FR2551582A1 - CATHODE RAY TUBE HAVING A FLAT PERIPHERAL FRONT PLATE - Google Patents

Abstract

CATHODIC RADIUS TUBE WITH RECTANGULAR FACEPLATE SHOWING AN OUTER SURFACE CURVED BOTH ALONG ITS MAIN AXIS AND ITS SECONDARY AXIS, AND PROVIDED WITH A LUMINESCENT SCREEN ON THE INSIDE SURFACE OF THE PLATE, THE LENGTH OF THE LENGTH OF THE PLATE. SECONDARY AXIS, AT LEAST IN A CENTRAL PART OF THE PLATE BEING AT LEAST 10 GREATER THAN THE CURVATURE ALONG THE MAIN AXIS XX, THIS TUBE BEING CHARACTERIZED IN THAT IT HAS POINTS, ON THE OUTER SURFACE, NEAR OF THE ENDS OF AXIS XX, ON THE EDGES OF SCREEN 22, WHICH ARE LOCATED IN A FIRST PLANE P1 PERPENDICULAR TO A LONGITUDINAL CENTRAL AXIS ZZ OF TUBE 10; POINTS ON THE EXTERIOR SURFACE, NEAR THE ENDS OF THE SECONDARY Y-Y AXIS, ON THE EDGES OF THE SCREEN, WHICH ARE LOCATED IN A SECOND PLANE P2 SPACE IN RELATION TO THE FIRST PLANE P1 AND PARALLEL TO THIS PLAN; AND, POINTS, ON THE OUTER SURFACE, NEAR THE ENDS OF THE DIAGONALS OF PLATE 18, ON THE EDGES OF THE SCREEN, WHICH ARE LOCATED IN A THIRD PLANE P3 SPACE IN RELATION TO AND PARALLEL TO THE FOREGROUND PLATE. THE PLANS P1, P2 AND P3 ARE SPACED IN RELATION TO A FOURTH PLANE P PARALLEL TO THE OTHERS AND TANGENT TO THE CENTRAL PART OF THE PLATE, THE PLANS P1, P2, P3 ARE SPACED, FROM THIS CENTRAL PART, IN ORDER NEXT: SECOND PLAN, FIRST PLAN, AND THIRD PLAN.

Description

The present invention relates to cathode ray tubes, 't erine

  specifically targets the surface contours of the faceplate panels of

such tubes.

  There are two basic faceplate panel contours currently used commercially for rectangular cathode ray tubes having screen dimensions greater than 23 cm diagonal: spherical contours and cylindrical contours Although it is possible to consider flat contours, the additional thickness and weight required for the front plate panel, in order to maintain the same envelope resistance, is undesirable In addition, if the flat front plate tube is a color image tube shadow mask, additional weight and complexity of a mask

  appropriate shade are also undesirable.

  It has recently been proposed to improve front plate panels of spherical cathode-ray tubes by increasing the radius of curvature of the panels by a factor of 1.5 to 2. Such an increase in radius of curvature decreases the curvature of the panel. front plate, which allows a better observation of the tube screen, when one is placed in a position

  offset from the axis of this tube Although such tubes, which have an increased radius of curvature, provide improved observation, there is still a need to make even flatter front plates, or, alternatively, to make tubes that look flatter.

  A concept of contour of a new front plate panel which gives the illusion of flatness is described in French patents n * 84 02 864, n 84 02 865, no 84 02 866, requested on February 24, 1984 by the present Titular Company. According to this concept, the contour has a curvature both along the main and secondary axes of the faceplate panel, but it is not spherical. According to a preferred embodiment described in these patents, the peripheral border of the screen of the tube is flat In such tubes, it is important to give the diagonals of the front plate panel a contour such that the various curvatures which extend from the main and secondary axes are correctly connected. In the French patent n * 84 02 865, this connection is obtained by allowing at least one change of sign of the

  second derivative of the diagonal contour, in the center-corner direction.

