DE2826134A1 - COLOR TUBE - Google Patents

Description

N.V. Philips' Gloeilampenfabrieken, Eindhoven / Holland

Color picture tube

The invention relates to a color picture tube containing means for generating in an evacuated envelope at least one electron beam and a screen with a plurality of different colors flashing Phosphors covered by a light-absorbing coating are surrounded and covered with a metal film.

The phosphors usually form a multitude of trios of fluorescent dots or strips, with the areas each trio represent the three basic colors red, green and blue. Between the stripes or dots is the light absorbing one Coating, which is also referred to as a matrix, and which, for example, consists of black-colored manganese oxide and / or iron oxide, which increases the contrast of the image

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gets bigger. In front of the screen is a color selection electrode with a very large number of round or slit-shaped ones Arranged openings, whereby each electron beam hits only the phosphor areas of the color assigned to it. The light-absorbing coating possibly absorbs the electrons which do not fall on the phosphor areas and therefore serves as a landing area for these electrons. About the phosphors and the light-absorbing coating is mostly a thin metal film, e.g. an aluminum film, arranged, which serves as an electrode and also contributes to the brightness of the image through its light reflection.

Such a color picture tube is known from US Pat. No. 3,890,527, according to which a thin aluminum film that is on the phosphors rests, is arranged over the entire screen.

It was found by measurement that the light reflection of an aluminum film attached in this way was not optimal and was also not equally strong across the entire screen.

The object of the invention was therefore to provide a color picture tube in which the light reflection of the metal film is considerably better and more uniform than with the picture tubes of this type produced up to now.

This object is achieved in a color picture tube of the type mentioned according to the invention in that the thickness of the light-absorbing coating is at least 3 / µm larger than the thickness of the phosphors and the metal film adheres to the light absorbing coating. "Thickness" is always to understand the mean thickness. The consequence of this thicker light-absorbing coating is that the metal film on the light-absorbing Coating and does not adhere to the lighting elements.

As is well known, a lacquer solution, e.g. a collodion solution, is applied over the luminous element before the metal film is applied.

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fabrics and the matrix cover attached. After a drying process a uniform paint film is obtained. Particles of the phosphors penetrate into the picture tubes known up to now more or less through this lacquer film. After evaporation of the metal film and after removal of the paint film by heating, the metal film adheres to the phosphors. By having the phosphors at least partially penetrate through the metal film and interrupt it and make it irregular, assume at the places where the adhesion of the metal film to the phosphors takes place, the light reflection from. This effect does not occur to the same extent everywhere over the screen, so that the image brightness is not even over the whole screen is.

Since the metal film is mainly adhered to the light-absorbing coating when the invention is applied, these occur Reflection-impairing effects are not affected and the overall brightness and the uniformity of the brightness are improved enlarged.

According to the invention, the light-absorbing coating is preferably composed of a material which contains grains, at least 50 % by weight of these grains having a diameter which is greater than 15 μm. In the claims and in the description, the diameter of a grain is always to be understood as the mean diameter, which means that the diameter of any grain is equal to the diameter of a spherical grain made of the same material with the same weight.

In the tubes of this type produced so far, grains with a diameter of about 1 / µm have always been used. By Application of the coarse grains according to the present invention has been found to be easier to absorb light Coating in a thickness that is at least 3 / µm greater than with

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application of the usual grains with a diameter of about 1 / to attach.

Another advantage of using less small grains is that they are less roughly in the phosphors existing cracks and pits will penetrate. The penetration of the light-absorbing material into cracks and Pits in the phosphors cause annoying black lines and dots in the reproduced image.

The screens are made by known photographic or electrophotographic techniques. It is possible, first to apply the light-absorbing coating, e.g. in the form of a striped pattern, after which the Phosphors can be attached. It is also possible to first use the phosphors and only then the light-absorbing ones to apply coating.

The invention will now be explained in more detail, for example with reference to the drawing. Show it

1 shows, in perspective and partially broken away, a color picture tube according to the invention,

Fig. 2 is a view of part of the screen and the color selection electrode;

Fig. 3 is a schematic section through part of a screen according to the invention and

Fig. 4 is a schematic section through part of a previously used screen.

