KR20010109800A - Beam index type CRT - Google Patents

Abstract

The present invention relates to a beam index type cathode ray tube that can improve the contrast ratio of a screen by increasing the light collecting efficiency of index light.

A fluorescent film screen formed on the inner surface of the panel and having an index stripe, a funnel portion coupled to the rear of the panel to form a transparent light receiving window, an electron gun emitting an electron beam toward the fluorescent film screen, and attached to the outer surface of the light receiving window An optical detector for detecting the index light emitted from the index stripe, an indexing circuit unit which converts the index light detected by the photo detector into an index signal and transmits an accurate color signal to the electron gun in synchronization with the color signal, and is provided on the inner surface of the light receiving window. Provided is a beam index type cathode ray tube including a lens unit for refracting index light incident to the surroundings and focusing the light detector.

Description

Beam index type cathode ray tube {Beam index type CRT}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a beam index type cathode ray tube, and more particularly, to a beam index type cathode ray tube capable of improving the light-concentration ratio of index light to improve the contrast ratio of a screen.

In general, the beam index type cathode ray tube generates an electron beam from an electron gun, focuses and accelerates it, and scans it on a fluorescent film screen to emit an image, and the basic principle is the same as that of a general cathode ray tube, but a beam index type cathode ray tube is a shadow. An index stripe is formed instead of a mask to perform color selection.

Fig. 5 is a cross-sectional view of a beam index type cathode ray tube according to the prior art, and Fig. 6 is a schematic diagram showing a current value of a fluorescent film screen and an electron beam reaching each position, and showing an electron beam toward the fluorescent film screen 17 in the electron gun 1. When (3) is emitted, the electron beam 3 excites the index stripe 5 to generate a light pulse (index light) in the ultraviolet region, which is detected by the photodetector 9 through the light collecting plate 7. Switch to the index signal. The index signal emits an accurate color signal in synchronization with the color signal in the indexing circuit unit 11 to implement a desired color.

As described above, the beam index type cathode ray tube continuously carries an electron beam B '(black level electron beam) for exciting the index stripe 5 in addition to the electron beam A for emitting the fluorescent film stripe 13 to emit an accurate color signal. Since the black level electron beam B 'has a current value of about 5-20% of the electron beam corresponding to the color signal, the black level electron beam B' is continuously emitted even in a scene (eg, a night scene) that does not need to emit a color signal due to the screen configuration. The fluorescent film stripe 13 emits light, and as a result, the contrast ratio of the screen is lowered.

Therefore, in order to prevent the emission of the fluorescent film stripe 13 by the black level electron beam B 'and increase the contrast ratio, the current value of the black level electron beam B' should be lowered by increasing the light condensing efficiency of the index light. However, as shown in FIG. 7, a portion of the index light is reflected at the inner surface of the light receiving window 19 to form a light loss. As a result of the measurement, about 30% of the index light is not transmitted to the light collecting plate 7 by the reflection in the light receiving window 19 and is lost, thereby reducing the light collecting efficiency.

In addition, the barium film generated during the getter flashing process, which is performed to improve the vacuum degree of the tube, may cover the light receiving window. In this case, the index light is reflected by the barium film to further reduce the light collecting efficiency. It is possible to change the shape of the getter shield so that the barium film does not face the light receiving window.However, if the barium film is not diffused sufficiently, the vacuum tube of the tube can be lowered to shorten the life of the cathode ray tube. Following.

Therefore, the present invention was devised to solve the above problems, and an object of the present invention is to concentrate the index light on the light collecting plate to improve the condensing efficiency of the index light, thereby reducing the current value of the black level electron beam, thereby improving the contrast ratio of the screen. A beam index type cathode ray tube is provided.

Another object of the present invention is to provide a beam index type cathode ray tube which can improve the condensing efficiency by suppressing the reflection of the index light by the barium film even when the barium scattered during the getter flashing process is directed toward the light receiving window.

1 is a cross-sectional view of a beam index type cathode ray tube according to the present invention.

2 is a schematic diagram showing current values of a fluorescent film screen and an electron beam;

3 is an enlarged cross-sectional view around the photodetector.