  This invention proposes to provide a cathode ray tube, the front plate panel of which has a substantially planar screen periphery. To this end, it relates to a cathode ray tube which comprises a rectangular front plate having an external surface curved both along its main axis and its secondary axis, this front plate being provided with a cathodoluminescent screen on a surface. interior of said plate, the curvature along the secondary axis, at least in a central part of the front plate, being 10 O at least greater than the curvature along the main axis, this cathode ray tube being characterized in that it comprises: points on said outer surface, near the ends of said main axis, on the edges of the screen of the tube, which are located in a first plane which is perpendicular to a longitudinal central axis of said tube; dots on said outer surface, near the ends of said secondary axis, on the edges of the screen, which are located in a second plane which is spaced from and parallel to the first plane; and, points, on said outer surface, near the ends of the diagonals of the rectangular front plate, on the edges of the screen, which are located in a third plane which is spaced from the first plane and parallel

to this one.

  The first, second and third planes are spaced with respect to a fourth plane which is parallel to the first three planes and which is tangent to the central part of said front plate, the first three planes being spaced from this central part in the next order: second plan, first plan

and third shot.

  Thanks to the invention, a front plate panel is obtained whose outline 25 appears flatter than that of the previous tubes, with a larger radius, this new tube according to the invention does not require the use of thicker glass for in

maintain resistance.

  Other characteristics and advantages of the present invention will emerge

  of the description given below with reference to the appended drawings, which illustrate various embodiments thereof which are in no way limiting in nature

  Drawings: Figure 1 is a plan view, partially in axial section, of a color image tube with shadow mask in which an embodiment of the invention has been implemented; Figure 2 is a front elevational view of the front plate panel of the tube shown in Figure 1, this view being taken along 2-2 of Figure 1; Figures 3, 4 and 5 are sectional views of the front plate panel of Figure 2, along lines 3-3, 4-4 and 5-5 of this Figure 2; Figure 6 is a composite diagram of the contours of the main and secondary axes and the diagonal of the tube panel shown in Figure 1; Figure 7 is a composite diagram of the contours of the faceplate panel, this diagram being taken along axes 3-3, A-A, B-B and C-C of Figure 2; Figure 8 is a diagram of a quadrant of the faceplate panel according to the present invention, showing the radius of curvature and the functions obtained by this curvature; Figure 9 is a schematic view showing the contours of the main axis, the secondary axis and the diagonal of the panel according to the invention, compared to a spherical panel with conventional radius Figure 10 is a schematic view showing the contours of the main axis, the secondary axis and the diagonal of the panel according to the invention, compared to a known spherical panel having a radius equal to 1.5 times a standard radius; Figure 11 is a diagram illustrating the contours of the main axis, the secondary axis and the diagonal of the panel according to the invention, compared to a spherical panel with a radius equal to twice a standard radius ,; and, FIG. 12 is a schematic view illustrating the contours of the main axis, the secondary axis and the diagonal of the panel according to the invention,

  compared to a panel with non-spherical planar edges.

  Figure 1 shows a cathode ray tube produced in the form

  of a color image tube 10, comprising a glass envelope 11 provided with a front plate panel 12 and a tubular neck 14, these two elements being connected by a frustoconical part 16 in the form of a funnel The panel comprises an observation front plate 18 and a lateral wall or peripheral flange 20 which is sealed to the frustoconical part 16 by a glass frit 17.

  A screen of three-color cathodoluminescent phosphors 22 is supported by the internal surface of the front plate 18 Preferably, this screen is a line screen in which the lines of phosphors extend substantially parallel to the secondary axis (or minor axis) YY of the tube (this axis is perpendicular to the plane of Figure 1) As a variant, the screen can be a screen of dots. A color selection electrode, provided with a plurality of perforations, or shadow mask 24, is removably mounted inside the front plate panel 12, in predetermined spacing relation to the screen 12 An online electronic gun 26, shown schematically in Figure 1 by a contour in broken lines, is mounted at the center of the neck 14, so as to generate and direct three electron beams 28 along convergent coplanar paths, through the mask 24, towards the screen 22. As a variant, the electronic gun can have a configuration

triangular or delta.

  The tube 10 illustrated in FIG. 1 is designed and produced so as to be used with an external magnetic deflection collar 4, such as that shown diagrammatically at 30, around the neck 14 and the frustoconical part 16, in the vicinity of the junction of these two elements, in order to subject the three electron beams 28 to vertical and horizontal magnetic flux ensuring the scanning of the electron beams along the main axis (XX) and vertically along the secondary axis (YY), respectively, according to a rectangular frame on

screen 22.

  Figure 2 shows the front part of the front plate panel 12.

