DE2225500A1 - Shadow mask color picture tube - Google Patents

Description

7383-72 / Sch / Ba
RGA 65003

US Ser.No. 147.776
AT: May 28, 1971

RGA Corporation, New York, N.Y. (V.St.A.)

Shadow mask color picture tube

The invention relates to a color picture tube with a mosaic. fluorescent screen made from a number of different sets of fluorescent elements, which each emit different colored light when bombarded with electrons, furthermore with one at a distance from Luminous screen arranged perforated mask and with an electron beam system, that for each set of fluorescent elements one through the shadow mask only on the fluorescent elements of the relevant one Set of incident electron beam generated.

The fluorescent elements are such in the fluorescent screen Color picture tube provided in the form of points or lines, which are usually on the faceplate, usually the tube front panel, in groups of three from three circularly arranged points of different colored light emitting phosphors are applied by a photographic direct printing process, a photosensitive coating on the Applied to the front pane and exposed through the circular openings of the shadow mask by means of a point light source, the coating is developed by washing away the uncured parts so that the desired pattern of exposed cured Points remaining. This process is repeated for each color, i.e. red, green and blue. The shadow mask will preferably removably attached to the flange of the windshield, so that it can be removed at any time and back in can put on exactly the same position. The fluorescent powder can

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for example directly with any photosensitive coating be mixed before it is applied to the windshield or applied to the coating after it has been exposed.

When the tube is in operation, the electron beams are subjected to influences such as deflection in horizontal and vertical directions and dynamic convergence to maintain beam convergence on the screen at different deflection angles subject to which the electron beam paths and thus the points of impact affect the rays on the screen in a manner similar to those used to print the screen Rays of light has not been the pail. If you have no compensation provides for the differences between the paths of the electron beams and the light beams, then result considerable misregistration between the jet impingement points and the phosphor points so that their centers are not coincide. The different types of misregistration that can occur and therefore need to be compensated for are in columns 1 and 2 of U.S. Patent 3,476,025 dated November 4, 1969. This patent deals with one method to form a correction lens, which when used in the exposure box for printing the mosaic screen of the shadow mask color picture tube which deflects light rays emanating from a point light source in such a way that an acceptable compensation is obtained occurs for each of a plurality of predetermined points which are distributed over the entire screen area, namely for all conditions that have a misregistration of the point of impact with the fluorescent dots result in deflection angles of at least 90 ° (in the example described it is a 90 ° tube with a screen diagonal of about 50 cm

However, it has been found that the manufacture and use of corrective lenses for the screen manufacture of Shadow mask color picture tubes, especially for tubes with deflection angles of more than 90 °, e.g. 110 ° tubes, unwanted conditions remain that are not related to

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Get corrected with the help of a refractive lens. Such residual states are, for example, distortions of the triangles which pass through the centers of the three phosphor points of the different phosphors peeler triad can be formed opposite an equilibrium triangle. As a result of the unequal sides These triangles overlap fluorescent points of adjacent triads or the distances between other points are too great. Depending on the type of used to print the mosaic screen Corrective lens can maximize these triangular distortions at the ends of the main axes of the screen and in the center of the screen Screen be minimal or be different over the entire screen area. In some! Cases, especially if the Screen is made by a "second order printing" process as described in U.S. Patent 3,282,691 issued November 1, 1966 is the jet impingement points are essentially concentric with the associated fluorescent dots, itself when the fluorescent triads deviate from their parallelism. However, in most cases, especially with large deflection angles, the beam impingement points do not exactly match the phosphor points of the distorted triads. Depending on the size of this misregistration, there may be unsatisfactory tolerances between the point of impact and the fluorescent point. i.e. tolerances of the white uniformity in the case of beam migration or tolerances of the color purity in the case of overlapping. The beam migration tolerance is the minimum distance by which a certain beam impingement point may shift relative to the associated fluorescent point, without however, that it extends beyond this phosphor point (i.e. begins to leave him). This tolerance is therefore due to the shortest distance between the edges of the fluorescent point and the associated beam impingement point. When the beam impingement points are smaller than the fluorescent points are (! tubes with positive tolerance) and a certain beam impact point protrudes beyond its fluorescent point (state negative phosphor point tolerance), then this

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fluorescent point emits less light than normal and the white balance between the three differently colored phosphor dots changes, so that for the relevant Triad the white uniformity is reduced. The color purity tolerance for a given dye point is given by the shortest distance between the edge of the dye point and the edge of the next beam impact point, the one is assigned to another phosphor point, defined, that is, by the distance by which this next beam impingement point is can move towards a certain phosphor point before it touches it or intersects with the phosphor point. Such an overlap results in a tube for color reproduction a decrease in the purity of color at this point on the screen because of the intersecting beam that coincides with a 3? Color information for a particular color is modulated, too would evoke some light of a different color.

