CZ624884A3 - Cathode-ray tube comprising a rectangular panel of the front plate - Google Patents

Abstract

Improvement is provided in the appearance of a color picture type cathode-ray tube including rectangular faceplate with an exterior surface having curvature along both the minor (Y-Y) and major (X-X) axes. At least in the center portion of the faceplate, the curvature along the minor axis is at least 10 percent greater than the curvature along the major axis. Points on the exterior surface near the ends of the major axis, at the edges of the screen, lie in a first plane (P1) perpendicular to the central axis (Z-Z) of the tube; points on the exterior surface near the ends of the minor axis, at the edges of the screen, lie in a second plane (P2) which is spaced from and parallel to the first plane; and points on the exterior surface near the ends of the diagonals of the rectangular faceplate, at the edges of the screen, lie in a third plane (P3) which is spaced from and parallel to the first plane. The three planes are spaced from the center portion of the faceplate in the order of second plane, first plane and third plane. Further relative dimensions are detailed. <IMAGE>

Description

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BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to images, and more particularly to the contours of the face plates of such screens.

There are two basic shapes of the faceplate used commercially for rectangular screens with a diagonal screen of greater than about 23 cm, namely spherical and cylindrical. Although a flat shape is also possible, an increase in the thickness and weight of the faceplate required to maintain the same rigidity of the envelope is not desirable.

Moreover, if the flat faceplate screen is a color screen with a shadow mask, the increase in weight and complexity of a suitable shadow mask is also undesirable.

Recently, it has been proposed that spherically shaped faceplates of the screen be improved by increasing the radius of curvature of the panels by a factor of 1.5 to 2. Such an increase in radius of curvature reduces the curvature of the faceplate and thereby allows more satisfactory viewing of the screen off its axis. Although screens having an increased radius of curvature do indeed improve display viewing, there is still a need for even flatter face plates or alternatively screens whose face plates appear to be flatter.

The concept of the shape of the face plate is known which creates the illusion of flatness. The shape has the curvature of the bar; along the main and minor axes of the faceplate, but is non-spherical. In a preferred embodiment of this concept, the peripheral border of the screen is flat. In such screens, it is important to shape the diagonals of the faceplate so that the differing curvature at the points away from the major and minor axes is correctly aligned. This binding can be achieved by allowing at least one change in the sign of the second derivative of the diagonal shape in the direction from the center to the corner.

The invention provides an improved screen comprising a rectangular faceplate having an outer surface with a curvature along both the major and minor axes. The faceplate also includes a cathodoluminescent screen on its inner surface. At least in the central portion of the faceplate, the curvature along side end ends on the front axes is at least 10% greater than the curvature along the major axis.

In the longitudinal direction at the ends of the main axis, the height of the plate is greater than the height. - · the face plate on the minor axis and less than the height of the face plate at the ends of its diagonal, where the following applies:

> SH1 / SH3> a ² / c ² a> SH2 / SH3> b ² / c ² , where b is the half of the major axis of the faceplate, and is half of the minor axis of the faceplate -, c is half the diagonal of the faceplate and the outer face of the faceplate is circularly curved in the central portion with increasing curvature to both ends of the major axis, and is also circularly curved at both ends of the major axis, with the outer face of the faceplate lying bothKDoay and k the axes in the first orthogonal perpendicular screen, the one arranged in a second distance from and parallel to it and the points at the diagonal in a third plane distant from the first plane; and the center of the faceplate forms a tangent point parallel to the three planes of the axis. one k5 of the centralmost axis of the plane and arranged and parallel to the fourth plane on the adjacent first axis

- and -

The present invention provides a faceplate shape that appears flatter than previously designed screens with a longer radius and which does not require the use of much thicker glass to maintain screen strength. '

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the accompanying drawings, in which: Figure 1 is a partially axial sectional view of a color screen with a screen mask incorporating one exemplary embodiment of the invention; 1-2, FIG.

Figures 3, 4 and 5 are cross-sectional views of the faceplate of Figure 2 taken along planes 3-3,

4-4, or 5-5 of Fig. 2, Fig. 6 is a composite diagram of the faceplate shapes according to the major axis, minor axis, and screen diagonal of Fig. 1; Fig. 7 is a composite diagram of the faceplate shapes taken along planes 3- 3, AA, BB, CC of Fig. 2;

Fig. 9 is a diagram of a face plate quadrant according to the invention showing radii and curvature functions; Fig. 9 is a diagram of a face plate contours according to the invention along a major axis, minor axis and diagonal compared to a spherical plate of standard radius; along the major axis, the minor axis and the diagonal as compared to a spherical plate having a radius of 1.5 times the standard size, FIG. 11 is a diagram of the front plate contour according to the invention along the major axis, the minor axis of the diagonal compared to a spherical plate twice the radius Fig. 12 is a diagram of the faceplate contours of the invention along the major axis, minor axis and diagonal as compared to a non-spherical faceplate with a planar edge.

