CS252451B2 - Convergence system for colour picture tube - Google Patents

Abstract

In a color television display system in which a plurality of horizontal in-line electron beams are directed toward color phosphor elements of a color picture tube, substantial convergence of the beams at all points on a scanned raster is achieved by transversely positioning the deflection yoke relative to the picture tube while maintaining substantial parallelism between the central longitudinal axes of the yoke and picture tube.

Description

The invention relates to a color-screen convergence system having in an evacuated flask a repeating pattern screen of three differently colored luminescent elements, a shielding mask located inside the bulb and provided with a plurality of holes aligned with the luminescent elements, an electron gun arranged inside the bulb at one end provided with electrodes forming the main focusing lens at the exit end of the electron beam of the electron gun, a magnetostatic convergence member disposed adjacent the electron gun, a self-converging deflection yoke disposed around the neck portion of the flask, the deflection yoke having a hollow ferrite magnetic core they are larger than the circumferential dimensions of the flask at its location on the flask to allow displacement of the yoke in directions transverse to the flask axis, and the horizontal deflection coil.

The most common type of color television uses screens with shading masks and delta nozzles, the so-called delta nozzle screens, in which three electron beams emanating from the tips of the triangle are deflected to decompose the raster on the luminescent screen. It is essential that the electron beams converge at all points on the screen to superimpose three rasters of different colors. In practice, an electromagnetic device for correcting dynamic convergence, arranged around the neck of the color screen, is used in the area where the rays leave the nozzles. This convergence correction device typically consists of three electromagnets, located around the three internal poles of the screen and excited at a frame rate to dynamically control the magnitude of the respective beam control to ensure satisfactory convergence at all points of the screen. The waveforms used for the electromagnets can be appropriately adjusted to achieve the desired correction.

A disadvantage of the prior art, however, is that the prior art displays require a dynamic correction device that is relatively complex and thus expensive, thus increasing the cost of a color television apparatus. In addition, the complexity of this device requires a lot of time for proper setup.

In some cases, delta color screens have been replaced by in-line color television screens having three horizontal electron beams side-by-side to simplify the equipment necessary to maintain beam convergence. For example, in a color television screen with three horizontal beams side by side and a screen with vertical strips i. Of different colored luminophores, the dynamic convergence device can be simplified, although dynamic convergence is still necessary. It is of course desirable to provide a color television receiver that does not require dynamic convergence correction at all.

These prior art drawbacks are largely overcome by a color-screen convertor system having a repeating pattern screen of three differently colored luminescent elements in an evacuated bulb, a shielding mask disposed within the bulb and provided with a plurality of holes aligned with the luminescent elements, an electron gun disposed within the bulb. one end of the throat against the screen and provided with electrodes forming the main focusing lens at the exit end of the electron beam of the electron gun, and a magnetostatic convergence member disposed adjacent the electron gun, self-converging deflection yoke disposed around the throat portion of the flask, the deflector yoke having a hollow ferrite core whose circumferential dimensions are greater than the circumferential dimensions of the bulb at its location on the bulb to allow the yoke to be displaced in the directions transverse to the bulb axis, and ontal deflector,.

characterized in that the electrodes and lenses comprise a common electrode at the shielding end of the electron gun, the common electrode having three holes.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail in the following description of an exemplary embodiment with reference to the accompanying drawings, in which FIG. 1 shows a system according to the invention for generating a plurality of beams in a row; FIG. 2 shows the characteristic of the magnetic deflection field Figures 3 and 4 show the effects of the magnetic deflection field of Figure 2 on the two external electron beams shown in Figure 1, and Figure 5 is a partial cross-section of the deflection yoke and screen shown in Figure 1.

Fig. 1 shows a color display convergence system according to the invention. Giant. 1 shows the main components of a color television receiver. The color television screen consists of a glass bulb 11. At one end, the glass bulb is provided with a translucent faceplate 12, the inside of which is provided with repeating groups of blue, red and green luminescent elements 13a, 13b, 13c. At a short distance from the luminescent elements 13a, 13b, 13c is a shielding mask 14 comprising a plurality of apertures 15. At the other end of the screen, inside the neck of the flask is a system 16 of electron guns for generating three horizontal beams 17a, 17b and 17c. The rays are modulated according to the television signals and carry the appropriate blue, red and green color information about the television image. A deflection yoke 18 is disposed around the neck of the screen and at the funnel portion of the flask 11, which, by suitable excitation from sources of vertical and horizontal scanning frequencies, causes the electron beams to form appropriate screens on the luminescent elements. The deflection yoke 18 is held in position by the yoke clamping device 18a, which will be described in more detail in the following description.