The object of the invention is to provide a shadow mask color picture tube with a fluorescent mosaic screen that improves the tolerance ratios between the fluorescent elements and provides the electron beam impact points.

In a color picture tube of the type mentioned at the outset, this object is achieved according to the invention in that the size of the phosphor elements in each set changes asymmetrically across the surface of the fluorescent screen. Here the size of an or several of the different phosphor elements of each triad depending on the requirements in at least those areas of the screen, where improvement is needed, enlarged or reduced so that the desired balance between the minimal overlap and migration tolerances for each Color is achieved. Preferably, the sizes of the phosphor elements are chosen so that the tolerance in predetermined small areas distributed over the entire screen surface is improved. Furthermore, the minimum dimensions are preferably

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migration "and overlap tolerances for each phosphor element essentially equalized. However, it can in some cases it may be desirable that the overlap tolerance be slightly larger than the corresponding migration tolerance.

The invention is described below with reference to the accompanying drawings explained in more detail. Show it:

Pig. 1 is a schematic drawing of a shadow mask color picture tube according to the invention;

Pig. Figure 2 is a cross-section through an exposure box for printing the screen in which the faceplate assembly the tube is assembled at manufacture;

Fig. 3 is an illustrative front view of the tube faceplate a grid of intersecting lines, which is a point pattern for measuring misregistration determined between beam impingement points and fluorescent points;

Pig. 4 shows a typical illustration of the mutual positions of six phosphor points and their associated beam impingement points near one of the intersections in Pig. 3;

Pig. 5 a characteristic curve for determining the optimal size of the Fluorescent dots; and

Pig. 6 is a family of curves of equal ratio of phosphor point to opening on the screen.

In Pig. Figure 1 is a schematic of a color picture tube of the type mentioned shown. It contains a piston 10 with a conventional electron beam system 11, as for example in the US patent 3,254,251 dated May 31, 1966 for generation three electron beams which are directed along the beam paths 13, 15 and 17 onto a mosaic color screen 19, the

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is applied to the inside of the front disk 21 of the tubular piston 10. A perforated mask 23 is at a small distance attached to the screen 19 in the path of the rays. Preferably the beam system 11 generates the beams in a triangular arrangement, and the shadow mask 23 is more circular with a plurality of smaller ones Openings 23a are formed which are systematically arranged in a diamond-shaped pattern. The screen 19 contains a plurality of color phosphor elements in the form of circular dots in respective assignment to the openings 23a the shadow mask 30. According to FIG. 4, the phosphor points are generally arranged in a hexagonal pattern, wherein three fluorescent dots each with different colors emitting phosphor (for example hot, green and blue) form a group of three (in a triangular arrangement).

When the tube is in operation, the three electron beams are due to the mechanical structure of the beam system 11 and / or the convergence forces acting by external means not shown directed so that they cross in the vicinity of the screen 19. Each of the three beams reaches the shadow mask 23 and penetrates with a part of the openings 23a in such a way that it occurs only on fluorescent dots which light the same Emit color. The beams are with the help of conventional scanning coils 25 in the horizontal and vertical directions over the Screen 19 deflected: One of the deflection directions is illustrated by rays 13 ', 15' and 17 '. The initial level of distraction is perpendicular to the longitudinal direction of the central axis A-A of the tube and lies approximately in the middle of the deflection coils 25 The center of deflection of each beam is defined by the intersection of the (extended) beam path with the plane P-P. If the deflection angle increases from Mull, then it shifts the effective deflection plane is axially in the direction of the screen.

Fig. 2 illustrates a light box suitable for use for printing a mosaic color fluorescent screen for a perforated

