NO135807B - - Google Patents

Description

color picture tube-

The present invention relates to a color picture tube comprising a flask with a picture screen and a flask neck with an electron gun for producing a plurality of coplanar "in line" rays, which are to hit the respective fluorescent color elements on the picture screen. The color picture tube also has a torus-shaped deflection yoke which is supplied with energy to cause the rays to sweep over the respective rasters on the picture screen, and the yoke is adjustable on the neck. Furthermore, the invention relates to a method for assembling the different parts and components of the color picture tube.

The usual types of color television receivers have picture tubes with a shadow mask and a delta-type electron gun in which three electron beams coming from the corners of a triangle are deflected to scan a grid on the fluorescent screen. It is important here that the electron beams converge at all points on the screen so that the three different color rasters lie on top of each other. For this purpose, it is common practice to use an electro-magnetic dynamic convergence correction device placed around the neck of the color picture tube in the area where the rays leave the cannon. This correction device usually consists of three electromagnets placed around three internal pole shoes in the picture tube, and the magnets are supplied with current at the line and field search speeds for dynamic control of the correction given to the respective beams to ensure satisfactory convergence at all points on the screen. The waveforms applied to the electromagnets can be suitably regulated to provide the desired correction. Although the dynamic correction apparatus seems satisfactory, it is • relatively complicated and therefore expensive, which increases the price of a color television receiver. The fact that the equipment is complex also requires time for the correct setting.

Color picture tubes using three horizontal "in line" electron beams have been used in some cases as a replacement for the delta gun tubes to simplify the equipment required to produce convergence of the beams. For example, in a color picture tube that uses three horizontal "in line" beams and a picture screen with fluorescent elements in the form of vertical, differently colored fluorescent strips, the equipment that provides dynamic convergence can be significantly simplified despite the fact that dynamic convergence is still required.

For these reasons, it would be desirable to come forward

to a color picture tube that does not require dynamic convergence correction, and according to the invention this is achieved by the torus-shaped deflection yoke, which has such internal dimensions that it becomes possible to shift the yoke across the neck of the flask, is connected to devices which are adapted to, by adjustment,

set the yoke in the transverse direction in relation to the picture tube.

The invention is characterized by those in the claims re-

given features and will be described in more detail in the following with reference to the drawings therein:

Fig. 1 shows a system according to the invention for

to produce convergence of a plurality of aligned rays, .

fig. 2 shows the characteristic of a magnetic deflection field generated by the deflection yoke shown in fig. 1, fig. 3 and 4 show the effect of the magnetic deflection field • on fig. 2 on the two outer electron beams shown in fig'.... 1..

fig. 5 is a partial cross-section of the deflection yoke, and £ ■ '• 'V...^..'-.. * the picture tube in fig. 1. V<*->,-

In fig. 1 shows a system according to the invention for producing convergence of a plurality of aligned electron beams. Fig. 1 shows the principal components of a color television projector. A color picture tube consists of a glass container 11. At one end of the container 11 is placed a translucent front plate 12 on the inside of which are placed repeated groups of blue, red and green phosphor elements 13a, 13b and 13c.

An aperture mask is placed at a short distance from the phosphor elements

14, in which a plurality of openings 15 are designed. In the neck part of the container 11 at the other end of the picture tube, an electron gun 16 is placed which generates three horizontal aligned beams 17a, 17b and 17c' The beams are modulated according to video

signals which are respectively representative of blue, red and green color information for the transmitted television picture. Around the neck of the container and near the sloping part, a deflection yoke 18 is placed which, when current is supplied for vertical and horizontal scanning, causes the electron beams 17a, 17b and 17c to scan the respective grid over the phosphor elements. The deflection yoke 18 is held in place by means of the mounting device 18a which will be described in more detail below in

detail.

Around the neck of the picture tube in the area where the electron beams leave the gun 16, a static radiant convergence device 19 and a beam purity device 20 are placed. The convergence device 19 comprises a plurality of permanent

magnets that statically converge the beams in the center of the picture screen. The purity device 20 comprises two ring-shaped magnets which are regulated simultaneously to achieve purity, that is to ensure that the respective color representative rays hit their respective color phosphor elements on the screen.