4 is a cross-sectional view of a beam index type cathode ray tube in the getter flashing process;

5 is a cross-sectional view of a beam index type cathode ray tube according to the prior art.

6 is a schematic diagram showing current values of a fluorescent film screen and an electron beam;

7 is an enlarged cross-sectional view around the light collecting plate.

In order to achieve the above object, the present invention,

A fluorescent film screen formed on an inner surface of the panel and having an index stripe;

A funnel portion coupled to the rear of the panel and forming a transparent light receiving window;

An electron gun that emits an electron beam toward the fluorescent screen;

A photo detector attached to an outer surface of the light receiving window to detect index light emitted from the index stripe;

An indexing circuit unit which converts the index light detected by the photo detector into an index signal and transmits an accurate color signal to the electron gun in synchronization with the color signal;

A beam index type cathode ray tube is provided on the inner surface of the light receiving window and includes means for refracting and concentrating the index light incident around the light receiving window.

The means here comprises a lens portion that is convex toward the inside of the funnel portion. As a result, the index light incident around the light receiving window is refracted by the lens unit and concentrated at the photo detector, thereby improving light condensing efficiency. Since the barium film is not formed in front of the lens part where the index light is mainly incident, the barium film has an advantage of minimizing reflection of the index light by the barium film.

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

Fig. 1 is a sectional view of a beam index type cathode ray tube according to the present embodiment, and Fig. 2 is a schematic diagram showing a current value of a fluorescent film screen and an electron beam reaching each position.

As shown, the beam index type cathode ray tube includes a panel 4 having a fluorescent film screen 2 formed therein, a funnel portion 6 and a neck portion 8 coupled to the rear of the panel 4, and a fluorescent film. Electron gun 12 for emitting electron beam 10 toward screen 2, deflection yoke 14 mounted on the outer circumferential surface of funnel portion 6, light detector 16 for detecting index light, electron gun And an indexing circuit section 18 electrically connected to the photo detector 16, and means for improving the light condensing efficiency of the index light.

The fluorescent film screen 2 includes R, G and B fluorescent film stripes 22 sequentially formed between the black matrix film 20, an aluminum reflecting film 24 for improving the brightness of the fluorescent film screen, and an aluminum reflecting film. It is formed on the index 24 at a predetermined interval and consists of an index stripe 26 that receives an electron beam and emits index light in the ultraviolet region.

The photo detector 16 detects the index light and transmits it to the indexing circuit section 18. As shown in FIG. 3, the photo detector 16 has an outer surface of the transparent light receiving window 6a of the funnel section 6. The light collecting plate 28 attached to the light collecting plate 28, the photosensitive diode 30 attached to one surface of the light collecting plate 28, and the total reflection mirror 32 attached to the opposite surface of the light collecting plate 28 are included.

The light collecting plate 28 converts the index light of the ultraviolet region (400 nm) into an optical signal having a good response sensitivity of the photosensitive diode 30 (600 to 900 nm) and transmits it to the photosensitive diode 30. To this end, the light collecting plate 28 is made of an injection molded product, which is made of, for example, polymethyl methacrylate (PMMA), a kind of thermoplastic resin having a high refractive index, and mixed with fluorescent dyes such as Hostasol Yellow8G and Hostasol Yellow3G.

This converts the index light in the ultraviolet region into an optical signal in the long wavelength region by the fluorescent dye uniformly dispersed in the light collecting plate 28, and the light collecting plate 28 is made of a material having a high refractive index and a low transmittance, so that the light receiving window 6a The light incident through the incident face facing the light is emitted toward the photosensitive diode 30 perpendicular to the incident face.

The photosensitive diode 30 converts the long-wavelength optical signal provided from the light collecting plate 28 into an electric signal (index signal) and transmits it to the indexing circuit unit 18. The total reflection mirror 32 is the light collecting plate 28. To minimize light loss.

As a result, the indexing circuit unit 18, which receives the index signal from the photo detector 16 having the above-described configuration, transmits the correct color signal to the electron gun 12 by synchronizing the index signal with the color signal, thereby performing accurate color realization. ) Should continuously scan the black level electron beam B for emitting the index light along with the electron beam A corresponding to the color signal.