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mask tube can be used. The light box 26 has a light box 27 "and a windshield holder 28, the are fastened to each other on a base "by bolts not shown, which in turn are fastened by leg 30 under a desired Angle is held. The light box 27 is a cylindrical cup-shaped casting, which at one end by a molded end wall 31 is closed. The other end of the light box 27 is closed by a plate 32 which folds fits into a circular recess 33 of the light box 27. The plate 32 has a central hole through which a light guide or Collimator 35 protrudes in the form of a tapered glass rod. The thin end 37 of the light guide 35 protrudes slightly beyond the plate 31 and forms a point light source for the Light box. The thicker end 39 of the light guide is fitted with a clamp 41 opposite one in the light box 27 45 mounted lamp 43 supported. A correction lens assembly 51 is by means of bolts 57 via spacers attached to a lens holding ring 53. The retaining ring 53 is clamped between the light box 27 and the windshield holder 28. The lens arrangement 51 can consist of two separate lenses 61 and 63 exist, which are provided for different types of optical corrections and by a Separating ring 65, an upper bracket 67 and a lower bracket are held at a distance from one another. However, it can also be used if necessary only one corrective lens can be used. On the upper surface of the lens 63, an optical filter 71 is more variable Permeability attached as described in U.S. Patent Application 844,852 filed July 25, 1969. The filter 71 can be made from preformed carbon particles' (with a middle Diameter of about 10 millimicrons) in gelatin or another clear colorless binder and in its Vary the thickness over half a wavelength of the yellow light. This filter has essentially a neutral gray permeability, which only changes in the gray intensity. This change fulfills from point to point in such a way that point-wise changes tier HeJliftkoit arise in the light field. The main task of the FiI

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ters 71 lies in the increase in the exposure of the edge areas of the windshield to compensate for the relative to the center opening size of the shadow mask, which decreases towards the edges (improvement of the tolerance) and to compensate for the usual, the square of the decrease in light at the edges with distance.

The fluorescent dots of each dye (e.g. red) are usually applied to the front panel of the tube in the following way:

1) Coating the inner surface of the front panel 21 with a photosensitive material that hardens when exposed and which is mixed with particles of the respective phosphor to be printed;

2) Assembly of the perforated mask 23 with the windshield and assembly of this structure in a light box (for example 26), the

a light source and one or more lenses 61, 63 which are dimensioned so that the light rays so are refracted so that they the deviations of the electron beam paths from normal linear light propagation (as in US Pat. No. 3,476,025) compensate so that essentially a correspondence of the jet impingement points with the Fluorescent dots present during later operation of the tube;

3) Exposure of the photosensitive coating with the through the lens assembly (including the filter 71) and the Mask openings penetrating light to harden the corresponding punctiform areas of the coating;

4) Developing the coating by washing off the uncured Parts between the cured point areas; and

5) Coating the point areas with the desired luminous

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fabric material, if this is not already in the cover was included.

The fluorescent dots of the other colors (e.g. green and blue) are formed on the windshield by repeating this process accordingly. This is commonly done each carried out in a different light box, with the light source in the deflection center for the respective to be printed Color, or at a point in relation to it, is arranged and in each case a different lens arrangement, which specially matched to the color in question is used.

It is common for some tubes to have a predetermined number of points distributed over the entire screen surface in operation to monitor: for example the intersections of a line consisting of horizontal and vertical lines 75 and 77 (Fig. 3) To view grids on the front panel 21 through a microscope and determine which misregistrations and / or triangular distortions occur in the vicinity of each of these points. from At each point, photomicrographs of a group of enlarged phosphor points and the associated beam impingement points are taken. A triangular group of six points comprising a triad of points and three adjacent points is selected and carefully drawn on an enlarged scale as shown in FIG.

4 shows a typical triad of circular phosphor dots 81 with a red phosphor dot 81R, a green phosphor dot 81G and a blue phosphor dot 81B, and three adjacent phosphor dots 81R ¹ , 81G ¹ and 81B ¹ -, which are indicated by large solid circles with the centers 82R, 82G, 82B, 82R ¹ , 82G ¹ and 82B ^! are shown. These phosphor dots are printed in a known manner with essentially the same size in each small screen area. The size of the-

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These points usually change in different areas because of the radial gradation of the mask openings and the changing density of the filter 71. Pie circular beam impingement points 83R, 83G and 83B as well as the adjacent impingement points 83R ¹ , 83G · ¹ and 83B ¹ are indicated by the small solid circles with the centers 84R _f 84G-, 84B, 84R ¹ , 84G- 'and 84B ¹ shown. Because of the limited size of the radiation source and because of the geometry of the tube, the point of incidence of the beam has an inner umbra, an outer penumbra and an intermediate size or diameter which determines the brightness of the emitted light. For reasons of tolerance, the maximum (i.e. the umbra) is usually used.

The first step in analyzing a representation like 4 lies in the determination of the most critical state, that is to say the smallest emigration and overlapping tolerances. A small or negative overlap tolerance is viewed as more critical than an equally large migration tolerance, since color purity errors in the image are more noticeable to the eye as errors of equal size in the ice uniformity. at In the specific example shown, the two tolerances are viewed as equally critical.