Cbr. 1 illustrates a rectangular screen in the form of a color screen 10 having a glass envelope 11 comprising a rectangular faceplate 12 and a cylindrical neck 14 connected thereto. The faceplate 12 includes a display faceplate and a peripheral flange or sidewall 20 that is fused to the funnel 16 by a glass frit 17. The rectangular three-color cathodoluminescent phosphor screen 22 is supported by the inner surface of the faceplate 18. The screen 22 is preferably a line screen wherein the phosphor lines extend substantially parallel to the minor axis YY of the screen, i.e. perpendicular to the plane of FIG. 1. Alternatively, the screen 22 may be a point screen. The linolith hole color selection electrode or shield mask 24 is detachably connected to the front panel 12 in a predetermined spatial relationship to the screen 22. The inline electron gun 26, shown schematically in dashed lines in Fig. 1, is centrally mounted in the neck 14 to form and route three electron beams. of the beams 28 along the coplanar convergent paths through the mask 24 to the screen 22. Alternatively, the electron gun 26 may have a triangular or delta configuration.

The screen 10 of FIG. 1 is designed to be used with an external magnetic deflection yoke, such as yoke 30 schematically shown surrounding neck 14 and funnel 16 near their junction to expose the three electron beams 28 to the vertical and horizontal magnetic flux for scanning electron beams. horizontally in the direction of the major axis XX and vertically in the direction of the minor axis YY in a rectangular pattern through the screen 22.

Giant. 2 shows the face of the front panel 12. The edges of the front panel 12 form a rectangle with slightly curved sides. The boundary of the screen 22 is shown the boundary of the screen is rectangular with straight dashed lines. The Parties and the Edge hereby: i

Specific cross sections of the front panel 12 along the minor axis YY, the major axis XX and the diagonals are shown in Figures 3, 4 and 5 respectively. The outer surface of the front panel 12 is curved along both the major axis and the minor axis, the curvature along the minor axis. is greater than the curvature along the major axis, at least in the middle portion of the front panel 12. For example, at the center of the front panel 12, the ratio of the radius of curvature of the outer surface shapes along the major axis to the radius of curvature along the minor axis is greater than 1.1. 10%. The deflection height of the point on the panel contour is measured from a plane perpendicular to the longitudinal axis ZZ of the screen and tangent to the center of the front panel 12 to another plane, for example P1, P2 or P3, which is parallel to the P plane. SH3 for points on the outer face of faceplate 18 near the ends of the major axis, minor axis, and diagonals at the edges of the screen 22 are shown in Figures 3, 4 and 5 respectively. The three deflection heights shown are in relation SH1 <SII2 <

Giant. 6 shows superimposed contours of the outer surface of the front panel 12 along a major axis, minor axis and diagonal, each contour terminating at the edge of the screen. The contour along the main axis ends on the first plane P1, which is perpendicular to the longitudinal axis Z-Z of the screen. The contour along the minor axis ends in a second plane P2 which is at a distance from the first plane P1 and parallel to the first plane P1. The diagonal contour ends in a third plane P3, which is at a distance from the first plane P1 and is parallel to the first plane P1. The three planes are at a distance from the central portion of the faceplate 18 in a second plane P2, a first plane P1 and a third plane P3. The points on the outer surface near the ends of the main axis at the edges of the screen 22 lie in the first plane P1. The points on the outer surface near the ends of the minor axis at the edges, the shades 22 lie in the second plane P2. The points on the outer surface near the ends of the diagonals at the edges of the screen 22 lie in the third plane P3. The ratio of the pitch, measured along the central longitudinal axis of the screen 10, between the second plane P2 and the fourth plane P tangent to the center of the faceplate 18 to the distance between the third plane P3 and the fourth plane P is greater than the minor axis of the screen 12 raised to the second divided by the size of the screen diagonal 22, raised to the second and less than 1. In the screen 10 with the screen 22 having an aspect ratio of 4 to 3, the lower limit of this aspect ratio is about 9/25. In another screen with a 5: 3 screen, the lower limit of the distance ratio is about 9: 34. Other side factors also enter accurate calculations of the shape of the faceplate 18 so that said ratios can only be considered approximate. Similarly, the ratio of the distances between the first plane P1 and the fourth plane? to the distance between the third plane P3 and the fourth plane P is greater than the dimension of the principal axis of the screen, squared to the second divided by the diagonal measurement; lampshades, squared and less than 1.