In a preferred embodiment, the phosphor elements 13a, 13b and 13c are vertical strips of phosphor material and the openings 15 are elongated slits which also run in a vertical direction. Such a vertical line structure for the phosphor elements eliminates vertical registration problems because even with a slight misalignment of the beams in the vertical direction, a particular beam will still hit its respective color phosphor element because the phosphor stripes run through the vertical dimension of the picture screen. However, vertical misalignment of the beams will lead to a convergence problem, which, together with its solution, will be described below. The arrangement described so far in fig. 1 is shown in detail in Norwegian patent application no. 161/73 of 12 July 1973 from A.M. Morell et al and termed: "Self-converging color television projector".

Fig. 2 shows the characteristic of a magnetic deflection field generated by the deflection yoke shown in fig. 1. As described in the above-mentioned Norwegian application, the electron gun 16 and the deflection yoke 18 will provide predominantly convergence of the beams at all points on the searched grid, requiring the use of dynamic convergence correction equipment. The characteristic of a deflection yoke to achieve this is that it exhibits negative horizontal isotropic astigmatism and positive vertical isotropic astigmatism. Fig. 2 shows the resulting or dominant magnetic field produced by a yoke exhibiting these astigmatic characteristics. In fig. 2, the flux line 25 shows the horizontal magnetic field. The pincushion shape of this field is due to the negative horizontal isotropic astigmatism. This pincushion deflection field increases in strength with distance from the center along an axis parallel to the horizontal direction of deflection. At the same time, this pincushion-shaped field decreases in strength along an axis perpendicular to the horizontal deflection line.

In fig. 2, the flux line 26 shows the vertical magnetic deflection field generated by a deflection yoke exhibiting positive vertical isotropic astigmatism. This vertical field is barrel-shaped and the vertical barrel-shaped deflection field becomes strong-

are along the horizontal axis and weaker along the vertical axis.

The deflection yoke's magnetic field distribution described in connection with fig. 2 is calculated to give perfect convergence to correctly aligned electron beams. If the rays are not correctly aligned with the center of the magnetic field, the rays will not converge on the image screen. Misalignment of the beams relative to the yoke's magnetic field can occur as a result of misalignment of the electron gun in the picture tube, misalignment of the deflection yoke in relation to the beams or the tube neck, or non-symmetry of the coils on the deflection yoke. It can be said in general that manufacturing variations in the electron gun, its placement in the picture tube or ■ •. in the windings of the deflection yoke will cause misalignment of the beams in relation to the yoke's magnetic field. In a system as described in fig. 1 where no dynamic convergence apparatus is used, the beams will not converge unless precautions are taken for

to adjust the beams with the magnetic field according to the invention.

Fig. 3 and 4 show the effect of the magnetic deflection field on fig. 2 on the two outer beams when the beams are misaligned relative to the deflection yoke's magnetic field. Fig. 3a shows the state where the blue and green rays 17a and 17c are misaligned in the vertical direction in relation to the center of the horizontal deflection field shown by the flux line 25. The dotted lines indicate the magnetic flux and the completely ^ solid arrows pointing away from the beams indicate the general direction and magnitude of beam displacement as a result of beam misalignment. To simplify fig. 3 and 4, the middle of the three beams, the red beam 17b, is omitted because it can generally be said that the effect on the center beam will be that it will lie between the outer blue and green beams.

In fig. 3a, the blue and green rays are exposed to magnetic fields of the same strength because they are equally displaced in the horizontal direction from the center of the field, but the directions are different so that when the rays are deflected to the right, the blue ray will also be deflected upwards and the green ray will be deflected downwards . When the beams are deflected to the left (by reversing the shown polarity of the magnetic field), the blue beam will be undesirably deflected downwards and the green beam upwards. This means that along the horizontal X-axis the blue beam will be low on the left side of the grid

and high on the right side in relation to the green beam. If the beams had been misaligned downwards from the center axis instead of upwards, the blue beam would be high on the left side and low on the right side in relation to the green beam.

