RU2059319C1 - Device for static convergence and color purity adjustment in color tubes - Google Patents

Abstract

FIELD: color picture tubes. SUBSTANCE: device for static convergence and color purity adjustment in color tubes with coplanar arrangement of guns has magnetic system built up of pair of two-pole magnets, two pairs of six-pole toroidal magnets whose centers are located on axial line of picture tube neck. Two-pole toroidal magnets are used to adjust color purity; six-pole toroidal magnets function to provide convergence between side beams and central beam. Six-pole toroidal magnets are saturated asymmetrically to their centers and each pair has zero magnetic field, respectively, in the region of second and central beams as well as in region of first side beam and central beam. EFFECT: improved design. 4 dwg

Description

 The invention relates to television technology and can be used in technological and output control of color picture tubes with a coplanar arrangement of electronic searchlights or deflecting systems for such picture tubes.

A device for reducing electron beams of a color picture tube, comprising a magnetic system mounted on the neck of a picture tube and consisting of a pair of bipolar ring magnets for setting color purity, a pair of four-pole ring magnets to bring together two side beams of a picture tube and a pair of six-pole ring magnets to reduce side rays with the central beam of the kinescope, while the centers of all ring magnets are located on the axial line of the neck of the kinescope, and the four- and six-pole rings e magnets have magnetization symmetry with zero magnetic field in the center of the magnet, the central beam coinciding with the kinescope [1]
The known device is designed to compensate for errors in the manufacture of a tube and has the following disadvantages:
the difficulty of converting the rays due to the magnetic field of the symmetrically magnetized each of the four and six-pole ring magnets is not on one, but on both side beams; low productivity in operations of mixing rays and setting the purity of color, due to the alternation of work with four and six-pole pairs of ring magnets.

Closest to the invention is a device for converging beams and adjusting color purity in color picture tubes with a coplanar arrangement of spotlights, containing a magnetic system mounted on the neck of the picture tube and consisting of a pair of bipolar ring magnets to set the color purity, a pair of six-pole ring magnets to reduce the first side beam with a central beam and pairs of six-pole ring magnets to reduce the second side beam with a central beam of the kinescope, while the centers are bipolar ring magnets are located on the center line of the tube neck, and pairs of six-pole ring magnets are mounted on the neck of the tube with eccentricity and their centers are shifted from the center line of the tube neck, respectively, to bring the first side beam with the central beam toward the second side beam by half the distance between the central and lateral rays, to reduce the second lateral beam with the central beam towards the first beam at half the distance between the central and side rays, and all six -pole ring magnets have magnetization symmetry with zero magnetic field in their centers [2]
In this device, separate regulation of the side beams is achieved by shifting the centers of the six-pole ring magnets along the line connecting the centers of the electronic spotlights by an eccentricity equal to half the distance from the central to the side beam. Thus, the center of the pair of six-pole ring adjustment magnets of red color is shifted towards the blue beam, and the center of the pair of six-pole ring magnets of adjustment of blue color is shifted towards the red beam.

 Compared to device [1], the device simplifies and speeds up the operation of converting rays and setting the color purity due to the fact that each pair of six-pole ring magnets acts only on its side beam of the kinescope.

The disadvantages of the device are:
large dimensions due to the use of eccentricity (an eccentric element, for example, a gasket), which requires an increase in the diameter of the six-pole ring magnets by a doubled amount of eccentricity;
the presence of parasitic effects of six-pole ring magnets on the central and other lateral rays.

 The proposed device for static mixing of rays and setting the purity of color has small dimensions due to the exclusion of an eccentric element from the design and reduces the complexity of mixing rays by eliminating the parasitic effects of six-pole ring magnets on the central and other side rays.

 This is achieved by the fact that in the device for static beam reduction and color purity setting in color picture tubes with coplanar arrangement of spotlights, containing a magnetic system mounted on the picture tube neck and consisting of a pair of bipolar ring magnets for setting color purity, the centers of which are located on the centerline of the neck picture tube, two pairs of six-pole ring magnets to reduce the first and second side beams with a central beam, respectively, six-pole ring magnets magnet their centers are asymmetrically located, which are also located on the axial line of the neck of the kinescope, with six-pole ring magnets to bring together the first side beam with a central beam and a zero magnetic field in the zone of the central and second side beams, and six-pole ring magnets to bring together the second side beam with a central beam have a zero magnetic field in the zone of the central and first lateral rays.

 In FIG. 1 shows a device, a General view; in FIG. 2 diagram of the action of the magnetic field of six-pole ring magnets; in FIG. 3 diagram of the action of the magnetic field of bipolar ring magnets; in FIG. 4 magnetization scheme of six-pole ring magnets.

 A device for static beam reduction and color purity setting in color picture tubes contains a magnetic system consisting of a first pair 1 of six-pole ring magnets 2 and 3 for moving the first side beam R, a second pair of 4 six-pole ring magnets 5 and 6 for moving the second side beam B, pairs 7 of bipolar ring magnets 8 and 9 for moving the rays R, G, B when adjusting the color purity, installed on the base 10 aligned with it and the neck of the tube 11 in the area of the focusing electrode of the electronic spotlights.

 The device operates as follows.