In a screen 10 having a 4: 3 aspect ratio, the lower limit of this aspect ratio is about 16/25. In the 5: 3 aspect screen 10, the lower limit of the main axis distance ratio is 25: 34. In any case, the upper limit equal to the unit is excluded from the range, since a ratio of 1 would indicate a face plate with a planar edge. Alternatively, the distance between the second plane P2 and the third plane P3 is substantially equal to the dimension of the minor axis of the screen squared, divided by the dimension of the diagonal of the screen squared, multiplied by the second and multiplied by ee zi third plane P3 and fourth plane P.

Giant. 7 shows the shapes of the outer surface parallel to the minor axis Y-Y along planes 3-3, the minor axes A-A, B-B and C-C of FIG. 2. Each contour is circular with the radius of curvature of each cross section increasing with increasing distance from the minor axis.

The outer surface for one exemplary embodiment of the faceplate 18 is described by a bivariant even-order polynomial of the 4th order function that provides a description of the quadrant symmetric smoothed surface of the base surface developed as shown in Figure S. . The surface curvature on the sides of the faceplate 15 parallel to the minor axis and at the edges of the shield is also circular, but with a radius: curvature R. The surface curvature in the parts parallel to the minor axis, which are between the minor axis and the sides of the staple, is circular with a radius of curvature R1. The radius of curvature R ^ is a function of the distance along the major axis from the minor axis and satisfies the relation Rq. The surface curvature at the top and bottom of the faceplate 18 parallel to the major axis and at the edge of the screen is circular with the radius of curvature R R. Surface curvature along the major axis is a somewhat more complex function of H (x) distance from the minor axis. Basically, this major axis curvature is circular near the center of the faceplate 18 with a radius of curvature R, but the curvature increases near the sides of the faceplate 18. Such an increase near the faces of the faceplate 18 can be considered a failure of the base radius as a curvature R.

The following table gives dimensions for a screen with a screen angle of 69 cm constructed according to the invention.

SH1 18 mm 3112 22nd mm SH3 26 mm Ro 1150 mm Re 5126 mm Ri > 1150 mm Rl 4574 mni rí (X) approaching R 1673 mm

The inner surface of the screen 22 by the frontal addition of suitable glass wedges behind the IS plates is determined by the purpose of the reinforcement, i1;

Is known in the art, and reshaping a bivariant polynomial form.

Figures 9 to 12 show the face shapes of the faceplate 18 along a major axis, minor axis and diagonal where the faceplate 18 has been constructed according to the invention, as shown in dashed lines as compared to four prior art faceplate shapes as shown in full solids. lines. All screens have a 69 cm screen diagonal.

Figure 9 shows the outline of a spherical faceplate with a standard IR radius. An exemplary standard radius size for a 635 mm screen is about 1034 mm. Since the face plate of the standard IR radius is spherical, the contours of the major axis and the minor axis lie on the contour of the diagonal. The deflection height measured between the parallel planes passing through the diagonal ends and the center face of the faceplate 1S is 52 mm for a faceplate with a standard IR radius. The difference in deflection height between the ends of the major and minor axes is about 15 mm, and the difference in deflection height between the ends of the major axis and the ends of the diagonals is about 19 mm.

Although the deflection height at the end of the diagonal at the contour of the faceplate 1S of the invention, i.e. 26 mm, is one half of the deflection height of a standard faceplate of radius IR, i.e. 52 mm, it should be noted that side axis is very likely curvature face plates with standard radius IR.

Such a curvature along the side plate 053 of the present invention provides the necessary strength without excessively increasing the glass thickness to withstand atmospheric pressure when the screen is depleted. In the following two spherical faceplates having a longer curvature radius, the required strength is obtained by using relatively thicker glass, resulting in heavier screens.

Gbr. 10 shows the outline of a reduced curvature spherical faceplate with a radius of curvature 1.5 times greater than the standard faceplate with an IR radius of FIG. 9, for example about 1500 mm. The deflection height for a 1.5 R faceplate is about 39 mm. The difference in deflection height between the ends of the major and minor axes is about 11 mm, and the difference in deflection height between the ends of the major axis and the ends of the diagonals is about 15 mm.