In fig. 3b, the blue and green rays are misaligned horizontally to the right in the horizontal deflection field 25. As described above, the strength of the pincushion-shaped horizontal deflection field increases with the distance from the center along the horizontal axis. Therefore, as the misaligned green beam is further from the center than the blue beam and is thus in a stronger magnetic field, it is further deflected. This means that the green grid is wider than the blue grid. It can be seen that if the polarity of the deflection field is reversed so that when the rays are deflected towards the right side of the grid, the green beam would correspondingly be deflected further than the blue. If the rays had been misaligned to the left, instead of to the right as shown, the green raster would be smaller than the blue raster. Fig. 4a shows the effect on the beams when they are misaligned vertically upwards under the influence of the vertical magnetic field shown by the flux line 26. The blue beam will move to the left at the top of the grid and to the right at the bottom of the grid in relation to the green beam due to the direction of the magnetic flux lines.

Fig. 4b shows the effect of a horizontal misalignment

of the rays in the vertical deflection field. As the green beam is further from the center axis than the blue one, it is in a stronger part of the field and will therefore be deflected a greater distance vertically than the blue beam. This causes the green raster to be larger in the vertical direction both at the top and bottom than the blue raster.

It has been shown how misalignment of the electron beams relative to the vertical and horizontal magnetic fields causes misconvergence. Horizontal misalignment of the beams causes the grids to vary in size, both vertically and horizontally. Vertical misalignment of the beams causes the grids formed by the two outer beams to be rotated in the opposite direction from each other.

Fig. 5 is a partial cross-section of the deflection and image tube shown in fig. 1. According to the invention, it has been found that misconvergence of the beams caused by misalignment of the beams relative to the deflection yoke's magnetic field can be reduced considerably by placing the deflection yoke relative to the beams, so that the magnetic deflection center of the yoke is brought into alignment with a point midway between the two outer rays. In fig. 5 shows a deflection yoke 18 where only conductors 21 are shown over part of the yoke and which is torus-shaped coiled around a core, is constructed so that the smallest and inner diameter of the yoke is larger than the outer diameter of the picture tube's neck. With such an arrangement, the deflection yoke can be displaced laterally in the X and Y directions or in any desired direction in the X-Y plane so that the yoke's magnetic field can. is set in such a way in relation to the electron beams that predominantly convergence of the beams is achieved on the phosphor screen. It is important to note that according to a feature of the invention, a deflection yoke which is placed in the X-Y plane around the picture tube container 11 is moved transversely so that the central longitudinal axis of the yoke or the central longitudinal axis of the yoke's deflection field is brought into alignment with the central beam axis or parallel to this. More recently, the mounting device for such yokes has been provided which enables the yoke to be tilted in relation to the neck of the picture tube, so that the yoke no longer lies in an X-Y plane. This tilt serves to correct for coma in a color picture tube of the delta-canon type, which meant that the blue rasters have a different width than the green and red rasters. With such an arrangement it was

* w w w w w required dynamic convergence correction of all beams to converge the beams in the phosphor screen. It has been found that in the arrangement described in fig. 1, the tilting of the deflection yoke could lead to a misalignment of the rays on the phosphor screen. However, by providing the transverse movement of the entire yoke, the conformity of the rays with the color phosphor elements will not be disturbed and convergence will be achieved without requiring dynamic convergence correction equipment.

It has been found that for a color television picture tube as described in connection with fig. 1 and with a picture screen of 38 cm, a radial clearance of approx. 1.25 mm between the outer diameter of the neck of the picture tube and the smallest inner diameter of the deflection yoke provide sufficient clearance to move the yoke so that predominantly convergence of the beams is obtained. It has been found that for a displacement of approx. 1.2 5 mm in the horizontal direction of the yoke gives a change of 1.25 mm in convergence on the horizontal sides of the grid. According to what is shown in fig. 3 and 4 will therefore result in a horizontal displacement of the yoke of approx. 1.25 mm to the right produces an increase of 1.25 mm in the size of the blue

grid on each side in relation to the green grid, with the size of the blue grid increasing and the size of the green grid decreasing. For the same horizontal displacement, the blue grid will be approx. 0.6 mm larger than the green in the upper and lower edges

of the grid. The sensitivity for vertical displacement of the yoke is approximately the same as for the described horizontal displacement.