First are the tolerances for a typical phosphor dot triad considered. It should be noted that the emigration tolerance is measured along a line passing through the Centers of each phosphor point and its associated impingement spot runs, while the overlap tolerance for a certain phosphor point versus a certain adjacent beam impingement point is measured along a line which is the centers of the fluorescent point and the point of incidence connects. From Fig. 4 it can be seen that the critical tolerance is the migration tolerance for the blue phosphor dot 81B (and 81B '), which is zero here, so

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On the other hand, the minimum (intersection tolerance for the same (blue) phosphor leak, which is the shortest distance between the blue phosphor ^spot 81B 1 and the nearest adjacent green hit spot 83G, is greater than necessary.

The emigration tolerance can be increased (and therefore cheaper by removing some of the excess blue overlap tolerance bargains against an increase in emigration tolerance. This is done by increasing the size or the The diameter of the blue phosphor dots in this area by an amount that is half the difference between the both tolerances, so in this Pail half of the Blue overlap tolerance. The boundaries of the enlarged blue phosphor dots are in Pig. 4 by dashed Circles 85B and 85B 'are shown. This results in the same emigration tolerances BLT and overlap tolerances BOT for the blue fluorescent dots. However, if the overlap tolerance is more critical than the emigration tolerance, then it may be desirable to use the blue emigration tolerance by a smaller amount so that it is, for example, half or a third of the overlap tolerance amounts to.

Another critical tolerance in Pig. 4 is the small overlap tolerance for the red phosphor point 81R with respect to the adjacent blue impingement point 83B ¹ compared to the relatively large migration tolerance for this phosphor point 81R. The red overlap tolerance is increased in this area and the red migration tolerance is decreased by reducing the size of the red fluorescent dots. The extent of the reduction in size is half the sum of the two original red tolerances, so that the new red phosphor dots 85R and 85R ^{1 have the} same emigration and. RLT and IiCT overlap tolerances.

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The minimum overlap tolerance for the green phosphor dot 81G with respect to the blue impact spot 83B 'is almost equal to the green migration tolerance in Pig. 4 However, since the overlap tolerance should be at least equal to the migration tolerance, the size of the green phosphor dots in this area is reduced, as the new dots 85G and 85G 'show, in the same way as the red phosphor dots, so that the green overlap tolerance GTO equal to the emigration tolerance GLT. After the most critical migration and overlap tolerances have been considered and made more favorable, it is no longer necessary to discuss the other relationships in FIG. 4 as well. The dashed circles in I ¹ Ig. 4 determine three different phosphor dot diameters that are required in a specific screen area so that the desired migration and overlap tolerances for each of the three colors in this area result.

A corresponding analysis can be carried out for each of the screen points selected for the measurement, and the new values of the fluorescent dot diameter, the migration tolerance and the overlap tolerance for each dot in three separate tables, one for each color. These values are used to modify the light filter 71, which had been used in the light box for printing the screen of the above-mentioned experimental tube. the The filter is changed in such a way that the phosphor dots printed with the modified filter are essentially have the desired new diameters to improve tolerance.

First, each new fluorescent dot diameter is measured through the known mask opening at the same point (the one through the Gradation characteristics of the mask used is determined) divided, and the resulting ratios are with regard to their position on the screen, for example by

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Allocation of numbers to the intersections of lines 75 and 77 in I * ig. 3 applied. The proportions along each horizontal Line 75 (A to M) are plotted separately over the distance from the screen, for example as indicated by the dots 87 in Pig. 5 is shown. The irregularities of this Relationships along each horizontal line 75 are determined by graphical averaging when the continuous curve 89 is drawn balanced between points 87 within the limits allowed by the new tolerances for each point. By the curve 89 for the horizontal lines A to M determined ratios in each of the positions O to 20 of the pig. 3 become plotted separately along vertical lines 77, and each set of the plotted ratios is replaced by the continuous Curve in the same way as in Fig. 5 for the horizontal Lines 75 is made approximated. Next, the approximated ratios at the selected points, which are determined by the set of vertical curves, with regard to their position on the screen with a separate set recorded for each color, and according to Pig. 6, curves 91 are drawn through these points of equal proportions. This Curve set 91 gives the desired change in phosphor dot diameter for one of the three colors.

The pattern of the curves 91 for each color can be reproduced on the undersurface of the correction lens 63 for that color as shown in FIG Light source 37 leads as described in Figures 4 and 5 of U.S. Patent 3,476,025. Belonging to the curves 91 ratios are converted into filter densities which are required for printing the phosphor dots with diameters in accordance with these conditions, and then a new light filter with the desired pattern for E _r set in the original filter 71 produced. The new filter can be put on

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-H-

the upper surface of the lens 63 with a filter material, whose Density can be changed by exposure, and by exposing this "coating" to light from source 37 through a stack of suitable thin light filters of neutral density are formed, each having a contour that corresponds to one of the Density curves is adapted.

