NL8900918A - Colour CRT shadow mask with reduced doming - has getter material with rough surface to increase heat radiation - Google Patents

Abstract

In a colour display tube wherein gettering is employed to improve the vacuum in the tube and the gettering material (21) is provided as a layer on the surface of the colour selection structure i.e. a shadow mask (11), the gettering material receiving surface (20) is made rough. The roughness of the surface is produced by etching or scouring it, or providing a layer of glass or alumina granules over it, onto which granules the getter material is deposited. The granule size is between 0.05 micrometres and 0.5 micrometres.

Description

N.V. Philips' Incandescent lamp factories in Eindhoven.

Color picture tube and image display device containing such a color picture tube.

The invention relates to a color picture tube containing an electron gun, a getter, a screen and for the screen a color selection structure with a surface remote from the screen.

A color display tube of the type described in the first paragraph contains an electron gun and a color selection structure. In operation, electrons emitted on the color selection structure by the electron gun heat up the color selection structure. Heating of the color selection structure results in distortions of the color selection structure, so-called "doming", with detrimental effects on image quality. The side of the color selection structure facing away from the screen may be so processed that it has favorable properties for doming. Furthermore, the color display tube contains a getter. The getter material is evaporated from the getter in a gettering process and deposits on surfaces of the color display tube. The layer of getter material thus formed improves the vacuum in the color display tube. It has been found that the layer of getter material influences doming. An increase in doming through the layer of getter material can be prevented by taking measures whereby no getter material precipitates on the color selection structure, for example an evaporation of the getter material away from the color selection structure. However, this imposes restrictions on the location and / or shape of the getter. Also, a portion of the surface within the color display tube is then not covered by getter material, which adversely affects the vacuum within the tube.

It is an object of the invention to provide a color display tube of the type mentioned in the first paragraph which meets the above stated drawbacks.

For this purpose, the color display tube according to the invention is characterized in that said surface is rough and a layer of getter material is applied to said surface.

A rough surface is here understood to mean a surface with a surface roughness, i.e. a difference between "peaks" and "dips" on the surface of the order of 0.5 to 20 µm.

It has been found that a layer of getter material applied to a smooth surface has a low infrared emission coefficient, so that the color selection structure can radiate little heat, resulting in a relatively large doming. If the layer of getter material is applied to a rough surface, the emission coefficient is higher.

The said surface can be roughened by etching or sanding.

An embodiment of the color display tube according to the invention in which the said surface is formed by a glass layer is characterized in that the glass layer contains particles of a different material.

The surface of the glass layer is then roughly made rough.

It is noted that a color display tube provided with a glass layer on which a layer of getter material is applied is known per se from European patent application 133411. Herein, the color selection structure on the side facing away from the screen is provided with a glass layer consisting of a lead borate glass. The lead borate glass layer reduces doming. A layer of getter material has been applied over the glass layer. The layer of getter material prevents an electric charging of the glass layer from occurring. An influence of the layer of getter material on the doming has not been reported. However, without special measures, a glass layer is smooth. It has been found that a layer of getter material on a smooth glass layer has a low infrared emission coefficient.

The particles in the glass layer can consist of materials with a melting point higher than the melting point of the glass layer, for example BZ2O3, AI2O3, or WC, or of particles with a melting point lower than the melting point of the layer, for example metal particles, such as tin or bismuth particles .

Preferably, materials are used in which the glass layer adheres to the color selection structure at a temperature of about 450 ° C. This temperature is approximately equal to the firing temperature of the color selection electrode. Foreign particles with a melting point lower than the melting point of the glass layer meet this condition, as do AI2O3 particles.

An embodiment of the color display tube according to the invention is characterized in that the glass layer is formed from a type of glass which, upon application, forms a rough glass layer.

An example is Philips 182 glass, which adheres to the color selection structure at a temperature of 490 ° C, but remains granular, forming a rough glass layer.

In an embodiment of the color display tube according to the invention, the layer of getter material is applied to a granular layer, for example to a layer containing Al2O3 granules or B12O3 granules.

Preferably, the layer of getter material contains an element with an atomic number higher than 50. The electron reflection coefficient is then relatively high.

The invention also relates to an image display device containing a color display tube according to the invention.

Some embodiments of the color display tube according to the invention are now further described by way of example with reference to a drawing.

Herein shows

Figure 1 is a partial perspective view of an image display device containing a color display tube according to the invention;

Figure 2 shows a detail of a cross section color picture tube, illustrating the effect of a local heating of the color selection structure;

Figure 3 is a cross-section of a known color selection structure;

Figure 4 is a sectional view of a color selection structure suitable for a color display tube according to the invention.

Figures 5 and 6 in cross section further examples of color selection structures suitable for a color display tube according to the invention.