  The periphery of the panel 12 forms a rectangle having slightly curved sides The border of the screen 22 has been shown in the form of an interrupted contour This screen border is rectangular, with sides

rectilinear and right angles.

  The straight sections of the specific panel, along the secondary axis (YY), the main axis (XX) and the diagonal are shown respectively in Figures 3, 4 and 5 The outer surface of the panel 12 is curved at both along the main axis and along the secondary axis, the curvature along the secondary axis being greater than that along the main axis, at least in the central part of the panel 12 For example, in the center of the front plate, the ratio of the radius of curvature of the contour of the outer surface along the main axis, to the radius of curvature along the secondary axis is greater than 1, 1 (or greater at a difference of 10 o) The sagittal height of a point located on the contour of the panel is measured from a plane (P) which is perpendicular to the longitudinal axis (ZZ) of the tube and tangent to the center of the panel 12, up to 'to another plane (for example Pi, P 2, P 3), which is parallel to the plane (P) The sagittal heights SH 1, SH Z, SH 3, with respect to the points which are located on the outer surface of the front plate 18, near the

  ends of the secondary axis, the main axis and the diagonal, on the 5 edges of the screen 22, are indicated respectively in Figures 3, 4 and 5.

  The three sagittal heights correspond to the following relation SH 1 4 SH 2 C_ SH 3 Figure 6 represents the contours of the external surface of the panel along the principal axis, the secondary axis and the diagonal, these contours 10 being superimposed on each other Each contour ends on the edge of the screen The contour of the main axis ends on a first plane (Pl) which is perpendicular to the longitudinal axis (ZZ) of the tube The contour of the secondary axis ends on a second plane (P 2) which is spaced from the first plane (Pl), to which it is parallel The outline of the diagonal ends on a third plane (P 3) spaced from the first plane (Pl ) and parallel to it The three planes (P 1 l, P 2, P 3) are spaced from the central part of the front plate

  In the following order: second plane (P 2), first plane (P 1 l) and third plane (P 3).

  Dots, on the outer surface near the ends of the main axis, on the edges of the screen, are located in the foreground (P 1) Dots, 20 on the outer surface near the ends of the secondary axis , on the edges of the screen, are located in the second plane (P 2) Points, on the outer surface near the ends of the diagonals, on the edges of the screen, are located in the third plane (P 3) The ratio of the spacing, measured along the central longitudinal axis of the tube, between the second plane (P 2) and the plane (P) tangent to the center of the front plate, to the spacing between the third plane (P 3) and the plane (P), is larger than the dimension of the screen axis, raised to the square, divided by the dimension of the screen diagonal, raised to the square, and this ratio is less than 1 In a tube having a screen which has an aspect ratio of 4/3 (we know that the aspect ratio is the aspect ratio of the image), the lower limit of c he spacing ratio is of the order of 9/25 In another tube, provided with a screen having an image format of 5/3, the lower limit of this spacing ratio was approximately 9/34 Other secondary factors also enter into the precise calculations of the faceplate contours, so that the ratios indicated here should only be considered as approximate values. Similarly, the ratio of the spacing between the foreground (P 1 ) and the plane (P) at the spacing between the third plane (P 3) and the plane (P) is greater than the dimension of the main axis of the screen, squared, divided by the dimension of the screen diagonal, squared, this ratio

  also being less than 1.

  In a tube with an aspect ratio of 4/3, the lower limit of this spacing ratio is about 16/25 In a tube with an aspect ratio of 5/3, the lower limit of the aspect ratio spacing of the main axis is of the order of 25/34 In each case, the upper limit equal to

  the unit is excluded, since a value of the ratio equal to the unit means that the front plate has flat edges.

  As a variant, the spacing between the second plane (P 2) and the third plane (P 3) is substantially equal to the dimension of the secondary axis of the screen, squared, divided by the dimension of the diagonal of the screen squared,

  multiplied by the spacing between the third plane (P 3) and the plane (P).

  In FIG. 7, the contours of the external surface are shown,

  parallel to the secondary axis (YY), along axes 3-3 (secondary axis), AA, BB and CC of Figure 2 Each contour is circular, the radius of curvature of each cross section increasing at the same time as increasing the distance from the secondary axis.

