a color television, a computer monitor, etc., and is provided to a consumer, and in recent years, it is produced also as an advanced product like high quality television (HDTV).

The cathode ray tube is applied to high-definition television or other office automation (OA) equipment, or the screen brightness is enhanced. For this purpose, the cathode voltage increases the deflection frequency of the deflection yoke or finally accelerates the electron beam. In this case, the deflection power is increased according to its action.

Conventionally, in order to solve such a problem, a technique has been attempted to increase the efficiency of the deflection yoke for the electron beam by reducing the neck diameter so that the deflection magnetic field generated in the deflection yoke is closer to the trajectory of the electron beam.

However, in this technology, due to the neck portion which is smaller than in the related art, not only the design of the electron gun but also the outer curvature of the funnel has to be designed differently, the cathode ray tube must be manufactured. Compared with the existing cathode ray tube, there is still not enough problem.

Accordingly, conventionally, the cathode ray tube has the neck diameter having a general size (for example, 29.1 φ) and instead reduces the deflection power by reducing the outer diameter of the neck portion of the funnel to the conventional size.

However, a problem remains in this technique, which results in a so-called Beam Shadow Neck (BSN) phenomenon in which an electron beam to reach the corner of the screen impinges on the inner wall of the neck portion of the funnel, resulting in good final image implementation. It will not be achieved.

That is, in the past, since the measurement technique for the trajectory of the electron beam has not been developed, the cathode ray tube was manufactured through user experience or numerous trials and errors. Therefore, it is not sufficient to effectively solve the problem of the BS of the electron beam. there was.

In other words, there is a limit to maximizing the efficiency of the BNS of the electron beam in order to reduce the deflection power with a technology that simply reduces the outer diameter of the funnel neck side.

Accordingly, the present invention has been made in view of the above-described problems, and an object of the present invention is to provide a cathode ray tube that is designed to effectively reduce deflection power while substantially preventing electron beams from causing BCs.

In order to realize the above object,

A panel having a screen formed on an inner surface thereof;

A funnel connected to the panel and installed with a deflection yoke on the outer circumference,

The funnel has a cylindrical neck in which an electron gun is inserted therein;

A cone portion connected to the neck side;

A body disposed between the cone portion and the panel and connected to the panel side;

When the neck-side end of the cone portion is a starting point (0), and the vertical distance from the tube axis Z of the cathode ray tube to the outer circumference of the cone portion is h, it is set on the tube axis from the starting point (0). An average rate of change (R) of h within 25% of the total length (L) of the cone part is provided to satisfy the following formula.

0.26 <R <0.43

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a side view showing a cathode ray tube according to an embodiment of the present invention, and as shown, the cathode ray tube is formed in a substantially rectangular shape, and a panel 3 having a phosphor screen 1 formed therein, and the panel It is formed of a vacuum tube including a funnel 5 having a funnel shape connected to (3) and provided with a deflection yoke (not shown) on the outer circumference.

In such a cathode ray tube, in order to make the deflection of the electron beam more efficient, the funnel 5 is as follows.

First of all, the funnel 5 includes a neck 50a formed in a cylindrical shape. As is known in the neck 50a, an electron gun 7 for generating an electron beam is inserted and installed in the neck 50a. A cone portion 50c having a neck seal surface 50b connected to the neck 50a is disposed in front of the panel 3, and the cone portion 50c is disposed between the cone portion 50c and the panel 3. A body 50d which is rapidly enlarged from the panel side end portion of 50c and connected to the panel 3 side is disposed.

In this funnel 5, the improved part according to the present invention is the above-mentioned cone part 50c portion, which is formed by further satisfying the following conditions. FIG. 2 is a reference figure for this, in which the portion indicated by 0 represents the neck-side end of the cone portion 50c, and L is the total length of the cone portion 50c set on the tube axis Z of the cathode ray tube. H represents the vertical distance from the said tube axis Z axis to the outer periphery of the cone part 50c.

In this state, the cone portion 50c uses the end portion as the starting point 0, and the average change rate R of h for the portion within 25% of the total length L from the starting point 0 satisfies the following value. Do it.

0.26 <R <0.43

In the present invention, the cone portion 50c is formed under the same conditions as described above. When the average change rate R is less than 0.26, a reduction in deflection efficiency cannot be expected, and the average change rate R is greater than 0.43. This is because it is known that the problem occurs in the BNS of the electron beam. In this example, its average rate of change (R) was 0.41.

Accordingly, when the funnel 5 is formed under the above conditions, the shape of the cone portion 50c in the funnel 5 is substantially smaller than that of the conventional portion (shown by a dotted line). Applicant's computer simulation of 50c) shows that even if the deflection yoke is mounted on the cone portion 50c, the deflection yoke sufficiently deflects the electron beam without causing the BCN phenomenon of the electron beam. .

Furthermore, when the deflection yoke is mounted on the cone portion 50c of the above type, the deflection magnetic field (especially the horizontal deflection magnetic field) generated in the deflection yoke approaches the trajectory of the electron beam, thereby reducing the deflection power. In this embodiment, it can be confirmed that its value is reduced by about 9.76% compared to the conventional.

For reference, when the 17-inch cathode ray tube (deflection angle 90 °) applied as an example of the present invention is provided with the above average change rate R in accordance with the following conditions, it is compared with the conventional cathode ray tube of the same model. The values are as follows:

R Deflection (horizontal) power The present invention 0.41 90.24% Conventional 0.18 100%

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. In addition, it is natural that it belongs to the scope of the present invention.

As described above, the cathode ray tube according to the present invention can effectively reduce the deflection power without having to worry about the problem of the BS of the electron beam due to the improved shape of the funnel portion.

Therefore, the cathode ray tube to which the technology of the present invention is applied can reduce power consumption as compared to the conventional cathode ray tube of the same type, and has an effect that can be provided to the consumer with good quality.

Claims (1)

A panel having a screen formed on an inner surface thereof; A funnel connected to the panel and installed with a deflection yoke on the outer circumference, The funnel has a cylindrical neck in which an electron gun is inserted therein; A cone portion connected to the neck side; A body disposed between the cone portion and the panel and connected to the panel side; When the neck-side end of the cone portion is the starting point (0), and the vertical distance from the tube axis of the cathode ray tube to the outer circumference of the cone portion is h, the entire cone portion is set on the tube axis from the starting point (0). A cathode ray tube, wherein the average rate of change (R) of h within 25% of length (L) satisfies the following formula. 0.26 <R <0.43

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