Around the neck of the screen, in the area where the electron beams exit the electron gun assembly 16, are located: a magnetic-static convergence member 19 and a correction device 20. the magnetic-static convergence member 19 may consist of a number of permanent magnets for magnetic-static convergence in the middle of the luminescent screen. The beam cleansing device 20 comprises two annular rings which are simultaneously adjusted to achieve color purity, i.e., to ensure that the individual beams 17a, 17b, 17c bearing the color information fall on each other the luminescent elements 13a, 13b, and 13c.

In an exemplary embodiment, the luminescent elements 13a, 13b and 13c are vertical strips of luminescent material, and the apertures 15 are elongated and elongated in shape and arranged in a vertical direction. Such a structure of the vertical banded luminescent elements 13a, 13b and 13c eliminates the problems of vertical recording, because even with a slight misalignment of the beams 17a, 17b, 17c in the vertical direction, the individual beam 17a, 17b, 17c will still impact the assigned color luminescent element 13a, 13b, 13c, or luminescent strips, are disposed throughout the vertical dimension of the faceplate of the screen. However, an incorrect vertical alignment of the beams will cause a convergence problem, which will be described together with its solution in the following.

Giant. 2 shows the characteristic of the magnetic deflection field produced by the deflection yoke shown in FIG. 1. As is known in the art, the particular choice of the electron gun assembly 16 and the deflection yoke 18 allows substantial convergence of the beams 17a, 17b, 17c at all points of the scanning grid. without the need for dynamic convergence correction devices. To achieve this, the deflection yoke 18 has the property of exhibiting negative horizontal astigmatism and positive vertical isotopic astigmatism. Giant. 2 illustrates a useful or predominant magnetic field created by a deflection yoke 18 that exhibits astigmatic properties. In Fig. 2, the horizontal magnetic field lines 25 represent the horizontal magnetic field lines 25 represent the horizontal magnetic field. The pincushion shape of the field is caused by a negative horizontal deflection direction. At the same time, the intensity of this padded field decreases along an axis perpendicular to the direction of horizontal deflection.

In Fig. 2, the vertical magnetic field lines 26 represent the vertical magnetic deflection field created by the deflection yoke 18, which exhibits a positive vertical isotopic astigmatism. The vertical field is barrel-shaped and the vertical barrel deflection field strengthens along the horizontal axis and weakens along the vertical axis.

The magnetic field distribution of the deflection yoke 18 described in connection with FIG. 2 is intended for the convergence of perfectly aligned electron beams 17a, 17b, 17c. If the beams 17a, 17b, 17c are not properly aligned with the center of the magnetic field of the deflection yoke 18, they will not converge on the screen. Incorrect convergence of the beams 17a, 17b, 17c to the magnetic field of the deflection yoke 18 could occur when aligning the electron guns inside the screen, incorrectly aligning the deflection yoke 18 with the beams 17a, 17b, 17c or the neck of the screen, or asymmetry of the deflection yoke coils. it can be said that manufacturing tolerances in the location of the electrode nozzle assembly 16 within the screen or winding of the deflection yoke 18 result in misalignment of the beams 17a, 17b, 17c to the eave of the yoke 18. In a system such as that described in FIG. If the dynamic convergence correction device is used, the beams will not converge until the measures for aligning the beams with the maagneic field according to the invention have been implemented.

Figs. 3 and 4 illustrate the effects of the microscopic deflection field of Fig. 2 on the two outer of the three electron beams 17a and 17c in their misalignment with respect to the deflection yoke field 18. Fig. 3a shows a state in which, in the vertical direction with respect to the center of the horizontal deflection field shown by the horizontal man-mnonic lines 25, the dotted horizontal man-mine lines 25 denote the man-mine flow and solid arrows pointing out of the spokes 17a, 17b, 17c generally indicate the direction and magnitude of the displacement caused by the misalignment of the spokes 17a, 171b, 17c. To simplify the illustration in Figs. 3 and 4, the center of the three spokes, i.e. the red spoke 17b has been omitted, since it can generally be assumed that the effect on the central beam 17b will be that it will run more than two months, i.e. the blue and green beams 17a and 17c.