In Fig. 1, a color picture tube according to the invention is shown in perspective. In a glass envelope 1, which consists of a front glass 2, a conical part 3 and a Neck 4, there are three electron guns 5, 6 and 7 for generating three electron beams 8, and 10. These electron beams pass through the openings in the color selection electrode 12 and are incident on a

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Variety of trios of fluorescent strips 14, 15 and 16, which together form the screen. The red (R) fluorescent strip 14, the green (G) fluorescent strip 15 and the blue (B) fluorescent strip 16 are in this Trap separated from each other by a black light-absorbing coating of manganese oxide and iron oxide. Practice: * An aluminum film 13 is applied to this coating and the fluorescent strips in the usual way by vapor deposition. Of the Aluminum film 13 according to the invention adheres mainly to the light-absorbing coating 17, which, as already is described, contributes to a high brightness and uniformity of the television image generated, as based on the the following figures will be explained in more detail. The three electron beams 8, 9 and 10 close a small one Angle, the so-called color selection angle, with each other and thus only ever fall on one fluorescent strip certain color. Thus, the electron beam 10 always falls only on phosphor areas 14. The deflection of the Electron beams are carried out in the usual way with the help of deflection coils (not shown here).

Fig. 2 shows part of the front glass 2 with a screen and part of the mask 12. Part of the 0.3 / µm thick aluminum film 13 is omitted, whereby the Fluorescent strips 14, 15 and 16 with an intermediate light-absorbing coating 17 made of manganese oxide and iron oxide are visible. The fluorescent strips are in this one Fall about 10 µm thick and 200 µm wide. In this case, the light-absorbing coating 17 is approximately 15 μm thick and 70 / µm wide and is composed of grains. The coarse grains provide a coating that is thick enough is. The smaller grains ensure that the spaces between the coarse grains are well filled. The fluorescent strips and the sheets of light absorbing coating may have other widths or one across the screen having changing width.

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Fig. 3 shows a schematic section through part of a screen as it is in a color picture tube of the invention is used. The 0.3 / µm thick aluminum film here mainly adheres to the light absorbing one Coating 17 and not or almost not on the fluorescent strips 14, 15 and 16. The light-absorbing coating in this case consists mainly of manganese-iron oxide grains, 50% by weight of the grains having a diameter of more than 15 µm.

In Fig. 4 is a schematic section through part of a previously used screen is shown. For the sake of clarity, the same reference numerals are used in FIG. 4 for corresponding parts as in FIG. 3. In the screens used up to now, the matrix coating was almost as thick as or less thick than the fluorescent strips, as known, for example, from US Pat. No. 3,890,527 already mentioned. The aluminum film 13 thereby adheres mainly to the phosphor areas. This adhesion has the consequence that unevennesses 18 in the phosphor areas penetrate through the aluminum film 13. This causes some of the light generated in the phosphor areas to be lost because it is not reflected by the aluminum film. This liability is not the same all over the screen so that an image is generated, the brightness is not the same everywhere.

By applying the invention, by increasing the thickness of the matrix coating, the metal film is mainly attached This light-absorbing coating adheres (Fig. 3), these adverse effects are avoided.

PHN 8833

80985Ϊ / 1003

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Claims (2)

N.V. Philips'Gloeilainpenfabrieken, Einöhoven / Holland PATENT CLAIMS: Color picture tube containing, in an evacuated enclosure, means for generating at least one electron beam and a screen with a plurality of fluorescent substances which light up in different colors and which are provided by a light-absorbing Coating surrounded and covered with a metal film, characterized in that the thickness of the light-absorbing Coating is at least 3 / µm greater than the thickness of the phosphors and the metal film on the light-absorbing Cover adheres. 2. color picture tube according to claim 1, characterized in that that the material from which the light-absorbing coating is composed contains grains, at least 50% by weight this grain has a diameter which is greater than 15 μm. PHN 8833
Zr / gü / br ORIGINAL INSPECTED 809851/1003