The changes are such that the blue and green rasters are moved in opposite directions compared to the red ones, which are in themselves between the blue and green. The convergence change in the corners when the yoke is shifted is a combination of the convergence changes on the nearby vertical and horizontal axes.

It appears from a relatively small displacement of the yoke that can provide considerable convergence correction. It is therefore highly desirable that the yoke can be maintained in the desired operative position in relation to the picture tube. For this purpose, a suitable device for mounting the yoke is provided which enables the yoke to be positioned correctly for the best overall convergence condition and then fixed in position.

An arrangement for mounting the yoke involves permanently gluing a mounting platform to the picture tube, permanently attaching a mounting element to the yoke, and then loosely attaching the mounting element to the platform while the yoke and tube are operated to find the optimum position for the yoke on the picture tube. When this position is found by observing the convergence of the lines in a criss-cross pattern that appears on the screen upon application of an appropriate test signal, the mounting elements on the platform are fixed to each other by means of an adhesive or by mechanical means, such as with screws and nuts which holding the two pieces together.

The invention is not limited by the special mounting device for the yoke that is provided. It is noted that any mounting device which allows transverse movement of the entire yoke rather than the rocking movement alone and which enables

, that the yoke can be held in the desired position is suitable for breaking in the invention.

The method of setting the yoke's magnetic field in relation to the beams in order to thereby achieve convergence, and the device for holding the yoke permanently in the desired operational position, will be used in the manufacture of television receivers as the yoke and the tube are operated to produce a suitable pattern, such as a crossed line pattern on the phosphor screen, allowing the operator to observe and determine the optimal placement of the yoke for maximum convergence.

The invention has been described in connection with a color television display system, where the invention mainly eliminates the need for dynamic convergence correction equipment. However, the invention can also be used with dynamic convergence correction equipment to supplement the degree of convergence correction or to simplify and reduce the costs of the existing convergence correction system, e.g. by eliminating some or all variable control elements or by reducing the number of components in the circuits that generate convergence-correcting waveforms.

Claims (4)

1. Color picture tube with a flask whose picture screen has elements that fluoresce with different colors and an electron gun placed in the neck of the flask for producing a plurality of coplanar "in line" rays which are to hit the respective fluorescent color elements, as well as a torus-shaped deflection yoke arranged to be supplied energy to cause the rays to sweep over the respective rasters on the color image screen, which yoke has a minimum inner circumference greater than the outer circumference of the neck portion of the flask, and means for placing the yoke on the picture tube, characterized in that the means (18a) is arranged to allow transverse movement of the yoke relative to the picture tube, so that the yoke can be moved to a position which produces substantially convergence of the beams (17a, 17b, 17c) and coincident rasters and to hold the yoke fixed in this position. 2. Color picture tube as stated in claim 1, characterized in that the yoke comprises a pair of vertical and a pair of horizontal deflection coils where the distribution of the conductor windings in the coils is chosen so that positive vertical isotropic astigmatism and negative horizontal isotropic astigmatism are formed. 3. Color picture tube as stated in claim 1, characterized in that the picture screen has strips of elements that fluoresce with different colours. 4. Method for assembling the color picture tube specified in claim 1, characterized in that the deflection yoke is placed on the picture tube and that the tube is held firmly in a specific position, that the deflection yoke is temporarily held in position on the picture tube near the said deflection zone, after which the picture tube and the yoke are set for to direct the rays towards the screen, and to cause the rays to sweep in separate rasters on the aforementioned screen, as well as by the transverse position of the yoke being regulated simultaneously in relation to the picture tube while maintaining predominantly parallelism between the longitudinal axes of the yoke and the picture tube, so that largely convergence of the beams and coincident rasters on the screen are achieved, after which the yoke is fixed on the picture tube in the aforementioned set position.