In Fig. 3a, the blue and green beams 17a and 17c have the same field intensity as they are equally spaced horizontally from the center of the field, but the directions differ in that when the beams are deflected to the right, the blue beam 17a also deflects darkness. The upward beam and the green beam 17c sweep downward. When the rays 17a, 171b, 17c are deflected to the left, by reversing the marked instances of the mannical field, the blue ray 17a would undesirably sweep down and the green ray 17c up. As a result, along the horizontal X-axis, the blue beam 17a will be low on the left side of the screen and on the right high side the green beam 17c. Although the beams 17a, 17b, 17c have been misaligned downward from the centerline rather than upward, the blue beam 17a will be high on the left side and low on the right side relative to the beam 17c.

In Fig. 3b, the blue and green beams 17a, 17c are misaligned to the right in the horizontal deflection position. As described above, the acuoidal field deflection field intensifies as it is centered along the horizontal axis.

Therefore, since the misaligned green beam 17c is farther from the central beam 17b than the blue beam 17a, this is in a stronger magnifying field and is more deflected. As a result, the green grid is wider than the blue grid. It is obvious that if the field is turned poSajita vychyiovacího as if beams 17a, 17b, 17c eёjy '., ^Ι deflect to the right in the bitmap, the green beam 17c could similarly vycc ^ Hl farther than the blue beam 17a. Jessliiv, beams 17a, 17b, 17c were misaligned to the left of the center rather than to the right, as shown, then the green screen would be smaller than the blue screen.

Giant. 4a illustrates the effect on beams when misaligned in the direction of the upstream, below the vertical maanoic deflection field, below the vertical maanneic deflection field shown by the vertical mmannelian field lines, 26. The blue beam 17a will move to the left in the upper portion of the grid and to the right in the lower portion of the grid relative to the green of the beam 17c, due to the direction of the vertical Maanneic flow lines 26 of the Mann stream.

Giant. 4b shows the effect of misalignment of the beams in the horizontal direction in the deflection position. Since the green beam 17c is farther from the centerline than the blue beam 17a is in the stronger part of the field and will therefore be deflected a greater distance in the direction of direction than the blue beam 17a. This causes the green grid to be wider in the snitlée direction, both up and down than the blue grid.

It has been shown how the misalignment of the electron beams 17a, 17b, 17c with respect to the wobble and the horizontal field causes a wrong conversion. Due to the horizontal misinterpretation of the beams 17a, 171b, 17c, the dimensions of the grid change in both vertical and horizontal directions. Vetikální misalignment beams 17a, 17b, 17c causing the rasters formed dvSma outdoor advert ^ ^ I y paprs ^to 17b, 17c to rotate in the other of ^p ačných directions. .

Giant. 5 is a partial cross-sectional view of the deflection yoke 18 and the screen of FIG. 1. According to the invention, it has been determined that erroneous beam convergence caused by erroneous alignment of the beams to the mm pte of the deflection yoke 18 to the beams 17a, 177b, 17c so the center of the maagonic deflection yoke 18 was in line with the point bisecting the distance between the two outer rays.

In FIG. 5, the deflection yoke 48, of which the wires 21, of which only a part is shown, is wound around the core, has at least a weave. the inner diameter of the yoke 18 is greater than the outer diameter of the neck of the flask 11. In such an arrangement the deflection yoke 18 may be displaced laterally in the X and Y directions or in the direction of the XY plane to align the mmanneic field of the yoke 18 with the central electoral beam 17b. to achieve beam convergence on the luminescent screen. It is important to note that, according to one aspect of the invention, the deflection yoke 48, by being positioned in the XY plane around the screen bulb 11, moves transversely such that the central longitudinal axis of the yoke 18 or the central longitudinal axis of the deflection yoke 18 coincides with the central the axis of the central beam 17b or parallel to it. In the mini-junction, the yoke 18 arrangements were made that allow the yoke 18 to tilt toward the neck of the screen so that the yoke 18 would no longer lie in the X-Y plane. This tilt serves for the correction to a triangle, resulting in a blue grid having a different width than the red and green grid. In such arrangements, the dynamic convergence correction of all beams 17a, 17b, 17c was necessary to properly converge the beams 17a, 171b, 17c on the luminescent screen. It has been found that in the arrangement described in FIG. 1, simply tilting the deflection yoke 18 could result in erroneous coverage of the beams 17a, 17b, 17c on the luminescent screen. However, by performing the described transverse displacement of the entire yoke 18, the coverage of the colored luminescent elements 13a, 131b, 13c by the rays 17a, 17b, 17c is not impaired and convergence is achieved. - dynamic convergence correction device.