The figures are schematic and not drawn to scale, with corresponding parts generally being designated with the same reference numerals in the various embodiments.

Figure 1 shows a cross-section of an image display device containing a color display tube according to the invention. In a glass envelope 1, which is composed of a display window 2, a cone 3, and a neck 4, an in-line electron gun 5 is arranged in the neck 4, which generates three electron beams 6, 7 and 8 which, with their axes in the are located flat in the drawing. The axis of the central electron beam 7 coincides in the unbent state with the tube axis 9. The display window is provided on the inside of a screen 10 containing a large number of trios of phosphor elements. The elements can, for example, consist of lines or dots. In the present case, the elements consist of trios of lines. Each trio contains a line containing a green-glowing phosphor, a line containing a blue-glowing phosphor, and a line containing a red-glowing phosphorus. The phosphor lines are perpendicular to the plane of the drawing. A color selection structure 11 is positioned in front of the screen, in which a large number of elongated openings 12 are provided, through which the electron beams 6, 7 and 8 pass. The three planar electron beams are deflected by a deflection coil system 13. The color display tube further includes a getter 14. In operation, getter material is evaporated from the getter.

Figure 2 shows in cross-section a detail of a color display tube. This figure illustrates, as an example of a doming phenomenon, the effect of a local warm-up of the color selection structure 11, which effect is referred to as "local doming". In the "cold" state, electron beam 7 hits the display 10 on the inside of the display window 2 at position 15. A local heating of the color selection structure 11, which can occur, for example, if the displayed image shows large differences in intensity, i.e. dark and light surfaces, results in a local bulge of the color selection structure 11, shown in Figure 2 by the hump 11a. The opening in the color selection structure 11 through which the electron beam 7 passes moves so that the electron beam 7 hits the screen 10 at position 16. A local heating of the color selection structure therefore results in a displacement of the spot of the electron beam on the screen, the effect of which is further referred to herein as "local doming". In addition to "local doming", for example, "color doming" also occurs in a color display tube. Even if the color selection structure 11 is irradiated almost everywhere with the same electron current density, temperature differences still arise between the center of the color selection structure and the edges of the color selection structure; the edges are generally colder than the center. As a result, the color selection structure as a whole bulges, which results in a displacement of the target.

Figure 3 shows a color selection electrode in cross section. The color selection structure 11 is provided on the side 17 facing the electron gun 5 with a glass layer 18 on which a layer of getter material 19. The layer of getter material in this example consists of a Barium layer.

The layer of getter material 19 has been found to affect "local doming" for such a color display tube.

Table 1 shows, for different lead borate glass layer thicknesses, for a 26 inch 30AX tube the "local doming" (in ym) for two points on the screen, a point on the long axis of the color picture tube at a distance from the center of the screen half the distance between the center and the edge of the display measured along the long axis (1/2 OW) and a point on the long axis at a distance from the center of the display equal to 2/3 ^ e of the distance between the center and the edge of the screen measured along the long axis (2/3 EW). The shadow mask is made of iron.

It is clear that the local doming before applying the Barium getter layer is smaller than after applying the Barium getter layer. The heat supplied by the electrons is dissipated either by radiation, the infrared radiation of a wavelength between 3 µm and 80 µm being particularly important, or by heat conduction through the color selection structure. In these tests, the Barium getter layer had a very low infrared emission coefficient (<0.1), so that only little heat can be radiated.

Figure 4 shows a color selection structure suitable for a color display tube according to the invention. The surface 20 is rough. A layer of getter material 21 is applied to the surface 20. Raw here is understood to mean rough relative to the wavelength of the radiated heat. The heat is radiated by means of infrared radiation with a wavelength in the range from 3 to 80 µm. The surface 14 has a surface roughness of the order of 0.5 to 20 µm. The layer of getter material is preferably thinner than 2 µm. A thicker layer of getter material results in a flattening of the layer of getter material. The thermal emission coefficient therefore decreases.

If the color selection structure is provided with a glass layer, the glass layer preferably contains foreign particles. These particles result in a roughening of the surface of the glass layer. A color selection structure with a glass layer 22 containing foreign particles 23 on which a layer of getter material 24 is applied is shown in figure 5.

Table 2 shows for a number of selection electrodes made of invar (an iron-nickel compound with a very low thermal expansion coefficient) and provided with a lead borate glass layer mixed with foreign particles, the measured infrared (= thermal) emission coefficients, after applying a Barium getter layer.

It is clear that the thermal emission coefficients are greater than the thermal emission coefficient of a smooth Barium getter layer.