At this time, the condensing efficiency of the photodetector 16 which detects the index light and the current value of the black level electron beam B to be observed by the electron gun 12 are in inverse proportion. That is, the higher the light converging efficiency of the index light, the lower the current value of the black level electron beam B, and the light emission of the fluorescent film stripe 22 by the black level electron beam B can be suppressed to improve the contrast ratio of the screen.

To this end, the present embodiment forms a convex lens portion 34 toward the inside of the funnel portion 6 on the inner surface of the light receiving window 6a facing the photo detector 16. For example, the lens unit 34 may be manufactured integrally with the funnel unit 6 using a glass mold when the funnel unit 6 is manufactured, and is formed to a diameter sufficient to cover the light receiving window 6a. It is preferable.

The lens unit 34 refracts most of the index light incident around the light receiving window 6a and enters the light collecting plate 28 through the light receiving window 6a, thereby improving the light collecting efficiency of the index light. As shown in FIG. 2, the minimum current value required for light emission, that is, the current value of the black level electron beam B, can be reduced than the current value of the black level electron beam B 'required in the existing cathode ray tube.

As described above, since the current value of the black level electron beam B can be reduced by improving the light condensing efficiency of the index light by the lens unit 34, light emission of the fluorescent film stripe 22 caused by the black level electron beam B is suppressed, and as a result, The contrast ratio of the screen can be improved.

As a result of the measurement, the contrast ratio in the conventional beam index type cathode ray tube is about 30 to 1, while the contrast ratio in the beam index type cathode ray tube according to the present embodiment is about 40 to 1 to 50 to 1, which is an improved contrast ratio. It is possible to implement more improved image quality.

In addition, the present embodiment can minimize the reflection of the index light by the barium film generated during the getter flashing process. That is, since the lens part 34 serves as a cover of the light receiving window 6a, the barium may be received from the getter support 36 positioned on the inner circumferential surface of the neck part 8 during the getter flashing process as shown in FIG. 4. Although scattered toward 6a, the barium film 38 is formed only on the rear surface facing the neck portion 8 by the convex lens portion 34 covering the light receiving window 6a, and the index light is mainly incident on the front surface. The barium film 38 is not formed in the portion.

Therefore, the lens unit 34 prevents the barium film 38 from being deposited on the front surface where the index light is mainly incident, thereby effectively preventing the light collection efficiency of the index light from the barium film 38, and the complex shape of the getter shield. The advantage is that the getter flashing process can be performed without modification.

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

As described above, the beam index type cathode ray tube according to the present invention forms a convex lens portion on the inner surface of the light receiving window so that most of the index light incident around the light receiving window is refracted and concentrated on the light detector. As a result, the light condensing efficiency of the index light can be improved to lower the current value of the black level electron beam, thereby improving the contrast ratio of the screen. In addition, since the lens part serves as a cover of the light receiving window, the barium film generated during the getter flashing process is deposited only on the rear part facing the neck part, thereby effectively preventing the reflection of the index light by the barium film.

Claims (5)

A fluorescent film screen formed on an inner surface of the panel and having an index stripe; A funnel portion coupled to the rear of the panel to form a transparent light receiving window; An electron gun that emits an electron beam toward the fluorescent screen; A photo detector attached to an outer surface of the light receiving window to detect index light emitted from the index stripe; An indexing circuit unit which converts the index light detected by the photo detector into an index signal and transmits an accurate color signal to the electron gun in synchronization with the color signal; And a means provided on the inner surface of the light receiving window and refracting the index light incident around the light receiving window to concentrate the light detector. The method of claim 1, A beam index type cathode ray tube, wherein the means comprises a lens portion that is convex toward the inside of the funnel portion. The method of claim 2, Beam index type cathode ray tube of the lens portion is made of a transparent glass material. The method of claim 1, A beam index type cathode ray tube comprising a light collecting plate on which the photo detector is located on an outer surface of a light receiving window, and a photosensitive diode attached to one side of the light collecting plate. The method of claim 4, wherein And a beam index type cathode ray tube provided with a total reflection mirror on the light collecting plate.