koma in color television screens with jets

It has been determined that for a color television screen as described in connection with FIG. 1 having a screen diagonal of 38 cm, a radial clearance of about 1 is sufficient to move the yoke 13 13 to achieve substantial beam convergence 17a, 17b, 17c. 27 mm between the outside diameter of the neck of the screen and the smallest inside diameter of the deflection yoke £ 8. It was determined that a yoke displacement of about 1.27 mm in the horizontal direction resulted in a 1.27 mm convergence change in the horizontal sides of the rasters. Thus, as shown in FIGS. 3 and 4, a horizontal displacement of yoke 18 of about 1.27 mm to the right causes an increase in the size of the blue screen on each side relative to the green by about 1.27 mm, so that the size of the blue screen has increased. the dimension of the green grid is reduced.

For the same horizontal shift, the blue grid is increased by about 0.63 mm relative to the green grid at the top and bottom of the grid. The sensitivity to the veetic shift is approximately the same as that for the described horizontal shift. The changes are such that the blue and green raster are moved in opposite directions to the red, which itself is between blue and green. The corners of convergence at the corners caused by the displacement of yoke 18 are a combination of convergence changes on adjacent vertical and horizontal axes.

Obviously, a relatively small displacement of yoke 88 can provide a correction for substantial convergence. Therefore, it is imperative that the yoke 18 be held firmly in the desired operating position relative to the screen. To this end, suitable arrangements have been made for fastening the yoke 8, which correctly positioning the yoke 18 for not improving the overall convergence state, and then fixing in the set position. A yoke mounting arrangement is known in which a platform is permanently attached to the screen, a mounting member is permanently attached to the deflection yoke 18, and the mounting member is freely mounted to the platform, while the yoke 18 and the screen can be used to determine the optimal position of the yoke 18 relative to the screen. After detecting this position, for example by observing the convergence of the lines of the cross-signal pattern formed on the screen by passing a suitable test signal to the television, the yoke 18 and platform members are immobilized with adhesive or mechaan means such as nuts and bolts holding both pieces together. .

The invention is not limited to the use of special yoke mounting means 18. It should be noted that any mootage means allowing transverse movement of the entire yoke 18 rather than the tilt itself and allowing the yoke 18 to be immobilized in the desired position is suitable for use with the invention.

A method of adjusting the magnetic field of yoke 18 with beams 17a, 17b, 17C to achieve convergence, and devices to keep yoke 18 permanently in the desired operating position would be used during the manufacture of the television when yoke 18 and screen are shifted to achieve a suitable pattern, e.g. signal on the luminescence screen so that the operator can observe and determine the optimal location of the yoke 18 for better convergence.

To ensure accurate positioning of the spokes 17a, 17b, 17c leaving the main crossroad of the lens, a common electrode is provided which is provided with three holes for the passage of the individual spokes 17a, 17b, 17c.

The invention has been described in connection with a color television imaging system in which the features of the invention eliminate the need for waveforms to correct dynamic convergence and the apparatus thereto. However, the invention may also be used with a dynamic convergence correction device to supplement the degree of system convergence correction or to simplify and reduce the cost of an existing convergence correction system, such as eliminating some or all of the variable controls or reducing the number of convergence correction.

Claims (1)

SUBJECT OF THE INVENTION A color-screen convergence system having, in an evacuated bulb, a repeating pattern screen of three differently colored luminescent elements, a screen mask located inside the bulb and provided with a plurality of holes aligned with the luminescent elements, an electron gun arranged inside the bulb at one end of the throat against the lampshade; forming a main focusing lens at the exit end of the electron beam of the electron gun, and a magnetostatic convergence member disposed adjacent the electron gun, a self-converging deflection yoke disposed around the neck portion of the flask, the deflector yoke having a hollow ferrite magnetic core. the dimensions of the flask at its location on the flask to allow the yoke to move in the directions transverse to the axis of the flask, and the horizontal deflection coil characterized in that the electrodes the lenses comprise a common electrode disposed at the screen end of the electron gun, the common electrode having three apertures.