  The external surface, for an embodiment of the front plate, is expressed in the form of a double variable polynomial, with uniform function and of the fourth order, giving a smooth surface, having a quadrant symmetry and corresponding to the developed surface illustrated by FIG. 8 The surface curvature along the secondary axis is circular, with a radius of curvature Ro The surface curvature, on the sides of the front plate parallel to the secondary axis and on the edge of the screen, is also circular, but with a radius of curvature Re The surface curvature, for sections parallel to the secondary axis which are located between the secondary axis and the sides of the screen, is circular, with a radius of curvature Ri The radius of curvature 30 Ri is a function of the distance along the main axis from the secondary axis, and it responds to the relationship Ro <Ri <Re The surface curvature, at top and bottom of the front plate, parallel to the main axis and on the edge of the screen, is circular, with a radius of curvature Ri The surface curvature along the main axis is a significantly more complex function H (x) of the distance from of the secondary axis Basically, this curvature of the main axis is circular near the center of the front plate, with a radius of curvature R, but it increases near the edges of the front plate This increase near the edges of the front plate can be considered as a disturbance, on the basic radius of curvature R. In the following table, we have given dimensions with regard to a

  tube with a screen of 69 cm (diagonal), produced as described above.

Board

  SH 1 18 mm SH 2 22 mm SH 3 26 mm Ro 1150 mm Re 5126 mm Ri 1150 mm and Z: 5126 mm R 4574 mm X (x) R disturbed: 1673 mm The internal surface of the front plate screen is defined by adding

  a rim suitable for glass, in order to reinforce it, as is well known, and by reformulating the contour in the form of a double variable polynomial.

  Figures 9 to 12 illustrate the surface contours of the main axis, the secondary axis and the diagonal of a front plate produced according to the present invention, these contours having been indicated by broken lines, compared with four contours of front plate according to the prior art, shown in solid lines All the tubes had a screen diagonal

69 cm.

  A standard of a spherical front plate of standard radius 1 R is visible in Figure 9 An example of standard radius for a tube with a diagonal of about 635 mm is of the order of 1034 mm Since the

  front plate 1 R is spherical, the main axis and secondary axis contours are located on the contour of the diagonal The sagittal height, measured between parallel planes passing through the ends of the diagonal and the central surface of the front plate , for the front plate l R, is 52 mm.

  The difference in sagittal height between the ends of the main and secondary axes is approximately 15 mm, and the difference in sagittal height between the ends of the main axis and the ends of the diagonals is of the order of

19 mm.

  Although the sagittal height, at the end of the diagonal of the front plate contour according to the invention (26 mm) is equal to half that of the standard front plate 1 R (52 mm), it will be noted that the curvature of contour according to the invention, along the secondary axis, is very close to that of the front plate 1 R Such a curvature, along the secondary axis of the front plate according to the invention, provides the desired resistance , without greatly increasing the thickness of the glass, to resist atmospheric pressure when a tube is evacuated In the following two spherical front plates, having larger radii of curvature, the necessary resistance is obtained by using a relatively glass thicker, which produces heavier tubes. FIG. 10 shows a contour of a spherical front plate 15 which has a reduced curvature, with a radius of curvature which is equal to 1.5 times that of the standard front plate 1 R represented in FIG. 9, c ' that is to say of the order of 1500 mm The sagittal height of the front plate 1, 5 R is of the order of 39 mm The difference in sagittal height between the ends of the main and secondary axes is approximately 11 mm, and the difference in sagittal height between the ends of the main axis and those of the diagonals

is around 15 mm.

  Figure 11 shows a contour of a spherical front plate having an even smaller curvature, its radius of curvature being equal to twice that of the standard front plate 1 R illustrated in Figure 9, i.e. around 25,000 mm The sagittal height, as regards the front plate 2 R, is 26 mm, that is to say the same as that of the contour of the front plate according to the invention The difference in sagittal height between the ends of

  the main axis and the secondary axis is 8 mm, and the difference in sagittal height between the ends of the main axis and those of the diagonals is of the order of 9 mm.

  Although it is possible to envisage spherical front plates having even greater radii of curvature than that of the 2 R front plate, the additional weight of glass required and the increased complexity of the design of the shadow mask constitute serious obstacles to their marketing However, the present invention provides a new front plate and a new tube which overcome these obstacles, while presenting the advantages of very flat front plate tubes, as regards the comfort of observation. of the front plate 18 according to the present invention, on the edges of the screen, varies only by + 4 mm, from a plane pas5 sant by the ends of the outline of the main axis, for a tube having a diagonal of 69 cm Taking into account that this variation is very small, the edges of the screen appear substantially flat to an observer This flatness, on the edges of the screen, creates the illusion according to laq if the screen is flat, even if there is a certain curvature of the front plate As indicated by 10, the differences in sagittal heights noted for the examples of realization of the spherical front plates 1 R, 1, 5 R and 2 R, this illusion of flatness is

  not possible for these spherical embodiments.