This new light filter is then used in the light box to print the pattern of fluorescent dots in one of the three colors the windscreen used. The fluorescent dots of the other Both colors are printed in the same way with the help of a light box, which contains a light filter that is used for Manufacture the desired phosphor dot diameter for the color in question.

The invention can also be used for the production of perforated mask tubes whose fluorescent elements and associated beam impingement points have a shape other than a circular shape. 7 shows part of a screen of a line screen tube with elongated mask openings for generating elongated beam impingement points. The screen contains elongated fluorescent strips 93ß, 93G- and 933 for the colors red, green and blue, which form a typical triad and are assigned to certain mask openings, and two strips 93B ¹ and 93G ¹ are shown. The associated jet impact points are labeled 95R, 95G, 95B, 95B ¹ and 95 & ¹ . In the embodiment shown, the distances between the beam impingement points are essentially the same, but the distances between the green and blue stripes 93G- and 93B are substantially greater than between the blue and red stripes 93B and 93R. This creates unequal migration and overlap tolerances for each color. In this case, the width of each of the phosphor strips has been increased by an amount sufficient to make the migration and intersection tolerances the same for each color, as shown by the enlarged strips 97R, 97G and 97B.

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Claims (10)

Patentan · Proverbs (J) Color picture tube with a mosaic fluorescent screen consisting of a A number of different sets of fluorescent elements, each of which emits light of different colors when bombarded by electrons, furthermore with a perforated mask arranged at a distance from the luminescent screen and with an electron beam system that works for everyone Phosphor element set one through the shadow mask only Generated on the phosphor elements of the set impinging electron beam, thereby geke ή nzeich that the size of the phosphor elements (81) in each set is asymmetrical over the surface of the phosphor screen (19) changes. 2) Color picture tube with a mosaic luminescent screen made of a plurality of different sets of luminescent elements, which are used in Electron bombardment each emit different colored light, furthermore with one arranged at a distance from the luminescent screen Shadow mask and with an electron beam system that only passes through the shadow mask one for each phosphor element set generated electron beam impinging on the phosphor elements of the relevant set, the size of the electron beam impingement points smaller than that of the corresponding phosphor elements and in any given one small area of the screen is essentially constant, characterized in that the size of the phosphor elements (81) in each set changes over the surface of the phosphor screen (19) according to a pattern which differs from the change pattern of each of the other phosphor element sets. 3) Color picture tube with a mosaic luminescent screen made of a plurality of different sets of luminescent elements, which are used in Electron bombardment each emit different colored light, forner with one arranged at a distance from the luminescent screen 209850/0889 Punch mask and with an electron beam system that works for everyone A set of fluorescent elements impinging through the shadow mask only on the fluorescent elements of the set in question Electron beam is generated, with no correction of the size of the phosphor elements over the surface of the phosphor screen unwanted changes in overlap and migration tolerances occur between screen and electron beam impact points, characterized in that that the sizes of the phosphor elements (81) are selectively dimensioned so that some of them are uncorrected Size larger and others smaller, such that the most critical tolerances in a given screen area Cost of the corresponding less critical tolerance can be improved, with the correction, if necessary, for Each phosphor element is made so that it is affected by the tolerance conditions at the relevant point on the phosphor screen is determined. 4) color picture tube according to claim 2, characterized in that the beam impingement points (83) and the fluorescent elements (81) have a slight misregistration at least in a plurality of areas of the luminescent screen (19). 5) color picture tube according to claim 4, characterized in that the areas over the entire surface of the luminescent screen (19) are distributed. 6) color picture tube according to claim 2, characterized in that the size of the fluorescent elements (81) is chosen so that the out-migration and overlap tolerance for each Fluorescent element of any color in any of the areas practical is equal to. 7) color picture tube according to claim 2, characterized in that the size of the phosphor elements (81) is chosen so that 2098S0 / 0Ü39 the cross-cutting tolerance for each fluorescent element each color is greater than the emigration tolerance. 8) color picture tube according to claim 2, characterized in that that the size of the openings (23a) of the shadow mask (23) varies from a predetermined size in the middle of the shadow mask to a smaller one Size is graded according to the edges of the shadow mask. 9) color picture tube according to claim 2, characterized in that the beam system (11) has three beams (13,15,17) in a triangular arrangement generated that the openings (23a) of the shadow mask (23) are circular and that the fluorescent elements (81) are arranged in a substantially hexagonal pattern with triads, each made up of fluorescent dots of each of the three sentences different. Phosphors exist. ' 10) Method of manufacturing a color picture tube according to Claim 3 209850/0 8 8