The six-pole ring magnets 2 and 3 are spaced apart at an angle α (see Fig. 2), while the south pole S 12 of the ring magnet 2 and the north pole N 13 of the ring magnet 3 create a magnetic field whose magnetic field lines encompass electron beams B . G, R and act on them with vector forces 14, 15 and 16, moving the rays in the horizontal direction. For example, with a distance of 7 mm between the beams of the kinescope 11 and an inner diameter of 34 mm of ring magnets 2 and 3, the modules of vectors 15 and 16 respectively comprise 30 and 10% of the module of vector 14. In the case where the local sections of the ring magnets 2 and 3 are located in the zone of the south S pole 17 and the north N pole 18 are magnetized 10 times weaker than the local sections at poles 12 and 13, the total modules of vectors 14, 15 and 16 will be 101% 33% and 20% of the module of vector 14, respectively, when exposed to beam B only the magnetic poles 12 and 13. When the magnets 2 and 3 rotate, the pairs of symmetry ary ray picture tube relative position vector of the line 11 14 changes its largest unit, keeping the horizontal direction, and changes its direction 180 by the rotation ^{of the} annular magnets 2 and 3 in the opposite direction.

Vector 14 will begin to rotate from horizontal to vertical (up or down) with the joint rotation of the separated ring magnets 2 and 3 counterclockwise or clockwise by 30 ^about . The angle α breeding ring magnets 2 and 3, at which the maximum value of the modulus of the vector 14 is achieved, is 60 ^about . Full circular rotation of the vector 14 and a change in its modulus from 0 to the maximum value is achieved by a different combination of the position of the ears A of the six-pole ring magnets 2 and 3 in a sector of ± 60 ^° from the line of electron beams G, B, R.

4 hexapole pair of annular magnets 5 and 6 operates to move the other lateral beam of red color R in a similar manner, the vapor 4 is set with respect to a pair of steer with 1 to ^180, i.e. the entire pole system is mirrored. When combining the ears A of the bipolar ring magnets 8 and 9 of the pair 7 (see Fig. 3), the magnetic fields of this pair are compensated and all three beams R, G, B are not exposed to the pair 7 of the bipolar ring magnets. By adjusting the divorce of the ears A and rotating the magnets 8 and 9, the electron beams are brought into the necessary zone of the kinescope 11. The force acting on the beams of the electron projectors depends on the degree of magnetization of the ring magnets 2, 3, 5, 6, 8 and 9 and their relative position in pairs 1.4 and 7.

 The asymmetry of the magnetic field is obtained by magnetizing sections of six-pole ring magnets 2, 3, 5, and 6 by an electromagnetic coil B (see Fig. 4), leaning against the inner circumference of the magnets and passing a current pulse I through the electromagnetic coil. Each magnetized local portion of the ring magnet 2 corresponds to such the magnetized portion of the ring magnet 3 pairs 1, respectively, of the ring magnets 5 and 6 pairs 4. The degrees of magnetization of these sections are equal to each other, but the sections have the opposite direction of the magnet total poles, which is achieved by magnetizing sections of one electromagnetic coil with the same current pulse, but passing it through the coil in opposite directions. When combining magnets, each pair 1 and 4 has zero magnetic field strength.

 The degree of magnetization of pairs of poles 19, 20, 21, 22 and pairs of poles 23, 24, 25, and 26 is selected in such a way that their magneto-force lines intersecting the R and G rays create modules of total vector forces that compensate for the total modules of force vectors from acting on there are pairs of poles 12, 13 and 17, 18. The inner diameter of the ring magnets 2, 3, 5 and 6 is calculated such that the vectors 27 and 28 of the magnetic poles 23, 24, 25, 26 and the vectors 29 and 30 of the magnetic poles 19, 29, 21, 22 are directed vertically and cancel each other out.

 The degree of magnetization of the pairs of poles 19, 20, 21, 22, 23, 24, 25, 26 is carried out in the following order.

 The degree of magnetization of the pairs of poles 19, 20, 21 and 22 rises until the module of the total vector 31 from the action of vectors 32 and 3 of the 3 magnetic pairs of poles 19, 20, 21 and 22 is compared with the module of the vector 16 from the action of the magnetic pair of poles R 12, 13, 17 and 18. Then the degree of magnetization of the pairs of poles 23, 24, 25, 26 rises until the modulus of the total vector 34 from the action of the vectors 35 and 36 of the magnetic pairs of poles 19, 20, 21, 22, 23, 24 , 25 and 26 is compared with the module of vector 15 from exposure to the beam G of pairs of poles 12, 13 and 17, 18. After carrying out the operations described above, with the total vectors 31 and 34 acting on the rays R and G are equal to zero.

 The proposed device was manufactured and tested with a 61LK5TS kinescope. The device was installed on the neck of the tube in the amount of 82 mm from the end of the tube of the tube to the flange of the device. The test results showed that with a significant reduction in the dimensions of the magnetic system and the simplicity of its design, it provides high-quality control of the beam alignment and the setting of color purity with a sufficiently high performance tuning color picture tubes in their manufacture.

Claims (1)

 DEVICE FOR STATIC RADIATION AND RADIATION OF COLOR PURITY IN COLOR KINESCOPES with coplanar arrangement of spotlights, containing a magnetic system mounted on the neck of the picture tube and consisting of a pair of bipolar ring magnets for setting the color purity, the centers of which are located on the centerline of the axial line magnets for reducing, respectively, the first and second side beams with a central beam, characterized in that the six-pole ring magnets are magnetized asymmetrically of their centers, which are also located on the axial line of the neck of the kinescope, with six-pole ring magnets to bring together the first side beam with a central beam and a zero magnetic field in the zone of the central and second side beams, and six-pole ring magnets to bring together the second side beam with a central beam have a zero magnetic field in the zone of the central and first lateral rays.

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