Preferably, good adhesion between the lead borate-containing layer and the rest of the color selection structure is obtained at a temperature approximately equal to or less than the temperature at which the display and cone are attached to each other. Good adhesion is obtained if the foreign particles are wetted by the glass. This is (depending on the type of glass the picture tube is made of) about 450 ° C. A separate high temperature treatment of the color selection structure is then not necessary. It was found that for layers containing B12O3 and WC, good adhesion took place at a temperature of about 600 ° C (in air). In this regard, a containing layer is preferable since it gives good adhesion at lower temperatures.

The layers with a material having a melting temperature lower than the melting temperature of the lead borate glass all had good adhesion to the color selection structure at about 450 ° C.

It is also possible to provide the color selection structure with a glass layer of a glass type, which adheres like granules to the color selection structure at the bonding temperature.

An example of such a type of glass is Philips 182 glass which adheres to a color selection structure as granules at a temperature of 490 ° C. The core of the invention is also satisfied in such an exemplary embodiment of the invention, that is to say that the surface on which the layer of getter material is to be applied is so rough that after applying the layer of getter material a relatively high thermal emission coefficient (> 0, 7) occurs.

In one embodiment, the surface on which the layer of getter material is applied is a granular layer.

Figure 6 shows a selection electrode provided with a rough layer 25 containing particles deposited on the color selection structure. The Barium getter layer 26 is sprayed thereon. As can be seen from the drawing, this barium getter layer is not flat. Table 3 compares local doming results for several 51 FS (Flat Square) color picture tubes. The amounts of 13 ^ 203 and Al2O3 are given in Table 3 in gr / color selection structure. For B12O3, 1 g / color selection structure for a 51 FS screen roughly corresponds to an average layer thickness of 1.1 µm. For AI2O3, 1 gr / color selection structure approximately corresponds to an average layer thickness of 2.6 µm. The average layer thicknesses are therefore on the order of 0.2 to 1 µm. The point 2/3 0D, for which the local doming is indicated in table 3, is a point on the diagonal located at a distance from the center of the screen equal to 2/3 of the distance between the center of the screen and the angle from the display.

For an invar color selection structure without a rough layer (see table 3B), applying a barium getter layer has an improving effect on local doming. Invar has a low thermal emission coefficient (about 0.25) and a low electron reflection coefficient (about 0.22). A smooth barium getter layer has an approximately equally high emission coefficient and a higher electron reflection coefficient, so that local doming decreases.

Table 4 compares the local doming for a 26 inch 30AX tube with an iron color selection structure for a color selection structure with a smooth lead borate layer, an uncovered color selection structure, a color selection structure provided with a granular layer of B12O3 with the B12O3 particles spread as evenly as possible over the surface of the color selection structure. and a color selection electrode wherein the B12O3 particles are agglomerated on the surface of the color selection structure in agglomorates. 1.0 g lead borate glass and 0.8 g B12O3 were applied per color selection structure. As the surface on which the barium getter layer is applied is rougher, as shown in this table, doming decreases.

The particles can also consist of other materials (for example a metal carbide or nitride). AI2O3 is a suitable material because it is cheap and available in many particle sizes. Preferably compounds of a metal with a low atomic number are used since apart from the fact that elements with a high atomic number are generally rarer and thus more expensive than elements with a low atomic number, the use of heavy metals can be an environmental burden to shape.

It will be clear that many variations are possible for the skilled person within the scope of the invention. The shape of the color picture tube should be seen as limiting, for example the color picture tube may be a flat picture tube, nor should the type of electron gun be considered as limiting, for example the electron gun may be a so-called delta electron gun or the tube may contain more than one electron gun. An electron gun is here understood to mean a system for generating one or more electron beams. In the examples given above, a Baruim getter layer is shown. This should not be considered limiting. The getter layer. can be formed from another material, for example Cesium or Titanium.

Claims (9)

A color display tube comprising an electron gun, a getter, a screen and a color selection structure for the screen with a surface facing away from the screen, characterized in that said surface is rough and a layer of getter material is applied to said surface. Color display tube according to claim 1, wherein said surface is formed by a glass layer, characterized in that the glass layer contains particles of another material. Color display tube according to claim 2, characterized in that said particles consist of a material with a melting point lower than the melting point of the glass layer. Color display tube according to claim 2, characterized in that the particles consist of Al 2 O 3. Color display tube fully cut claim 1, wherein said surface is formed by a glass layer, characterized in that the glass layer is formed from a glass type which forms a rough glass layer upon application. Color display tube according to claim 5, characterized in that the glass type is Philips 182 glass. Color display tube according to claim 1, characterized in that the layer of getter material is applied to a granular layer. Color display tube according to claim 7, characterized in that the granular layer AI2O3 contains particles. Image display device comprising a color display tube according to any one of the preceding claims.