Giant. 11 shows an outline of a spherical faceplate having an even smaller curvature with a radius of curvature twice as large as the standard faceplate with an IR radius of FIG. 9, for example about 2000 mm. The deflection height for the faceplate of radius 2R is 26 mm, the same as that of the faceplate 18 according to the invention. The difference in deflection height between the ends of the major and minor axes is S mm and the difference in deflection height between the ends of the major axis and the ends of the parallel lines is about 9 mm. Although spherical face plates having even greater curvature radii than a 2R-shaped customs plate, it is theoretically possible to add additional weight to the plate's windshield and increase complexity. the design of the shield mask poses serious disadvantages for their commercialization. However, the invention provides an improved faceplate 16 and a screen circumventing these disadvantages, while at the same time providing the viewing benefits of flatter faceplate screens. The circumference of the new faceplate 18 at the edges of the screen only changes by + 4 mm from the plane passing the ends of the main axis contours for the 69 cm screen. Since these variations are small, the edges of the screen appear substantially flat to the viewer. Such flatness at the edges of the screen creates the illusion that the screen is flat even if the faceplate 18 is curved. As indicated by the differences in deflection height mentioned for the design of spherical face plates with radii IR, 1.5R and 2Β »such an illusion of flatness is not for these spherical? possible designs.

Giant. 12 illustrates the contours of the faceplate along the major axis, minor axis, and diagonal for a faceplate with a planar edge, as mentioned in the height of the opening paragraphs. Such contours indeed provide truly planar edges of the screen. However, in general, if the diagonal contour of the planar edge face plate is formed with substantial bending, some surface distortion can be observed. The invention makes it possible to create a smooth surface of the faceplate where there is no appreciable surface distortion.

Although a preferred embodiment of the screen 10 having a diagonal of 69 cm @ -1 is described with a difference; deflection. height between the first plane P1 and the second plane? 2 equal to 4 mm and the difference between the first plane P1 and the third plane P3 also 4 mm, the scope of the invention includes other variations in deflection height such as j (previously mentioned distance diameter limits). Special type of lampshade, or electron gun.

implied c invention screen

PV 6248-84

Claims (6)

PATENTOV at 1 > Q · <=> LO O CZ σ ’ X WITH . ^: > < O - < Π N, ro ν- <α řjl κ_χ 1 Zit jr. A screen comprising a rectangular faceplate comprising an observation faceplate and peripheral sidewalls, wherein the faceplate has an outer surface curved along its major and minor axes and an inner surface provided with a cathodoluminescent screen, wherein at least in the central portion of the faceplate there is at least 10% greater than the curvature along the major axis, characterized in that in the longitudinal direction at the ends of the major axis (XX), the height (SH2) of the faceplate (18) is greater than the height (SH1) of the faceplate (18) at the ends of the minor axis (YY) and less than the height (SH3) of the faceplate (18) at the ends of its diagonal (5), where the relationships are: 1> SH1 / SH3> a ² / c ² a 1> SH2 / SH3> b ² / c ² , where b is half the dimension of the major axis (XX) of the faceplate (18), and is half the dimension of the minor axis (YY) of the faceplate (18), c is half the diagonal ) the faceplate (18) and the outer face of the faceplate (18) is circularly curved in the central portion with increasing curvature to both ends of the major axis (XX) and is also circularly curved at both ends of the minor axis (YY), On the one hand, the main axes (XX) lie in a first plane (P1) perpendicular to the center axis (ZZ) of the screen (10), as a second axis (YY) at the end plane of the second plane (P2). the first plane (P1) and parallel thereto, and secondly the endpoints of the diagonal (5) disposed in a third plane (P3) distant from the first plane (P1) and parallel thereto and the center of the faceplate (18) form the tangent point of the fourth plane (P) parallel to the three planes (P1, P2, P3). 2. A screen as claimed in claim 1 having an aspect ratio of 4: 3, characterized in that the square of the dimension of the minor axis (YY) on the faceplate (18) divided by the square of the diagonal dimension of the faceplate (18) is greater than 9/25 and less than 1. 3. A screen as claimed in claim 1 having an aspect ratio of 5: 3, wherein the square of the dimension of the minor axis (YY) on the faceplate (18) divided by the square of the diagonal dimension of the faceplate (18) is greater than 9/34 and less than 1. 4. The screen of claim 1, wherein the ratio of the height (SH1) of the faceplate (18) forming the distance of the first plane (P1) from the fourth plane (P) measured in the center line (YY). ) of the screen (10) to the height (SH 3) of the plate (18) forming the distance, the third plane (P3) from the fourth plane (P) is greater than the square of the dimension of the major axis ( XX) on the faceplate (18) divided by the square of the diagonal dimension of the faceplate (18). 5. A screen as claimed in claim 4 having an aspect ratio of 4: 3, characterized in that the square of the major axis dimension (X of the faceplate (18) divided by the square of the diagonal dimension of the slab (18) is greater than 16/25 and less than 1. 6.Obrazovka according to claim 4 having an aspect ratio of 5: 3, 9 knows about I s ^to t in that the square dimensions of the major axis (X front plate (18) divided by the square of the diagonal dimension of the plate (18) is greater than 25 / 34 and less than 1. X) at the front X) at the front i í s 'i i O o r ~ O i <