  FIG. 12 shows the contours of a front plate with planar edges, along the main axis, the secondary axis and the diagonal, of the type which was the subject of the discussion which appears in the preamble below. above these contours give a screen periphery which is really flat; however, in general, if the diagonal contour of such a front plate with flat edges has a relatively large inflection, one can observe a certain distortion

  The present invention allows the formation of a smooth and smooth faceplate surface 20 without detrimental surface distortion.

  Although the preferred exemplary embodiment refers to a tube having a diagonal of 69 cm and a difference in sagittal height, between the first plane Pl and the second plane P 2, of 4 mm, and a difference between the first plane Pl and the third plane P 3 also of 4 mm, the invention is not limited to this example, but it also encompasses the embodiments of tubes having other differences in sagittal height, as indicated above, in Regarding the limits of spacing ratios Finally, this invention is not limited to a particular type of cathode ray tube screen or

electronic gun.

Claims (5)

  1 cathode ray tube which comprises a rectangular front plate having an external surface curved both along its main axis and its secondary axis, this front plate being provided with a cathodo-luminescent screen on an internal surface of said plate, the curvature along the secondary axis, at least in a central part of the front plate, being at least 10% greater than the curvature along the main axis, this cathode ray tube being characterized in that it comprises points, on said outer surface, near the ends of said main axis (XX), on the edges of the screen (22) of the tube, which are located in a first plane (P 1) which is perpendicular to a longitudinal central axis (ZZ) of said tube (10); points on said outer surface, near the ends of said secondary axis (YY), on the edges of the screen, which are located in a second plane 15 (P 2) which is spaced from the first plane (P 1) and parallel to this plane; and, points, on said outer surface, near the ends of the diagonals of the rectangular front plate (18), on the edges of the screen, which are located in a third plane (P 3) which is spaced from the first plane and parallel to it; and in that the first (Pl), second (P 2) and third (P 3) planes are spaced with respect to a fourth plane (P) which is parallel to the first three planes and which is tangent to the central part of said front plate, the first three planes (P 1, P 2, P 3) being spaced, from this central part, in   the following order: second plan, first plan, and third plan.   2 cathode ray tube according to claim 1, characterized in that the ratio of the spacing (SH 1) between the second (P 2) and fourth (P) planes, measured along the longitudinal central axis (ZZ) of said tube (10), at the spacing (SH 3) between said third (P 3) and fourth (P) planes, is larger than the dimension of the secondary axis of said screen (22), squared, 30 divided by the size of the screen diagonal, squared, and it's less than unity.   3 cathode ray tube according to claim 2, having an image format, that is to say a width / height ratio of the image, of 4/3, characterized in that the dimension of the secondary axis of said screen (22), raised to the square, divided by the dimension of the diagonal of said screen, raised to the square,   is greater than 9/25, and less than 1.   4 cathode ray tube according to claim 2, having an image format of 5/3, characterized in that the dimension of the secondary axis of said screen (22), squared, divided by the dimension of the diagonal of the screen, squared, is greater than 9/34 and less than 1. Cathode ray tube according to claim 1, characterized in that the ratio of the spacing (SH 1) between the first (P 1) and fourth (P) planes, measured along the longitudinal central axis (ZZ) of said tube (10), at the spacing (SH 3) between the third (P 3) and the fourth (P) planes, is greater than 10 the dimension of the main axis of said screen, squared, divided by the dimension of the diagonal of said screen (22), squared, and it is less than 1. 6 Cathode ray tube according to claim 5, having a 4/3 aspect ratio, characterized in that the dimension of said main axis of said screen (22), squared, divided by the diagonal dimension of the screen,   squared, is greater than 16/25 and less than 1.   7 cathode ray tube according to claim 5, having an image format of 5/3, characterized in that the dimension of said main axis   of said screen (22), squared, divided by the diagonal dimension of said screen, squared, is greater than 25/34 and less than 1.